Another year gone. In history books it will be marked as the year of the first LHC collisions, and in a few years noone will remember that 2.36$\ll$14. Meantime particle theorists have dwelled mostly on the dark side. The great expectations on the part of the Fermi experiment have not been fulfilled so far: their result may contain interesting physics but at the moment they are far from conclusive. The CDMS bubble inflated by certain irresponsible bloggers ;) has burst last week with a loud smack. In short, we remain in darkness.
This is the last post this year. While you gobble I vanish into jungle. Will be back next year, with more reckless rumors.
Wednesday, 23 December 2009
Thursday, 17 December 2009
CDMS Live
- 16:41. Welcome to the live commentary from the CDMS seminar starting today at 2pm Pacific time at SLAC. It might be the event of the year, or the flop of the decade. Though most likely it will be a hint of the century.
- 16:50 Our seminar room is starting to get packed. The webcast from SLAC will be projected on a big screen.
- 17:00. The SLAC seminar has started! The speaker is Jodi Cooley.
- 17:06. Dark matter history. Zwicky, Ruben, rotation curves, bullet clusters. No way around it, we have to suffer through that....
- 17:09. There is also a webcast of the Fermilab seminar here. They are ahead of SLAC...
- 17:12. Now talking at length about WIMPs. Does it mean they see a vanilla-flavor WIMP?
- 17:14. A picture of a cow on one of the slides.
- 17:15. Fermilab already got to the gamma rejection. We are watching the wrong webcast, booo.
- 17:18. Jodi starts describing the CDMS experiment.
- 17:20. Previous CDMS results at Fermilab. They're getting close.
- 17:30. We switched to the Fermilab talk here in Rutgers. Now the speaker is Lauren Hsu. She seems faster.
- 17:35. Very technical details about phonon timing and data quality monitoring.
- 17:38. Expected backgrounds. Finally some important details.
- 17:39. Estimated cosmogenic neutron background 0.04, and similarly for radiogenic ones.
- 17:40. Surface event background estimated at 0.6.
- 17:45. They are talking about expected limits. Scaring. They don't have a signal? If there were no signal they would obtain two times better bounds than the last time.
- 17:47. Rumors reaching me, of 2 events at 11 and 15 keV.
- 17:49. It's official: 2 events. One at 12 keV, the other at 15 kev.
- 17:49. There are additional 2 events very close to the cut window, approximately at 12 keV.
- 17:58. Now discussing the post-unblinding analysis and the statistical significance.
- 18:00. Both events were registered on weekends. Grad students having parties?
- 18:01. The significance of the signal is less than two sigma.
- 18:04. One of the events has something suspicious with the charge pulse. A long discussion unfolds.
- 18:12. After post-unblinding analysis the signal significance drops to 1.5sigma (23 percent probability of the background fluctuation).
- 18:14. The new limits on dark matter $4x10^{-44} cm^2$ for a 70 GeV WIMP. Slightly better (factor 1.5) than the last ones.
- 18:17. Inelastic dark matter interpretation of the DAMA signal is not excluded by the new CDMS data.
- 18:18. Nearing the end. The speaker discusses super-CDMS, the possible future upgrade of the experiment.
- 18:20. Summarizing, no discovery. Just a hint of a signal but with a very low statistical significance. Was fun anyway.
- 18:20. So much for now. Good night and good luck. The first theory papers should appear on Monday.
Wednesday, 16 December 2009
A little update on CDMS
I guess I owe you a short summary to straighten out what I messed up. This Thursday CDMS is going to announce their new results on dark matter detection based on the 2008 and 2009 runs. The collaboration has scheduled two simultaneous talks, one in Fermilab and one in SLAC, for 5pm Eastern time (23:00 in Europe). The SLAC talk will be webcasted here. An ArXiv paper is also promised, and it will probably get posted Thursday evening. These facts are based on the news from the official CDMS page, so they may turn out to be facts after all, unlike the previous facts I called facts even though they were unfacts :-)
Having rendered unto Caesar, I can go on indulging in completely unfounded speculations. It is pretty clear that no discovery will be announced this week, in the formal scientific sense of the word "discovery". Earlier expectations of a discovery that I was reporting on were based on the rumors of a CDMS paper accepted in Nature, which turned out to be completely false.
Moreover, some CDMS members seem to play down the hopes. But the secrecy surrounding the announcement of the new results may suggest that CDMS has seen at least a hint of a signal:
not enough for a 3 sigma evidence, but enough to send us all into an excited state.
So I see two possible scenarios:
Having rendered unto Caesar, I can go on indulging in completely unfounded speculations. It is pretty clear that no discovery will be announced this week, in the formal scientific sense of the word "discovery". Earlier expectations of a discovery that I was reporting on were based on the rumors of a CDMS paper accepted in Nature, which turned out to be completely false.
Moreover, some CDMS members seem to play down the hopes. But the secrecy surrounding the announcement of the new results may suggest that CDMS has seen at least a hint of a signal:
not enough for a 3 sigma evidence, but enough to send us all into an excited state.
So I see two possible scenarios:
- Scenario #1
CDMS has detected 2-3 events with the expected background of order 0.5. All eyes will turn to XENON100 - a more sensitive direct detection experiment that is kicking off as we speak - who should provide the definitive answer by the next summer. In the meantime, theorists will produce a zillion of papers fitting their favorite recoil spectrum to the 3 events. - Scenario #2
All this secrecy was just smoke and mirrors. CDMS has found 0 or 1 events, thus setting the best bounds so far on the dark matter-nucleon cross section. Given the expectations they raised in the physics community, the Thursday speakers will be torn to pieces by an angry mob, and their bones will be thrown to undergrads.
Wednesday, 9 December 2009
Go LHC!
Monday, 7 December 2009
What the hell is going on in CDMS???
The essence of blogging is of course spreading wild rumors. This one is definitely the wildest ever. The particle community is bustling with rumors of a possible discovery of dark matter in CDMS.
CDMS is an experiment located underground in the Soudan mine in Minnesota. It consists of two dozens of germanium and silicon ice-hockey pucks cooled down to 40 mK. When a particle hits the detector it produces both phonons and ionization, and certain tell-tale features of these two signals allow the experimenters to sort out electron events (expected to be produced by mundane background processes) from nuclear recoils (expected to be produced by scattering of dark matter particles, as the apparatus is well shielded from ordinary nucleons). The last analysis, published early 2008, was based on a data set collected in the years 2006--2007. After applying blind cuts they saw zero events that look like nuclear recoils, which allowed them to set the best limits so far on the scattering cross section of a garden variety WIMP (for WIMPs lighter than 60 GeV the bounds from another experiment called XENON10 are slightly better).
By now CDMS must have acquired four times more data. The new data set was supposed to be unblinded some time last autumn, and the new improved limits should have been published by now. They were not.
And then...
Important update: I just received this in an email:
CDMS is an experiment located underground in the Soudan mine in Minnesota. It consists of two dozens of germanium and silicon ice-hockey pucks cooled down to 40 mK. When a particle hits the detector it produces both phonons and ionization, and certain tell-tale features of these two signals allow the experimenters to sort out electron events (expected to be produced by mundane background processes) from nuclear recoils (expected to be produced by scattering of dark matter particles, as the apparatus is well shielded from ordinary nucleons). The last analysis, published early 2008, was based on a data set collected in the years 2006--2007. After applying blind cuts they saw zero events that look like nuclear recoils, which allowed them to set the best limits so far on the scattering cross section of a garden variety WIMP (for WIMPs lighter than 60 GeV the bounds from another experiment called XENON10 are slightly better).
By now CDMS must have acquired four times more data. The new data set was supposed to be unblinded some time last autumn, and the new improved limits should have been published by now. They were not.
And then...
- Fact #1: CDMS submitted a paper to Nature, and they were recently accepted. The paper is embargoed until December 18 (embargo is one of these relics of the last century that somehow persists until today, along with North Korea and Michael Jackson fans) - the collaboration is not allowed to speak publicly about its content. Consequently, CDMS has canceled all seminars scheduled before December 18.
- Fact #2: A film crew that was supposed to make a reportage from unblinding the CDMS data was called off shortly before the scheduled date. They were told to come back in January, when the unblinding will be restaged.
- Theory #1: The common lore is that particle physics papers appearing in Nature (the magazine, not the bitch) are those claiming a discovery. It is not at all impossible that the new data set contains enough events for an evidence or even a discovery. If the zero events in the previous CDMS paper was a downward fluke, several WIMP events could readily occur in the new data. Furthermore, in some fancy theories like inelastic dark matter, a large number of WIMP scattering events is conceivable because the new data were collected in summer when the wind is favorable.
- Theory #2: Data-starved particle theorists once again are freaking out for no reason. There is no discovery; CDMS will just publish their new, improved bounds on the scattering cross section of dark matter. CDMS is acting strangely because they want to draw attention: the experimental community is turning toward noble liquid technologies and funding of solid-state detectors like the one in CDMS is endangered.
Important update: I just received this in an email:
It is still true that the new CDMS data are scheduled to be released on December 18th, and there will be presentations in a number of labs around the world. But if there's no Nature paper then theory #2 becomes far more likely.I was alerted to your blog of yesterday (you certainly don't make contacting you easy). Your "fact" #1, that Nature is about to publish a CDMS paper on dark matter, is completely false. This would be instantly obvious to the most casual observer because the purported date of publication is a Friday, and Nature is published on Thursdays. Your "fact" therefore contains as much truth as the average Fox News story, and I would be grateful if you would correct it immediately. Your comments about the embargo are therefore, within this context, ridiculous. Peer review is a process, the culmination of which is publication. We regard confidentiality of results during the process as a matter of professional ethics, though of course authors are free to post to arxiv at any point during the process (we will not interfere with professional communication of results to peers). Dr Leslie Sage Senior editor, physical sciences Nature
Sunday, 6 December 2009
Back on track... what's next?
Unless you just came back from a trip to Jupiter moons you know that the LHC is up and running again. This time, each commissioning step can be followed in real time on blogs, facebook, or twitter, which demonstrates that particle physics has made a huge leap since the last year, at least in technological awareness. After the traumatic events of the last Fall (LHC meltdown, moving to New Jersey) I'm still a little cautious to wag my tail. But the LHC is back on track, no doubt about it, and one small step at a time we will reach high energy collisions early next year.
So what does this mean, in practice?
In the long run - everything.
In the short run - nothing.
The long run stands for 3-4 years. By that time, the LHC should acquire enough data for us to understand the mechanism of electroweak symmetry breaking. Most likely, Higgs will be chased down and its mass and some of its properties will be measured. If there is new physics at the TeV scale we will have some general idea of its shape, even if many details will still be unclear. The majority (all?) of currently fashionable theories will be flushed down the toilet, and the world will never be the same again.
In the short run, though, nothing much is bound to happen. In 2010 the LHC will run at 7 TeV center of mass energy (birds singing that there won't be an energy upgrade next year), which makes its reach rather limited. Furthermore, the 100 inverse picobarns that the LHC is planning produce next year is just one hundredth of what Tevatron will have acquired by the end of the end of 2010. These two facts will make it very hard to beat the existing constraints from Tevatron, unless in some special, very lucky circumstances. So the entire 2010 is going to be an engineering run; things will start to rock only in 2012, after the shutdown in 2011 brings the energy up to 10 TeV and increases the luminosity.
Unless.
Unless, by the end of 2010 Tevatron has a 2-3 sigma indication of a light Higgs boson. In that case, I imagine, CERN might consider the nuclear option. The energy is not that crucial for chasing a light Higgs - the production cross section at 7 TeV is only a factor of two smaller than at 10 TeV, and moreover the background at 7 TeV is also smaller. So CERN might decide to postpone the long shutdown and continue running at 7 TeV for as long as it takes to outrace Tevatron and claim the Higgs discovery. That scenario is not impossible in my opinion, and it would be very attractive for bloggers because it promises blood. But even that, in any case, is more than one year away.
In the meantime, we have to look elsewhere for excitement. Maybe the old creaking Tevatron will draw the lucky number? Or maybe astrophysicists will find a smoking gun in the sky? Or, as I was dreaming early this year, the dark matter particle will be detected. Or maybe it already was? But that wild rumor deserves a separate post ;-)
So what does this mean, in practice?
In the long run - everything.
In the short run - nothing.
The long run stands for 3-4 years. By that time, the LHC should acquire enough data for us to understand the mechanism of electroweak symmetry breaking. Most likely, Higgs will be chased down and its mass and some of its properties will be measured. If there is new physics at the TeV scale we will have some general idea of its shape, even if many details will still be unclear. The majority (all?) of currently fashionable theories will be flushed down the toilet, and the world will never be the same again.
In the short run, though, nothing much is bound to happen. In 2010 the LHC will run at 7 TeV center of mass energy (birds singing that there won't be an energy upgrade next year), which makes its reach rather limited. Furthermore, the 100 inverse picobarns that the LHC is planning produce next year is just one hundredth of what Tevatron will have acquired by the end of the end of 2010. These two facts will make it very hard to beat the existing constraints from Tevatron, unless in some special, very lucky circumstances. So the entire 2010 is going to be an engineering run; things will start to rock only in 2012, after the shutdown in 2011 brings the energy up to 10 TeV and increases the luminosity.
Unless.
Unless, by the end of 2010 Tevatron has a 2-3 sigma indication of a light Higgs boson. In that case, I imagine, CERN might consider the nuclear option. The energy is not that crucial for chasing a light Higgs - the production cross section at 7 TeV is only a factor of two smaller than at 10 TeV, and moreover the background at 7 TeV is also smaller. So CERN might decide to postpone the long shutdown and continue running at 7 TeV for as long as it takes to outrace Tevatron and claim the Higgs discovery. That scenario is not impossible in my opinion, and it would be very attractive for bloggers because it promises blood. But even that, in any case, is more than one year away.
In the meantime, we have to look elsewhere for excitement. Maybe the old creaking Tevatron will draw the lucky number? Or maybe astrophysicists will find a smoking gun in the sky? Or, as I was dreaming early this year, the dark matter particle will be detected. Or maybe it already was? But that wild rumor deserves a separate post ;-)
Thursday, 19 November 2009
Fermi says "nothing"...like sure sure?
I wrote recently about a couple of theory groups who claim to have discovered intriguing signals in the gamma-ray data acquired by the Fermi satellite. The Fermi collaboration hastened to trash both these signals, visibly annoyed by pesky theorists meddling in their affairs. Therefore a status update is in order. Then I'll move to realizing the holy mission of yellow blogs, which is spreading wild rumors.
The first of the theorist's claims concerned the gamma-ray excess from the galactic center, allegedly consistent with a 30 GeV dark matter particle annihilating into b-quark pairs. The relevant data are displayed on this plot released recently by Fermi, which shows the gamma-ray spectrum in the seven-by-seven degrees patch around the galactic center. There indeed seems to be an excess in the 2-4 GeV region. However, given the size of the error bars and of the systematic uncertainties, not to mention how badly we understand the astrophysical processes in the galactic center, one can safely say that there is nothing to be excited about for the moment.
The status of the Fermi haze is far less clear. Here is the story so far. In a recent paper, Doug Finkbeiner and collaborators looked into the Fermi gamma-ray data and found an evidence for a population of very energetic electrons and positrons in the center of our galaxy. These electrons would emit gamma rays when colliding with starlight, in the process known as inverse Compton scattering. They would also emit microwave photons via synchrotron radiation, of which hints are present in the WMAP data. The high-energy electrons could plausibly be a sign of dark matter activity, and fit very well with the PAMELA positron excess, although one cannot exclude that they are produced by conventional astrophysical processes. But Fermi argues that there is no haze in their data. During the Fermi Symposium last week the collaboration was chanting anti-haze songs and tarred-and-feathered anyone humming Hazy shade of winter. Interestingly, it seems that each collaboration member has a slightly different reasons for doubts. Some say the haze is just heavy cosmic-ray elements faking gamma-ray photons. Some say the haze does exist but it can be easily explained by tuned-up galactic models without invoking an energetic population of electrons. Some say the haze is LOOP-1 - a nearby supernova remnant that happens to lie roughly in the direction of the galactic center. But none of the above explanations seems to be on a firm footing, and the jury is definitely out. In the worst case, the matter should be clarified by the Planck satellite (already up in the sky) who is going to make more accurate maps of photon emission at lower frequencies that will lead to a better understanding of astrophysical backgrounds.
And now wild rumors... which, let's make it clear, are likely due to daydreaming over-imagination of data-hungry theorists. The rumors concern Fermi's search for subhalos, which is one of the most promising methods of detecting dark matter in the sky. Subhalos are dwarf galaxies orbiting our Milky Way who are made almost entirely of dark matter. Two dozens of subhalos have been discovered so far (by observing small clumps of stars that they host) but simulations predict several hundreds of these objects. The darkest of the discovered subhalos has a mass-to-light ratio larger than a thousand, indicating large concentration of dark matter. Because of that, one expects dark matter particles to efficiently annihilate and emit gamma rays (typically, via final state radiation or inverse Compton scattering of the annihilation products). Although the resulting gamma-ray flux is expected to be smaller than that from the galactic center, the subhalos with its small visible matter content offer a much cleaner environment to search for a signal.
So, Fermi is searching for spatially extended object away from the galactic plane that steadily emit a lot of gamma rays but are not visible in other frequencies. The results based on 10-months data have been presented in this poster. Apparently, they found no less than four candidates at the 5-sigma level!!! However, according to the poster, these candidates do not fit the spectra of three random dark matter models. For this reason, the conclusion of the search is that no subhalos have been detected, even though it is not clear what astrophysical processes could produce the signal they have found.
Well, I bet an average theorist would need fifteen minutes to write down a dark matter model fitting whatever spectrum Fermi has measured. On the other hand, the collaboration must have better reasons, not revealed to us mortals, to ditch the candidates they have found. On yet another hand, the fact that Fermi is not revealing the positions and the measured spectra of these four candidates makes the matter very very intriguing. So, we need to wait for more data. Or for a snitch :-)
The first of the theorist's claims concerned the gamma-ray excess from the galactic center, allegedly consistent with a 30 GeV dark matter particle annihilating into b-quark pairs. The relevant data are displayed on this plot released recently by Fermi, which shows the gamma-ray spectrum in the seven-by-seven degrees patch around the galactic center. There indeed seems to be an excess in the 2-4 GeV region. However, given the size of the error bars and of the systematic uncertainties, not to mention how badly we understand the astrophysical processes in the galactic center, one can safely say that there is nothing to be excited about for the moment.
The status of the Fermi haze is far less clear. Here is the story so far. In a recent paper, Doug Finkbeiner and collaborators looked into the Fermi gamma-ray data and found an evidence for a population of very energetic electrons and positrons in the center of our galaxy. These electrons would emit gamma rays when colliding with starlight, in the process known as inverse Compton scattering. They would also emit microwave photons via synchrotron radiation, of which hints are present in the WMAP data. The high-energy electrons could plausibly be a sign of dark matter activity, and fit very well with the PAMELA positron excess, although one cannot exclude that they are produced by conventional astrophysical processes. But Fermi argues that there is no haze in their data. During the Fermi Symposium last week the collaboration was chanting anti-haze songs and tarred-and-feathered anyone humming Hazy shade of winter. Interestingly, it seems that each collaboration member has a slightly different reasons for doubts. Some say the haze is just heavy cosmic-ray elements faking gamma-ray photons. Some say the haze does exist but it can be easily explained by tuned-up galactic models without invoking an energetic population of electrons. Some say the haze is LOOP-1 - a nearby supernova remnant that happens to lie roughly in the direction of the galactic center. But none of the above explanations seems to be on a firm footing, and the jury is definitely out. In the worst case, the matter should be clarified by the Planck satellite (already up in the sky) who is going to make more accurate maps of photon emission at lower frequencies that will lead to a better understanding of astrophysical backgrounds.
And now wild rumors... which, let's make it clear, are likely due to daydreaming over-imagination of data-hungry theorists. The rumors concern Fermi's search for subhalos, which is one of the most promising methods of detecting dark matter in the sky. Subhalos are dwarf galaxies orbiting our Milky Way who are made almost entirely of dark matter. Two dozens of subhalos have been discovered so far (by observing small clumps of stars that they host) but simulations predict several hundreds of these objects. The darkest of the discovered subhalos has a mass-to-light ratio larger than a thousand, indicating large concentration of dark matter. Because of that, one expects dark matter particles to efficiently annihilate and emit gamma rays (typically, via final state radiation or inverse Compton scattering of the annihilation products). Although the resulting gamma-ray flux is expected to be smaller than that from the galactic center, the subhalos with its small visible matter content offer a much cleaner environment to search for a signal.
So, Fermi is searching for spatially extended object away from the galactic plane that steadily emit a lot of gamma rays but are not visible in other frequencies. The results based on 10-months data have been presented in this poster. Apparently, they found no less than four candidates at the 5-sigma level!!! However, according to the poster, these candidates do not fit the spectra of three random dark matter models. For this reason, the conclusion of the search is that no subhalos have been detected, even though it is not clear what astrophysical processes could produce the signal they have found.
Well, I bet an average theorist would need fifteen minutes to write down a dark matter model fitting whatever spectrum Fermi has measured. On the other hand, the collaboration must have better reasons, not revealed to us mortals, to ditch the candidates they have found. On yet another hand, the fact that Fermi is not revealing the positions and the measured spectra of these four candidates makes the matter very very intriguing. So, we need to wait for more data. Or for a snitch :-)
Saturday, 7 November 2009
Higgs chased away from another hole
The hunt for the Higgs continues. Tevatron is running at full steam hoping to catch a glimpse of the sucker before the LHC joins in the game. If the standard model is correct, the entire range of allowed Higgs masses will be covered within next 3-4 years. But there is one disturbing puzzle: indirect measurement indicate that we should have already found the Higgs! Indeed, precision measurements at LEP and Tevatron - mostly lepton asymmetries of Z decay and the value of the W boson mass - are best explained if the Higgs mass is some 80-90 GeV, whereas the direct limit from LEP implies that it must be heavier than 115 GeV.
There is one more reason, this time purely theoretical, to expect that the Higgs may be lighter than the naive LEP bound. If supersymmetry is relevant at the weak scale it is in general very uncomfortable with a heavy Higgs. Well, they keep telling you that the upper limit in the MSSM is 130 GeV. But that requires stretching the parameters of the model to the point of breaking, while the natural prediction is 90-100 GeV. Indeed, not finding the Higgs at LEP is probably the primary reason to disbelieve that supersymmetry is relevant at low energies.
Is it possible that Higgs is lighter than 115 GeV and LEP missed it? The answer is yes, because the LEP searches have left many loopholes. Sensitivity of LEP analyses deteriorates if the Higgs decays into a many-body final state, which is possible in some extensions of the standard model. One popular theory where this could happen is the NMSSM - the 2.0 version of the MSSM with an additional singlet. Roughly, the Higgs could first decay into the new singlet, who in turn decays into two tau leptons, which amounts to Higgs decaying into four tau leptons. This funny decay topology could escape LEP searches even if the Higgs is as light as 86 GeV! That is the case not because of deep physical reasons, but simply because LEP collaborations were too lazy to search for it (in comparison, Higgs decaying into four b-quarks, which was studied by LEP, is excluded for the Higgs mass up to 110 GeV).
But not anymore - this particular gaping hole has been recently sealed. A group of brave adventure-seekers ventured into CERN caverns, excavated the ancient LEP data and analyzed them lookig for the Higgs-to-4tau signal. The results were presented this week at the ALEPH meeting celebrating the 20th anniversary and 9th anniversary of its demise. Of course, there is nothing there, in case you had any doubts. The new limit for the Higgs-to-4tau channel excludes the Higgs mass smaller than 105-110 GeV. Yet the beautiful thing in that analysis is that going back to the LEP data is still possible, if only there is reason, and will, and cheap work force.
So, is the idea of the hidden light Higgs dead? It has definitely received a serious blow, but it can still survive in some perverse models where Higgs decays into four light jets, at least until someone ventures to kill that too. Anyway, never say dead; there is no experimental results that theorists could not find a way around ;-)
There is one more reason, this time purely theoretical, to expect that the Higgs may be lighter than the naive LEP bound. If supersymmetry is relevant at the weak scale it is in general very uncomfortable with a heavy Higgs. Well, they keep telling you that the upper limit in the MSSM is 130 GeV. But that requires stretching the parameters of the model to the point of breaking, while the natural prediction is 90-100 GeV. Indeed, not finding the Higgs at LEP is probably the primary reason to disbelieve that supersymmetry is relevant at low energies.
Is it possible that Higgs is lighter than 115 GeV and LEP missed it? The answer is yes, because the LEP searches have left many loopholes. Sensitivity of LEP analyses deteriorates if the Higgs decays into a many-body final state, which is possible in some extensions of the standard model. One popular theory where this could happen is the NMSSM - the 2.0 version of the MSSM with an additional singlet. Roughly, the Higgs could first decay into the new singlet, who in turn decays into two tau leptons, which amounts to Higgs decaying into four tau leptons. This funny decay topology could escape LEP searches even if the Higgs is as light as 86 GeV! That is the case not because of deep physical reasons, but simply because LEP collaborations were too lazy to search for it (in comparison, Higgs decaying into four b-quarks, which was studied by LEP, is excluded for the Higgs mass up to 110 GeV).
But not anymore - this particular gaping hole has been recently sealed. A group of brave adventure-seekers ventured into CERN caverns, excavated the ancient LEP data and analyzed them lookig for the Higgs-to-4tau signal. The results were presented this week at the ALEPH meeting celebrating the 20th anniversary and 9th anniversary of its demise. Of course, there is nothing there, in case you had any doubts. The new limit for the Higgs-to-4tau channel excludes the Higgs mass smaller than 105-110 GeV. Yet the beautiful thing in that analysis is that going back to the LEP data is still possible, if only there is reason, and will, and cheap work force.
So, is the idea of the hidden light Higgs dead? It has definitely received a serious blow, but it can still survive in some perverse models where Higgs decays into four light jets, at least until someone ventures to kill that too. Anyway, never say dead; there is no experimental results that theorists could not find a way around ;-)
Friday, 30 October 2009
Hail to Freedom
Experimental collaborations display vastly different attitudes toward sharing their data. In my previous post I described an extreme approach bordering on schizophrenia. On the other end of the spectrum is the Fermi collaboration (hail to Fermi). After one year of taking and analyzing data they posted on a public website the energy and direction of every gamma-ray photon they had detected. This is of course the standard procedure for all missions funded by NASA (hail to NASA). Now everybody, from a farmer in the Guangxi province to a professor in Harvard, has a chance to search for dark matter using real data.
The release of the Fermi data has already spawned two independent analyses by theorists. One is being widely discussed on blogs (here and here) and in popular magazines, whereas the other paper passed rather unnoticed. Both papers claim to have discovered an effect overlooked by the Fermi collaboration, and both hint to dark matter as the origin.
The first (chronologically, the second) of the two papers provides a new piece of evidence that the center of our galaxy hosts the so-called haze - a population of hard electrons (and/or positrons) whose spectrum is difficult to explain by conventional astrophysical processes. The haze was first observed by Jimi Hendrix ('Scuse me while I kiss the sky). Later, Doug Finkbeiner came across the haze when analyzing maps of cosmic microwave radiation provided by WMAP; in fact, that was also an independent analysis of publicly released data (hail to WMAP). The WMAP haze is supposedly produced by synchrotron radiation of the electrons. But the same electrons should also produce gamma rays when interacting with the interstellar light in the process known as the inverse Compton scattering (Inverse Compton was the younger brother of Arthur), the ICS in short. The claim is that Fermi has detected these ICS photons. You can even see it yourself if you stare long enough into the picture.
The second paper also takes a look at the gamma rays arriving from the the galactic center, but uncovers a completely different signature. There seems to be a bumpy feature around a few GeV that does not fit a simple power-law spectrum expected from the background. The paper says that a dark matter particle of mass around 30 GeV annihilating into b quark pairs can fit the bump. The required annihilation cross section is fairly low, of order $10^{-25} cm^3/s$, only a factor of 3 larger than that needed to explain the observed abundance of dark matter via a thermal relic. That would put this dark matter particle closer to a standard WIMP, as opposed to the recently popular dark matter particles designed to explain the PAMELA positron excess who need a much larger mass and cross section.
Sadly, collider physics has a long way to go before reaching the same level of openness. Although collider experiments are 100% financed by public funds, and although acquired data have no commercial value, the data remains a property of the collaboration without ever being publicly released, not even after the collaboration has dissolved into nothingness. The only logical reason to explain that is inertia - a quick and easy access to data and analysis tools has only quite recently become available to everybody. Another argument raised on that occasion is that only the collaboration who produced the data is able to understand and properly handle them. That is of course irrelevant. Surely, the collaboration can make any analysis ten times better and more reliably. However, some analyses are simply never done either due to lack of manpower or laziness, and others are marred by theoretical prejudices. The LEP experiment is a perfect example here. Several important searches have never been done because, at the time, there was no motivation from popular theories. In particular, it is not excluded that the Higgs boson exist with a mass accessible to LEP (that is less than 115 GeV), but it was missed because some possible decay channels have not been studied. It may well be that ground breaking discoveries are stored on the LEP tapes rotting on dusty shelves in CERN catacombs. That danger could be easily avoided if the LEP data were publicly available in an accessible form.
In the end, what do we have to lose? In the worst case scenario, the unrestricted access to data will just lead to more entries in my blog ;-)
Update: At the FERMI Symposium this week in Washington the collaboration trashed both of the above dark matter claims.
The release of the Fermi data has already spawned two independent analyses by theorists. One is being widely discussed on blogs (here and here) and in popular magazines, whereas the other paper passed rather unnoticed. Both papers claim to have discovered an effect overlooked by the Fermi collaboration, and both hint to dark matter as the origin.
The first (chronologically, the second) of the two papers provides a new piece of evidence that the center of our galaxy hosts the so-called haze - a population of hard electrons (and/or positrons) whose spectrum is difficult to explain by conventional astrophysical processes. The haze was first observed by Jimi Hendrix ('Scuse me while I kiss the sky). Later, Doug Finkbeiner came across the haze when analyzing maps of cosmic microwave radiation provided by WMAP; in fact, that was also an independent analysis of publicly released data (hail to WMAP). The WMAP haze is supposedly produced by synchrotron radiation of the electrons. But the same electrons should also produce gamma rays when interacting with the interstellar light in the process known as the inverse Compton scattering (Inverse Compton was the younger brother of Arthur), the ICS in short. The claim is that Fermi has detected these ICS photons. You can even see it yourself if you stare long enough into the picture.
The second paper also takes a look at the gamma rays arriving from the the galactic center, but uncovers a completely different signature. There seems to be a bumpy feature around a few GeV that does not fit a simple power-law spectrum expected from the background. The paper says that a dark matter particle of mass around 30 GeV annihilating into b quark pairs can fit the bump. The required annihilation cross section is fairly low, of order $10^{-25} cm^3/s$, only a factor of 3 larger than that needed to explain the observed abundance of dark matter via a thermal relic. That would put this dark matter particle closer to a standard WIMP, as opposed to the recently popular dark matter particles designed to explain the PAMELA positron excess who need a much larger mass and cross section.
Sadly, collider physics has a long way to go before reaching the same level of openness. Although collider experiments are 100% financed by public funds, and although acquired data have no commercial value, the data remains a property of the collaboration without ever being publicly released, not even after the collaboration has dissolved into nothingness. The only logical reason to explain that is inertia - a quick and easy access to data and analysis tools has only quite recently become available to everybody. Another argument raised on that occasion is that only the collaboration who produced the data is able to understand and properly handle them. That is of course irrelevant. Surely, the collaboration can make any analysis ten times better and more reliably. However, some analyses are simply never done either due to lack of manpower or laziness, and others are marred by theoretical prejudices. The LEP experiment is a perfect example here. Several important searches have never been done because, at the time, there was no motivation from popular theories. In particular, it is not excluded that the Higgs boson exist with a mass accessible to LEP (that is less than 115 GeV), but it was missed because some possible decay channels have not been studied. It may well be that ground breaking discoveries are stored on the LEP tapes rotting on dusty shelves in CERN catacombs. That danger could be easily avoided if the LEP data were publicly available in an accessible form.
In the end, what do we have to lose? In the worst case scenario, the unrestricted access to data will just lead to more entries in my blog ;-)
Update: At the FERMI Symposium this week in Washington the collaboration trashed both of the above dark matter claims.
Tuesday, 27 October 2009
What's really behind DAMA
More than once I wrote in this blog about crazy theoretical ideas to explain the DAMA modulation signal. There is a good excuse. In this decade, DAMA has been the main source of inspiration to extend dark matter model building beyond the simple WIMP paradigm, in particular inelastic dark matter was conceived that way. This in turn has prompted to tighten the net of experimental searches to include signals from non-WIMP dark matter particles. More importantly, blog readers always require sensation, scandal and blood (I know, I'm a reader myself), so that spectacular new physics explanations are always preferred. Nevertheless, prompted by a commenter, I thought it might be useful to balance a bit and describe a more trivial explanation of the DAMA signal that involves a systematic effect rather than dark matter particles.
Unlike most dark matter detection experiments, the DAMA instrument has no sophisticated background rejection (they only reject coincident hits in multiple crystals). That might be an asset, because they are a priori sensitive to a variety of dark matter particles, whether scattering elastically or inelastically, whether scattering on nucleons or electrons, and so on. But at the same time most of their hits comes from mundane and poorly controlled sources such as natural radioactivity, which makes them vulnerable unknown or underestimated backgrounds.
One important source of the background is a contamination of DAMA's sodium-iodine crystals with radioactive elements like Uranium 238, Iodine 129 and Potassium 40. The last one is the main culprit because some of its decay products have the same energy as the putative DAMA signal. Potassium, being in the same Mendeleev column as sodium, can easily sneak into the lattice of the crystal. The radioactive isotope 40K is present with roughly 0.01 percent abundance in natural potassium. Ten percent of the times 40K decays to an excited state of Argon 40, which is followed by a de-excitation photon at 1.4 MeV and emission of Auger electrons with energy 3.2 keV. This process is known to occur in the DAMA detector with a sizable rate; in fact DAMA itself measured that background by looking for coincidences of MeV photons and 3 keV scintillation signals, see the plot above. That same background is also responsible for the little peak at 3keV in the single hit spectrum measured by DAMA, see below (note that this is not the modulated spectrum on which DAMA claim is based!). The peak here is exactly due to the Auger radiation.
Now, look at the spectrum of the time dependent component of the signal where DAMA claims to have found evidence for dark matter. The peak of the annual modulation signal occurs precisely at 3 keV.The fact that the putative signal is on top of the known background is VERY suspicious.
One should admit that it is not entirely clear what could cause the modulation of the background,
although some subtle annual effect affecting the efficiency for detecting the Auger radiation is not implausible. So far, DAMA has not shown any convincing arguments that would exclude 40K as the origin of their modulation signal.
Actually, it is easy to check whether it's 40K or not. Just put one of the DAMA crystals inside the environment where the efficiency for detecting the decay products of 40K is nearly 100 percent. Like for example, in the Borexino balloon that is waiting next door in the Gran Sasso Laboratory. In fact, the Borexino collaboration has made this very proposal to DAMA. The answer was a resounding no.
There is another way Borexino could quickly refute or confirm the DAMA claim. Why not buying the sodium-iodine crystals directly from Saint Gobain - the company that provided the crystals for DAMA? Not so fast. In the contract, DAMA has secured exclusive eternal rights for the use of sodium-iodine crystals produced by Saint Gobain. At this point it comes as no surprise that DAMA threatens legal actions if the company attempts to breach their "intellectual" property.
There is more stories that make hair on your chest stand on end. One often hears the phrase "a very specific collaboration" when referring to DAMA, which is a roundabout way of saying "a bunch of assholes". Indeed DAMA has worked very hard to earn their bad reputation, and sometimes it's difficult to tell whether at the roots is only paranoia or also bad will. The problem, however, is that history of physics has a few examples of technologically or intellectually less sophisticated experiments beating better competitors - take Penzias and Wilson for example.
So we will never know for sure whether the DAMA signal is real or not until it is definitely refuted or confirmed by another experiment. Fortunately, it seems that the people from Borexino have not given up yet. Recently I heard a talk of Cristiano Galbiati who said that the Princeton group is planning to grow their own sodium-iodine crystals. That will take time, but an advantage is that they will be able to obtain better, more radio-pure crystals, and thus reduce the potassium 40 background by many orders of magnitude. So maybe in two years from now the dark matter will be cleared...
Unlike most dark matter detection experiments, the DAMA instrument has no sophisticated background rejection (they only reject coincident hits in multiple crystals). That might be an asset, because they are a priori sensitive to a variety of dark matter particles, whether scattering elastically or inelastically, whether scattering on nucleons or electrons, and so on. But at the same time most of their hits comes from mundane and poorly controlled sources such as natural radioactivity, which makes them vulnerable unknown or underestimated backgrounds.
One important source of the background is a contamination of DAMA's sodium-iodine crystals with radioactive elements like Uranium 238, Iodine 129 and Potassium 40. The last one is the main culprit because some of its decay products have the same energy as the putative DAMA signal. Potassium, being in the same Mendeleev column as sodium, can easily sneak into the lattice of the crystal. The radioactive isotope 40K is present with roughly 0.01 percent abundance in natural potassium. Ten percent of the times 40K decays to an excited state of Argon 40, which is followed by a de-excitation photon at 1.4 MeV and emission of Auger electrons with energy 3.2 keV. This process is known to occur in the DAMA detector with a sizable rate; in fact DAMA itself measured that background by looking for coincidences of MeV photons and 3 keV scintillation signals, see the plot above. That same background is also responsible for the little peak at 3keV in the single hit spectrum measured by DAMA, see below (note that this is not the modulated spectrum on which DAMA claim is based!). The peak here is exactly due to the Auger radiation.
Now, look at the spectrum of the time dependent component of the signal where DAMA claims to have found evidence for dark matter. The peak of the annual modulation signal occurs precisely at 3 keV.The fact that the putative signal is on top of the known background is VERY suspicious.
One should admit that it is not entirely clear what could cause the modulation of the background,
although some subtle annual effect affecting the efficiency for detecting the Auger radiation is not implausible. So far, DAMA has not shown any convincing arguments that would exclude 40K as the origin of their modulation signal.
Actually, it is easy to check whether it's 40K or not. Just put one of the DAMA crystals inside the environment where the efficiency for detecting the decay products of 40K is nearly 100 percent. Like for example, in the Borexino balloon that is waiting next door in the Gran Sasso Laboratory. In fact, the Borexino collaboration has made this very proposal to DAMA. The answer was a resounding no.
There is another way Borexino could quickly refute or confirm the DAMA claim. Why not buying the sodium-iodine crystals directly from Saint Gobain - the company that provided the crystals for DAMA? Not so fast. In the contract, DAMA has secured exclusive eternal rights for the use of sodium-iodine crystals produced by Saint Gobain. At this point it comes as no surprise that DAMA threatens legal actions if the company attempts to breach their "intellectual" property.
There is more stories that make hair on your chest stand on end. One often hears the phrase "a very specific collaboration" when referring to DAMA, which is a roundabout way of saying "a bunch of assholes". Indeed DAMA has worked very hard to earn their bad reputation, and sometimes it's difficult to tell whether at the roots is only paranoia or also bad will. The problem, however, is that history of physics has a few examples of technologically or intellectually less sophisticated experiments beating better competitors - take Penzias and Wilson for example.
So we will never know for sure whether the DAMA signal is real or not until it is definitely refuted or confirmed by another experiment. Fortunately, it seems that the people from Borexino have not given up yet. Recently I heard a talk of Cristiano Galbiati who said that the Princeton group is planning to grow their own sodium-iodine crystals. That will take time, but an advantage is that they will be able to obtain better, more radio-pure crystals, and thus reduce the potassium 40 background by many orders of magnitude. So maybe in two years from now the dark matter will be cleared...
Monday, 5 October 2009
Early LHC Discoveries
It seems that the LHC restart will not be significantly delayed beyond this November. The moment when first protons collide at 7 TeV energy will send particle theorists into an excited state. From day one, we will start harassing our CMS and ATLAS colleagues, begging for a hint of an excess in the data, or offering sex for a glimpse on invariant mass distributions. That will be the case in spite of the very small odds for seeing any new physics during the first months. Indeed, the results acquired so far by the Tevatron make it very unlikely that spectacular phenomena could show up in the early LHC. Although the LHC in the first year will operate at a 3 times larger energy, the Tevatron will have the advantage of 100 times larger integrated luminosity, not to mention the better understanding of their detectors.
Nevertheless, it's fun to play the following game of imagination: what kind of new physics could show up in the early LHC without having been already discovered at the Tevatron? For that, two general conditions have to be satisfied:
The possible couplings of Z' to quarks and leptons can be theoretically constrained: imposing anomaly cancellation, flavor independence, and the absence of exotic fermions at the TeV scale implies that the charges of the new U(1) acts on the standard model fermions as a linear combination of the familiar hypercharge and the B-L global symmetry. Thus, one can describe the parameter space of these Z' models by just three parameters: two couplings gY and gB-L and the Z' mass. This simple parametrization allows us to quickly scan through all possibilities. An example slice of the parameter space for the Z' mass 700 GeV is shown on the picture to the right. The region allowed by the Tevatron searches is painted blue, while the region allowed by electroweak precision tests is pink (the coupling of Z' to the electrons induces effective four-fermion operators that have been constrained by the LEP-II experiment). As you can see, these two constraints imply that both couplings have to be smallish, of order 0.2 at the most, which is even less than the hypercharge coupling g' in the standard model. That in turn implies that the production cross section at the LHC will be suppressed. Indeed, the region where the discovery at the LHC with 7 TeV and 100 inverse picobarns is impossible, marked as yellow, almost fully overlaps with the allowed parameter space. Only a tiny region (red arrow) is left for that particular mass, but even that pathetic scrap is likely to be wiped once the Tevatron updates their Z' analyses.
The above example illustrates how difficult is to cook up a model suitable for an early discovery at the LHC. A part of the reason why Z' is not a good candidate is that it is produced by quark-antiquark collisions. That is a frequent occurrence in the proton-antiproton collider like the Tevatron, whereas at the LHC, who is a proton-proton collider, one has to pay the PDF price of finding an antiquark in the proton. An interesting way out that goes under the name of diquark resonance was proposed in another recent paper. If the new resonance carries the quantum numbers of two quarks (rather than quark-antiquark pair) then the LHC would have a tremendous advantage over the Tevatron, as the resonance could be produced in quark-quark collisions that are more frequent at the LHC. Because of that, a large number of diquark events may be produced at the LHC in spite of the Tevatron constraints. The remaining piece of model building is to ensure that the diquark resonance decays to leptons often enough.
Diquarks are not present in the most popular extensions of the standard model and therefore they might appear to be artificial constructs. However, they can be found in somewhat more exotic models like for example the MSSM with a broken R-parity. That model allows for couplings like $u^c d^c \tilde b^c$, where $u^c,d^c$ are right-handed up and down quarks, while $\tilde b^c$ is the scalar partner of the right-handed bottom quark called the (right) sbottom. Obviously, this coupling violates R-symmetry because it contains only one superparticle (in the standard MSSM, supersymmetric particles couple always in pairs). The sbottom could then be produced by collisions of up and down quarks, both of which are easy to find in protons.
Decays of the sbottom are very model dependent: the parameter space of supersymmetric theories is as good as infinite and can accommodate numerous possibilities. Typically, the sbottom will undergo a complex cascade decay that may or may not involve leptons. For example, if the lightest supersymmetric particle is the scalar partner of the electron, then the sbottom can decay into a bottom quark + a neutralino who decays into an electron + a selectron who finally decays into an electron and 3 quarks:
$\tilde b^c -> b \chi^1 -> b e \tilde e -> b e e j j j$
As a result, the LHC would observe two hard electrons plus a number of jets in the final state, something that should not be missed.
To wrap up, the first year at the LHC will likely end up being an "engineering run", where the standard model will be "discovered" to the important end of calibrating the detectors. However, if the new physics is exotic enough, and the stars are lucky enough, then there might be some real excitement store.
Nevertheless, it's fun to play the following game of imagination: what kind of new physics could show up in the early LHC without having been already discovered at the Tevatron? For that, two general conditions have to be satisfied:
- There has to be a resonance coupled to the light quarks (so that it can be produced at the LHC with a large enough cross section) whose mass is just above the Tevatron reach, say 700-1000 GeV (so that the cross section at the Tevatron, but not at the LHC, is kinematically suppressed).
- The resonance has to decay to electrons or muons with a sizable branching fraction (so that the decay products can be seen in relatively clean and background-free channels).
The possible couplings of Z' to quarks and leptons can be theoretically constrained: imposing anomaly cancellation, flavor independence, and the absence of exotic fermions at the TeV scale implies that the charges of the new U(1) acts on the standard model fermions as a linear combination of the familiar hypercharge and the B-L global symmetry. Thus, one can describe the parameter space of these Z' models by just three parameters: two couplings gY and gB-L and the Z' mass. This simple parametrization allows us to quickly scan through all possibilities. An example slice of the parameter space for the Z' mass 700 GeV is shown on the picture to the right. The region allowed by the Tevatron searches is painted blue, while the region allowed by electroweak precision tests is pink (the coupling of Z' to the electrons induces effective four-fermion operators that have been constrained by the LEP-II experiment). As you can see, these two constraints imply that both couplings have to be smallish, of order 0.2 at the most, which is even less than the hypercharge coupling g' in the standard model. That in turn implies that the production cross section at the LHC will be suppressed. Indeed, the region where the discovery at the LHC with 7 TeV and 100 inverse picobarns is impossible, marked as yellow, almost fully overlaps with the allowed parameter space. Only a tiny region (red arrow) is left for that particular mass, but even that pathetic scrap is likely to be wiped once the Tevatron updates their Z' analyses.
The above example illustrates how difficult is to cook up a model suitable for an early discovery at the LHC. A part of the reason why Z' is not a good candidate is that it is produced by quark-antiquark collisions. That is a frequent occurrence in the proton-antiproton collider like the Tevatron, whereas at the LHC, who is a proton-proton collider, one has to pay the PDF price of finding an antiquark in the proton. An interesting way out that goes under the name of diquark resonance was proposed in another recent paper. If the new resonance carries the quantum numbers of two quarks (rather than quark-antiquark pair) then the LHC would have a tremendous advantage over the Tevatron, as the resonance could be produced in quark-quark collisions that are more frequent at the LHC. Because of that, a large number of diquark events may be produced at the LHC in spite of the Tevatron constraints. The remaining piece of model building is to ensure that the diquark resonance decays to leptons often enough.
Diquarks are not present in the most popular extensions of the standard model and therefore they might appear to be artificial constructs. However, they can be found in somewhat more exotic models like for example the MSSM with a broken R-parity. That model allows for couplings like $u^c d^c \tilde b^c$, where $u^c,d^c$ are right-handed up and down quarks, while $\tilde b^c$ is the scalar partner of the right-handed bottom quark called the (right) sbottom. Obviously, this coupling violates R-symmetry because it contains only one superparticle (in the standard MSSM, supersymmetric particles couple always in pairs). The sbottom could then be produced by collisions of up and down quarks, both of which are easy to find in protons.
Decays of the sbottom are very model dependent: the parameter space of supersymmetric theories is as good as infinite and can accommodate numerous possibilities. Typically, the sbottom will undergo a complex cascade decay that may or may not involve leptons. For example, if the lightest supersymmetric particle is the scalar partner of the electron, then the sbottom can decay into a bottom quark + a neutralino who decays into an electron + a selectron who finally decays into an electron and 3 quarks:
$\tilde b^c -> b \chi^1 -> b e \tilde e -> b e e j j j$
As a result, the LHC would observe two hard electrons plus a number of jets in the final state, something that should not be missed.
To wrap up, the first year at the LHC will likely end up being an "engineering run", where the standard model will be "discovered" to the important end of calibrating the detectors. However, if the new physics is exotic enough, and the stars are lucky enough, then there might be some real excitement store.
Sunday, 27 September 2009
Resonating dark matter
On this blog I regularly follow the progress in dark matter building. One reason is that next-to-nothing is happening on the collider front: Tevatron invariably confirms the standard model predictions up to a few pathetic 2 point null sigma bleeps now and then. In these grim times particle theorists sit entrenched inside their old models waiting for the imminent LHC assault. The dark matter industry, on the other hand, enjoys a flood of exciting experimental data, including a number of puzzling results that might be hints of new physics.
One of these puzzles - the anomalous modulation signal reported by DAMA - continues to inspire theorists. It is a challenge to reconcile DAMA with null results from other experiment, and any model attempting that has to go beyond the simple picture of elastic scattering of dark matter on nuclei. The most plausible proposal so far is the so-called inelastic dark matter. Last week a new idea entered the market under the name of resonant dark matter. Since this blog warmly embraces all sorts of resonances I couldn't miss the opportunity to share a few words about it.
In the resonant dark matter scenario the dark matter particle is a part of a larger multiplet that transforms under weak SU(2). This means that the dark matter particle (who as usual is electrically neutral) has partners of approximately the same mass that carry an electric charge. Quantum effects split the masses of charged and neutral particles making the charged guys a bit heavier (this is completely analogous to the $\pi_+ - \pi_0$ mass splitting in the standard model). Most naturally, that splitting would be of order 100 MeV; some theoretical hocus-pocus is needed to lower it down to 10 MeV (otherwise the splitting is to large compared to nuclear scales, and the idea cannot be implemented in practice), which is presumably the weakest point in this construction.
Now, when dark matter particles scatter on nuclei in a detector there is a possibility of forming a narrow bound state of the charged partner with an excited state of the nucleus, see the picture. That would imply that the scattering cross-section sharply peaks at a certain velocity corresponding to the resonance.The existence of the resonance is very sensitive to many nuclear parameters: mass, charge, atomic number and the energies of excitation levels. It is conceivable that the resonant enhancement occurs only for one target, say, iodine present in DAMA's sodium-iodine crystals, while it is absent for other targets like germanium, silicon, xenon etc. that are employed in other dark matter experiments. For example, the resonant velocity for these other elements might be outside the range of velocities of dark matter in our galaxy (the escape velocity is some 500 km/s so that there is an upper limit to scattering velocities).
So, that looks like a perfect hideaway for DAMA, as other experiment would have a hard time exclude the resonant dark matter hypothesis in a model independent way. Fortunately, there is another ongoing dark matter experiment involving iodine: the Korean KIMS based on cesium-iodine crystals. After one year of data taking the results from KIMS combined with those from DAMA put some constraints on the allowed values of the dark matter mass, the position of the resonance and its width, but they leave large chunks of allowed parameter space. More data from KIMS will surely shed more light on the resonant dark matter scenario.
One of these puzzles - the anomalous modulation signal reported by DAMA - continues to inspire theorists. It is a challenge to reconcile DAMA with null results from other experiment, and any model attempting that has to go beyond the simple picture of elastic scattering of dark matter on nuclei. The most plausible proposal so far is the so-called inelastic dark matter. Last week a new idea entered the market under the name of resonant dark matter. Since this blog warmly embraces all sorts of resonances I couldn't miss the opportunity to share a few words about it.
In the resonant dark matter scenario the dark matter particle is a part of a larger multiplet that transforms under weak SU(2). This means that the dark matter particle (who as usual is electrically neutral) has partners of approximately the same mass that carry an electric charge. Quantum effects split the masses of charged and neutral particles making the charged guys a bit heavier (this is completely analogous to the $\pi_+ - \pi_0$ mass splitting in the standard model). Most naturally, that splitting would be of order 100 MeV; some theoretical hocus-pocus is needed to lower it down to 10 MeV (otherwise the splitting is to large compared to nuclear scales, and the idea cannot be implemented in practice), which is presumably the weakest point in this construction.
Now, when dark matter particles scatter on nuclei in a detector there is a possibility of forming a narrow bound state of the charged partner with an excited state of the nucleus, see the picture. That would imply that the scattering cross-section sharply peaks at a certain velocity corresponding to the resonance.The existence of the resonance is very sensitive to many nuclear parameters: mass, charge, atomic number and the energies of excitation levels. It is conceivable that the resonant enhancement occurs only for one target, say, iodine present in DAMA's sodium-iodine crystals, while it is absent for other targets like germanium, silicon, xenon etc. that are employed in other dark matter experiments. For example, the resonant velocity for these other elements might be outside the range of velocities of dark matter in our galaxy (the escape velocity is some 500 km/s so that there is an upper limit to scattering velocities).
So, that looks like a perfect hideaway for DAMA, as other experiment would have a hard time exclude the resonant dark matter hypothesis in a model independent way. Fortunately, there is another ongoing dark matter experiment involving iodine: the Korean KIMS based on cesium-iodine crystals. After one year of data taking the results from KIMS combined with those from DAMA put some constraints on the allowed values of the dark matter mass, the position of the resonance and its width, but they leave large chunks of allowed parameter space. More data from KIMS will surely shed more light on the resonant dark matter scenario.
Tuesday, 22 September 2009
Scherzo II
I'm still in a holiday mood so forgive one more prank before moving to serious physics (as if this blog were ever serious ;-). Traveling to conferences this summer I noticed that humans had acquired a new useful skill. Have a look at this picture:
and another:
and there are many more similar ones stored on my disc ;-) Of course, the interesting point here is not sleeping during a talk - everybody does that. The remarkable point is perfect balancing of a laptop while sleeping. In the extreme case it went on for 45 min without awaking and without dropping the laptop to the floor. Amazing!
Using Darwin's theory of evolution one can predict that this new skill will quickly spread in the scientific community.Those who do not possess it will inevitably destroy their laptops while sleeping at conferences, thus losing years of work and dropping in the academic ranking. As a consequence, these handicapped ones will acquire less mating partners and thus less chances to pass their genes. Unless laptops become shock resistant in the meantime.
and another:
and there are many more similar ones stored on my disc ;-) Of course, the interesting point here is not sleeping during a talk - everybody does that. The remarkable point is perfect balancing of a laptop while sleeping. In the extreme case it went on for 45 min without awaking and without dropping the laptop to the floor. Amazing!
Using Darwin's theory of evolution one can predict that this new skill will quickly spread in the scientific community.Those who do not possess it will inevitably destroy their laptops while sleeping at conferences, thus losing years of work and dropping in the academic ranking. As a consequence, these handicapped ones will acquire less mating partners and thus less chances to pass their genes. Unless laptops become shock resistant in the meantime.
Monday, 21 September 2009
Scherzo
Last week I was stranded at a conference far in Italy. There was no internet to speak of; instead, the venue was offering alternative commodities. Like for example a chapel:
It striked me as a really good idea. They say that science and religion cannot go hand in hand, but that's obviously not true. Take the first example in a row: the Higgs searches at Tevatron.
According to the plot on the right, Tevatron has roughly a 30 percent chance of finding a 3 sigma evidence for the Higgs in the most interesting region between 115 and 130 GeV. Since we speak of chances the matter is open for prayers. Therefore chapels should be available not only at conferences but also at every accelerator facility.
In that case one would expect the following pattern:
It striked me as a really good idea. They say that science and religion cannot go hand in hand, but that's obviously not true. Take the first example in a row: the Higgs searches at Tevatron.
According to the plot on the right, Tevatron has roughly a 30 percent chance of finding a 3 sigma evidence for the Higgs in the most interesting region between 115 and 130 GeV. Since we speak of chances the matter is open for prayers. Therefore chapels should be available not only at conferences but also at every accelerator facility.
In that case one would expect the following pattern:
- Tevatron would pray that they find the Higgs
- The LHC would pray that Tevatron does not find the Higgs
- Graduate students at the LHC would pray for any data at all before they turn fifty
- Everybody would pray that the magnets do not explode
- Except for Hawaii surfers and Holger Nielsen who would pray for the contrary
Friday, 28 August 2009
New ideas in dark matter
I keep receiving complaints about my meager blogging output. Concerning the last few weeks I have a good excuse: I was studying Mont Blanc (that narrow resonance visible at the LHC on a clear day); and after that I was being tired; and after that I was being lazy; and in any case nothing happens during summer months.
But the coming autumn is going to be exciting. The approaching LHC start-up is one but not the unique reason. On a completely different frontier, huge progress is expected in the area of direct detection of dark matter. The XENON100 experiment in Gran Sasso is going to kick off next month, while its bitter enemy - the LUX experiment in the Homestake mine - is hoping to follow before the end of the year. Within one year experimental sensitivity to the WIMP-nucleon cross section should be improved by two orders of magnitude, biting deep into the parameter space region where numerous popular theories predict a signal.
In the best case scenario the very first months or even days can lead to a discovery. This is the prediction of the dark matter models designed to resolve the DAMA puzzle. Recall that the DAMA experiment in Gran Sasso claims to have detected dark matter by observing the annual modulation of the count rate in their sodium-iodine detector. Particle theorists struggle to reconcile the DAMA signal with the null results from a dozen of other, in principle more sensitive, experiments. That is not quite impossible because various experiments use different targets and different detection techniques, in particular, the masses of the target nuclei as well as the range of the observable recoil energies are specific to each experiment. The game is thus to arrange the properties of dark matter such that the nuclear recoils due to scattering of dark matter particles could have been observed only by DAMA.
The standard WIMP is not an option here: DAMA would require large cross section at the level that has been excluded by CDMS, XENON10 (the little brother of XENON100) and others. But theorists are not easily discouraged and they are trying to come up with alternative ideas. Recently the so-called inelastic dark matter has gained a lot of publicity. In that scenario, dark matter particles scatter inelastically off nuclei into a slightly (hundred of keV) heavier state. Thus, one needs to provide enough energy to produce the heavier state which implies a minimum velocity of the initial dark matter particle for the scattering to occur. The splitting can be tuned such that DAMA is able to see the signal while the others are not. That of course requires some amount of conspiracy. Fortunately, the inelastic dark matter theory predicts a thunderstorm of events in the upcoming runs of XENON100 and LUX.
Until recently inelastic dark matter was the only plausible explanation of DAMA. But this week there was a paper exploring a different idea. In this new scenario, the scattering of dark matter on nucleons is elastic, but the scattering amplitude depends in a non-trivial way on the momentum transfer, hence the name form factor dark matter. If the form factor is suppressed outside the window to which DAMA happens to be sensitive, the null results of other experiments can be explained.
Non-trivial form factors can be arranged by some dirty model building tricks. The paper presents an example of a scalar dark matter particle with dipole-type ($D_\mu X^\dagger D_\nu X F_{\mu\nu}$) interactions with some new hidden vector fields. The latter mix with the photon which provides a coupling to the ordinary matter. To explain the DAMA phenomenology one needs at least two vector fields with opposite couplings to the photon and comparable masses, which makes the whole construction a bit contrived. Again, the model predicts a characteristic recoil spectrum, and a large number of events in XENON100 and LUX.
What seems to be most valuable in these constructions is that they demonstrate that dark matter can have very different properties than the standard WIMP. That should encourage the experimenters to extend the scope of their searches; so far their search algorithms have been tailor-made for the standard WIMP case, and they could have easily missed something interesting. The fantastic experimental progress makes the dark matter models testable well before the LHC can offer us any interesting data. If you have a good idea in store now is the good time to come out.
But the coming autumn is going to be exciting. The approaching LHC start-up is one but not the unique reason. On a completely different frontier, huge progress is expected in the area of direct detection of dark matter. The XENON100 experiment in Gran Sasso is going to kick off next month, while its bitter enemy - the LUX experiment in the Homestake mine - is hoping to follow before the end of the year. Within one year experimental sensitivity to the WIMP-nucleon cross section should be improved by two orders of magnitude, biting deep into the parameter space region where numerous popular theories predict a signal.
In the best case scenario the very first months or even days can lead to a discovery. This is the prediction of the dark matter models designed to resolve the DAMA puzzle. Recall that the DAMA experiment in Gran Sasso claims to have detected dark matter by observing the annual modulation of the count rate in their sodium-iodine detector. Particle theorists struggle to reconcile the DAMA signal with the null results from a dozen of other, in principle more sensitive, experiments. That is not quite impossible because various experiments use different targets and different detection techniques, in particular, the masses of the target nuclei as well as the range of the observable recoil energies are specific to each experiment. The game is thus to arrange the properties of dark matter such that the nuclear recoils due to scattering of dark matter particles could have been observed only by DAMA.
The standard WIMP is not an option here: DAMA would require large cross section at the level that has been excluded by CDMS, XENON10 (the little brother of XENON100) and others. But theorists are not easily discouraged and they are trying to come up with alternative ideas. Recently the so-called inelastic dark matter has gained a lot of publicity. In that scenario, dark matter particles scatter inelastically off nuclei into a slightly (hundred of keV) heavier state. Thus, one needs to provide enough energy to produce the heavier state which implies a minimum velocity of the initial dark matter particle for the scattering to occur. The splitting can be tuned such that DAMA is able to see the signal while the others are not. That of course requires some amount of conspiracy. Fortunately, the inelastic dark matter theory predicts a thunderstorm of events in the upcoming runs of XENON100 and LUX.
Until recently inelastic dark matter was the only plausible explanation of DAMA. But this week there was a paper exploring a different idea. In this new scenario, the scattering of dark matter on nucleons is elastic, but the scattering amplitude depends in a non-trivial way on the momentum transfer, hence the name form factor dark matter. If the form factor is suppressed outside the window to which DAMA happens to be sensitive, the null results of other experiments can be explained.
Non-trivial form factors can be arranged by some dirty model building tricks. The paper presents an example of a scalar dark matter particle with dipole-type ($D_\mu X^\dagger D_\nu X F_{\mu\nu}$) interactions with some new hidden vector fields. The latter mix with the photon which provides a coupling to the ordinary matter. To explain the DAMA phenomenology one needs at least two vector fields with opposite couplings to the photon and comparable masses, which makes the whole construction a bit contrived. Again, the model predicts a characteristic recoil spectrum, and a large number of events in XENON100 and LUX.
What seems to be most valuable in these constructions is that they demonstrate that dark matter can have very different properties than the standard WIMP. That should encourage the experimenters to extend the scope of their searches; so far their search algorithms have been tailor-made for the standard WIMP case, and they could have easily missed something interesting. The fantastic experimental progress makes the dark matter models testable well before the LHC can offer us any interesting data. If you have a good idea in store now is the good time to come out.
Wednesday, 5 August 2009
10? 6.66? Eleventeen?
Today (Wednesday) the CERN management is going to reach a decision that will affect the life of everybody on this planet. Namely, the operating energy of the LHC machine in the first year will be decided today. Senior readers may remember that the LHC used to be a 14 TeV collider. However that energy cannot be achieved in near future due to poor quality of the magnets provided by industry. Reaching the nominal energy will require a long process of magnet training, and the prospect for upgrade seem unlikely within the next 3 years. For this reason, 10 TeV was the energy planned for the last year false start, as well as for the restart scheduled for mid-November.
However, the rumor is that even this smaller energy will not be achieved next year due to the well known problems with bad splices. The hundreds of individual magnets around the LHC ring are connected using a process called soldering - an advanced cutting-edge technique whose many aspects are clouded in mystery. There are in fact two separate problems with soldering that have been detected at the LHC. One is a poor quality of interconnections between the superconducting magnets. That leads to excessive resistance (like nanoohms) and, in consequence, the current flowing through the interconnection generates heat that triggers a quench of the superconductor. The other problem are faulty interconnections between copper bus bars who are supposed to carry the current when the superconductor quenches. It is suspected that the solder in the bus bars was sometimes accidentally melted during subsequent soldering of the superconducting cable connections. In fact, it was a combination of the two above mentioned problems that triggered the fireworks of September 19.
Bad splices are known to be present in the LHC ring, and those residing in cold sectors cannot be repaired without a considerable slip to the schedule. So the alternative is to either postpone the LHC restart or run at slightly lower energies (the latter implies slightly smaller currents running through magnets and thus a slightly smaller risk of another catastrophe). During the last few months numerous simulations and experiments have been performed to determine the maximum safe current.
After a careful study of the plot above, listening to the experts, and weighing all pros and cons, the director general is going to roll a pair of dice, and the sum of dots will determine the LHC energy for the coming restart. As for the rumors, I have heard any rational number between 4 and 10 TeV. So, now is the last moment place your bets. Theoretical analysis of the 2-dice experiment suggests that 7 is the most likely outcome :-).
Once we know the operating energy, we will have a better idea what kind of results to expect in the first year. It is already certain that for a while the LHC cannot compete with the Tevatron in the area of Higgs searches. In fact, almost all reasonable new physics signatures require at least one inverse femtobarn of integrated luminosity, much more than the 100 inverse picobarns expected in the first year. This leaves boring standard model signatures, including slightly less boring top quark physics (but even in the case of the top quark competing with the Tevatron results may be tough if the center-of-mass energy is lower than 10 TeV). However, some spectacular (and unlikely) signatures like a new 1 TeV Z' gauge boson or light superparticles may be within reach if the center of mass energy is not much less than 10 TeV. But realistically, we have to keep patient until at least 2012.
And the winner is...
Seven!
However, the rumor is that even this smaller energy will not be achieved next year due to the well known problems with bad splices. The hundreds of individual magnets around the LHC ring are connected using a process called soldering - an advanced cutting-edge technique whose many aspects are clouded in mystery. There are in fact two separate problems with soldering that have been detected at the LHC. One is a poor quality of interconnections between the superconducting magnets. That leads to excessive resistance (like nanoohms) and, in consequence, the current flowing through the interconnection generates heat that triggers a quench of the superconductor. The other problem are faulty interconnections between copper bus bars who are supposed to carry the current when the superconductor quenches. It is suspected that the solder in the bus bars was sometimes accidentally melted during subsequent soldering of the superconducting cable connections. In fact, it was a combination of the two above mentioned problems that triggered the fireworks of September 19.
Bad splices are known to be present in the LHC ring, and those residing in cold sectors cannot be repaired without a considerable slip to the schedule. So the alternative is to either postpone the LHC restart or run at slightly lower energies (the latter implies slightly smaller currents running through magnets and thus a slightly smaller risk of another catastrophe). During the last few months numerous simulations and experiments have been performed to determine the maximum safe current.
After a careful study of the plot above, listening to the experts, and weighing all pros and cons, the director general is going to roll a pair of dice, and the sum of dots will determine the LHC energy for the coming restart. As for the rumors, I have heard any rational number between 4 and 10 TeV. So, now is the last moment place your bets. Theoretical analysis of the 2-dice experiment suggests that 7 is the most likely outcome :-).
Once we know the operating energy, we will have a better idea what kind of results to expect in the first year. It is already certain that for a while the LHC cannot compete with the Tevatron in the area of Higgs searches. In fact, almost all reasonable new physics signatures require at least one inverse femtobarn of integrated luminosity, much more than the 100 inverse picobarns expected in the first year. This leaves boring standard model signatures, including slightly less boring top quark physics (but even in the case of the top quark competing with the Tevatron results may be tough if the center-of-mass energy is lower than 10 TeV). However, some spectacular (and unlikely) signatures like a new 1 TeV Z' gauge boson or light superparticles may be within reach if the center of mass energy is not much less than 10 TeV. But realistically, we have to keep patient until at least 2012.
And the winner is...
Seven!
Friday, 24 July 2009
FERMI is seeing something?
It has become a tradition that release of new astrophysical data proceeds in the atmosphere of scandal, sex, and intrigues. Less than two weeks ago in this blog I was whining that the FERMI collaboration is guarding their secrets too effectively. Not any more. Not even guns and barbed wire fences could keep theorists off, once they have smelled real data.
Once again the story is related to the searches of indirect signals of dark matter in cosmic rays. In the previous episodes, the PAMELA satellite reported an excess of cosmic ray positrons between 10 and 100 GeV, and FERMI announced that the spectrum of electrons and positrons is harder (falls off more slowly with energy) than predicted by conventional cosmic ray propagation models. Although there exist plausible explanations in terms of mundane astrophysics, the excess positrons and electrons can also be understood as products of annihilation or decay of dark matter in our galaxy. If that is the case, there is one robust consequence. The electrons and positrons produced by dark matter throughout the galaxy should interact with the photons of the cosmic microwave background and starlight in the process known as the inverse Compton scattering, ICS in short. A high energy electron scattering off a photon transfers most of its energy to the photon. Thus, dark matter models explaining the PAMELA and FERMI results also predict an excess of gamma ray photons from the galactic center at energies 100 GeV and more. That's why the astroparticle community has been eagerly awaiting the release of FERMI measurements of gamma rays from the galactic center.
A week ago FERMI announced some new results at the TeV Particle Astrophysics conference held at SLAC. The new data included measurements of the gamma ray spectrum from the galactic center. The results from the one-by-one degree square around the galactic center, while providing new constraints on dark matter models, do not show any exciting features, see the upper plot. However, the data from a larger portion of the sky referred to as the inner galaxy do show an excess, or a hardening of the spectrum, starting at 100 GeV, see the plot on the left. The hardening occurs exactly where the dark matter models predict it! The FERMI collaboration did not want to post the latter result because it is still contaminated with poorly understood backgrounds. But somehow, mysteriously, the plot made it into the summary talk given by Persis Drell and the slides were posted at the conference page. These slides have now been removed; too late alas too late. Today there is a new paper on arXiv that interprets the new FERMI data in terms of the PAMELA/FERMI motivated models dark matter. The plot below reproduced from that paper shows the FERMI data together with expected backgrounds and predictions from dark matter models.
So is FERMI seeing dark matter? Most likely not. Members of the FERMI collaboration suspect that the feature in the gamma ray spectrum around 100 GeV is due to an unexpected background from other cosmic ray particles. Further analysis should clarify the situation. What is definitely true is that we're living in interesting times...
Once again the story is related to the searches of indirect signals of dark matter in cosmic rays. In the previous episodes, the PAMELA satellite reported an excess of cosmic ray positrons between 10 and 100 GeV, and FERMI announced that the spectrum of electrons and positrons is harder (falls off more slowly with energy) than predicted by conventional cosmic ray propagation models. Although there exist plausible explanations in terms of mundane astrophysics, the excess positrons and electrons can also be understood as products of annihilation or decay of dark matter in our galaxy. If that is the case, there is one robust consequence. The electrons and positrons produced by dark matter throughout the galaxy should interact with the photons of the cosmic microwave background and starlight in the process known as the inverse Compton scattering, ICS in short. A high energy electron scattering off a photon transfers most of its energy to the photon. Thus, dark matter models explaining the PAMELA and FERMI results also predict an excess of gamma ray photons from the galactic center at energies 100 GeV and more. That's why the astroparticle community has been eagerly awaiting the release of FERMI measurements of gamma rays from the galactic center.
A week ago FERMI announced some new results at the TeV Particle Astrophysics conference held at SLAC. The new data included measurements of the gamma ray spectrum from the galactic center. The results from the one-by-one degree square around the galactic center, while providing new constraints on dark matter models, do not show any exciting features, see the upper plot. However, the data from a larger portion of the sky referred to as the inner galaxy do show an excess, or a hardening of the spectrum, starting at 100 GeV, see the plot on the left. The hardening occurs exactly where the dark matter models predict it! The FERMI collaboration did not want to post the latter result because it is still contaminated with poorly understood backgrounds. But somehow, mysteriously, the plot made it into the summary talk given by Persis Drell and the slides were posted at the conference page. These slides have now been removed; too late alas too late. Today there is a new paper on arXiv that interprets the new FERMI data in terms of the PAMELA/FERMI motivated models dark matter. The plot below reproduced from that paper shows the FERMI data together with expected backgrounds and predictions from dark matter models.
So is FERMI seeing dark matter? Most likely not. Members of the FERMI collaboration suspect that the feature in the gamma ray spectrum around 100 GeV is due to an unexpected background from other cosmic ray particles. Further analysis should clarify the situation. What is definitely true is that we're living in interesting times...
Sunday, 19 July 2009
Bullets Fly
I'm sure that everybody has heard of the Bullet cluster aka 1E 0657-56:
This picture from August 2006 made the headlines because it offers a new way to see the presence of dark matter in the universe (the key of course is to paint it blue). The depth of the gravitational potential deduced from gravitational lensing is marked blue, while the matter that shines ordinary photons is marked red. The picture is interpreted as showing two clusters of galaxies that have recently undergone a head-on collision. The dark matter components (and also most of the ordinary stars in the galaxies) just passed through each other with little or no interaction, while the interstellar gas made of familiar protons and electrons collided and got left behind. The observation of the Bullet cluster gave another blow to dark matter alternatives like MOND-type modified gravity theories: in the latter context it is hard to explain why the gravitational potential is not spatially correlated with the ordinary matter distribution.
What might be a little less known is that the Bullet cluster is not the only one. In August 2007 Abell 520 aka Train Wreck was revealed:
This one is much more messy. In fact, in this case the dark matter interpretation is less straightforward. The reason is that the galaxies seems to have been removed from the densest core of dark matter, and it is not clear what mechanism could have caused it. Then in August 2008 we had a pleasure to meet MACS J0025.4-1222 aka Baby Bullet:
which is another pretty clear evidence in favor of dark matter. Apparently, galactic collisions happen every year in August, so next month we should be presented with another picture of this kind :-)
The most important thing about these observations is that they look cool in pictures. But they also carry some practical consequence for particle theorists who sweat to construct models of dark matter. From the fact that the dark matter components pass through each other so easily one can derive a constraint on the self-interaction cross section of dark matter. The paper of Randall et al (not that Randall) based on the analysis of the Bullet cluster quotes the limit
That's an order of magnitude better than the so-called Spergel-Steinhard bound that can be deduced from the dynamics of our galaxy. While this bound is irrelevant for a standard 100 GeV WIMP, it might be a useful constraint for recently popular theories of dark matter where the dark sector consists of strongly interacting particles bound by some new unknown GeV scale forces.
This picture from August 2006 made the headlines because it offers a new way to see the presence of dark matter in the universe (the key of course is to paint it blue). The depth of the gravitational potential deduced from gravitational lensing is marked blue, while the matter that shines ordinary photons is marked red. The picture is interpreted as showing two clusters of galaxies that have recently undergone a head-on collision. The dark matter components (and also most of the ordinary stars in the galaxies) just passed through each other with little or no interaction, while the interstellar gas made of familiar protons and electrons collided and got left behind. The observation of the Bullet cluster gave another blow to dark matter alternatives like MOND-type modified gravity theories: in the latter context it is hard to explain why the gravitational potential is not spatially correlated with the ordinary matter distribution.
What might be a little less known is that the Bullet cluster is not the only one. In August 2007 Abell 520 aka Train Wreck was revealed:
This one is much more messy. In fact, in this case the dark matter interpretation is less straightforward. The reason is that the galaxies seems to have been removed from the densest core of dark matter, and it is not clear what mechanism could have caused it. Then in August 2008 we had a pleasure to meet MACS J0025.4-1222 aka Baby Bullet:
which is another pretty clear evidence in favor of dark matter. Apparently, galactic collisions happen every year in August, so next month we should be presented with another picture of this kind :-)
The most important thing about these observations is that they look cool in pictures. But they also carry some practical consequence for particle theorists who sweat to construct models of dark matter. From the fact that the dark matter components pass through each other so easily one can derive a constraint on the self-interaction cross section of dark matter. The paper of Randall et al (not that Randall) based on the analysis of the Bullet cluster quotes the limit
$\sigma/M \leq 3 \cdot 10^3/GeV^3$.
That's an order of magnitude better than the so-called Spergel-Steinhard bound that can be deduced from the dynamics of our galaxy. While this bound is irrelevant for a standard 100 GeV WIMP, it might be a useful constraint for recently popular theories of dark matter where the dark sector consists of strongly interacting particles bound by some new unknown GeV scale forces.
Friday, 10 July 2009
That's Another One for the Fire
It's a lazy summer season: everybody's on the beach and nothing's much going on. To stay in business I have to feed you with some microwaved news. Last week the FERMI collaboration uploaded a pile of papers on arXiv, one of which caught my attention. FERMI is a space gamma-ray observatory, but first of all he is a ruthless terminator with a mission to eliminate other astrophysical experiments. A while ago in May the widely publicized measurement of the cosmic-ray electron+positron spectrum pierced the ATIC balloon that had been pumped for several months. Earlier this year FERMI made another kill: it shot down EGRET, its direct predecessor in cosmic gamma-ray observations. That result has been presented at conferences for a few months, but only last week it made it to arXiv (there's also a longer PRL paper announced).
EGRET was a sattelite gamma-ray observatory that in particular studied the diffuse gamma ray emission in the 30 MeV-100 GeV range. Diffuse means spread over the sky rather than originating from point sources. The main source of diffuse radiation is scattering of the cosmic rays on the milk of the Milky Way. Dark matter annihilation into standard model particles can also contribute to the diffuse flux. The EGRET results showed an excess of gamma rays above 1 GeV, which was quickly hailed as the harbinger of dark matter and supersymmetry. But FERMI's measurement now demonstrates that there's nothing exciting going on below 10GeV: the experimental curve nicely follows the theoretical prediction of the standard propagation model. No exotic physics in sight. ATIC, EGRET...who's next?
FERMI's goal is to measure the diffuse gamma-ray spectrum up to some 300 GeV. The high energy data around are even more interesting for theorists as many popular models of dark matter - especially those that explain the PAMELA positron excess - predict a large signal peaking around a few hundred GeV. More results are expected in August since on August 12th the collaboration is supposed to make all their photon data public. If you hear cries and squealing later this summer that's the dark matter models being slaughtered. Or maybe FERMI sees an excess in which case all hell will break loose? The rumor is...the weird thing is that there are no rumors. Last time, quite accurate descriptions of the electron spectrum circulated in the community months before publication of the FERMI data, and theory papers from outside of the collaboration were out days after FERMI's publication (or even violating causality in one case). Probably because of that experience the collaboration has now entrenched in its camp with barbed wire fences, dogs, booby traps to keep off the theorists. Oh come on, dont be so serious, we also wanna know ;-)
EGRET was a sattelite gamma-ray observatory that in particular studied the diffuse gamma ray emission in the 30 MeV-100 GeV range. Diffuse means spread over the sky rather than originating from point sources. The main source of diffuse radiation is scattering of the cosmic rays on the milk of the Milky Way. Dark matter annihilation into standard model particles can also contribute to the diffuse flux. The EGRET results showed an excess of gamma rays above 1 GeV, which was quickly hailed as the harbinger of dark matter and supersymmetry. But FERMI's measurement now demonstrates that there's nothing exciting going on below 10GeV: the experimental curve nicely follows the theoretical prediction of the standard propagation model. No exotic physics in sight. ATIC, EGRET...who's next?
FERMI's goal is to measure the diffuse gamma-ray spectrum up to some 300 GeV. The high energy data around are even more interesting for theorists as many popular models of dark matter - especially those that explain the PAMELA positron excess - predict a large signal peaking around a few hundred GeV. More results are expected in August since on August 12th the collaboration is supposed to make all their photon data public. If you hear cries and squealing later this summer that's the dark matter models being slaughtered. Or maybe FERMI sees an excess in which case all hell will break loose? The rumor is...the weird thing is that there are no rumors. Last time, quite accurate descriptions of the electron spectrum circulated in the community months before publication of the FERMI data, and theory papers from outside of the collaboration were out days after FERMI's publication (or even violating causality in one case). Probably because of that experience the collaboration has now entrenched in its camp with barbed wire fences, dogs, booby traps to keep off the theorists. Oh come on, dont be so serious, we also wanna know ;-)
Thursday, 25 June 2009
Angles and Demons
Since writing down the standard model back in the summer of love the only progress in particle theory has been the discovery that neutrinos have masses. This fact makes the leptons similar in spirit to the quarks in the sense that transitions between different flavors are possible. In both cases the flavor eigenstates, that is the states to which the W bosons couple, are not the same as the mass eigenstates but linear combinations thereof. This fact opens the door to a fascinating endeavor of measuring the angles in the unitary matrix that relates the flavor and the mass eigenstates.
The angles in the quark sector have been measured from every angle. The final conclusion is that what they taught at school was right: the sum of the angles in a (unitarity) triangle is equal to 180 degrees. In the lepton sector, experiment is lagging behind: so far we know only two of the angles. The one known as the atmospheric or $\theta_{23}$ angle (responsible in particular for the transitions of atmospheric muon neutrinos into tau ones) is close to 45 degrees. The solar or $\theta_{12}$ angle (responsible for the vanishing of electron neutrinos produced in the Sun) turned out to be a bit smaller, about 30 degrees. For the last angle, at the moment we have only an upper bound from the CHOOZ reactor experiment: $\theta_{13} < 11$ degrees at 90 percent C.L.
Now what have demons to do with it? I recently came across a talk from the MINOS collaboration a few month ago in Fermilab. MINOS, when on leave from Hades, studies the muon neutrino beam sent over the distance of 735 kilometers from Fermilab to a far detector located in the Soudan mine in Minnesota. One reason to bother (just imagine what it takes to dig such a long tunnel to send the neutrino beam over several states) is a precise measurement of the angle $\theta_{23}$ which controls the fraction of muon neutrinos that disappear on the way. But there may be more fun than that. Most of the muon neutrinos that vanish turn into tau neutrinos who escape detection. However, if $\theta_{13}$ is non-zero then a small fraction of the muon neutrinos should turn into electron neutrinos, and those receive a warm welcome in Soudan. Thus, MINOS is one in a long queue of experiments trying to pinpoint $\theta_{13}$.
In February this year MÌNOS announced their first results concerning the electron neutrino appearance. They see 35 electron event, roughly 1.5 sigma above the expected background of $27$ events. Not too significant, but already tantalizing. Moreover, if the MINOS data are combined with all available neutrino data the hint for a non-zero $\theta_{13}$ is strengthened to 2 sigma. The central value for $\theta_{13}$ inferred from the overall fit is 8 degrees (plus minus 4) - just below the CHOOZ limit.
If the current hints converge to a full-fledged measurement of $\theta_{13}$ in the 5-10 degrees ballpark then there are some far reaching consequences. First of all, measuring the $\theta_{13}$ angle paves the way to measuring yet another angle (isn't particle physics exciting?), more precisely the CP violating phase in the neutrino mixing matrix. Secondly, it would appear that the mixing angles in the lepton sector are pretty random numbers with no structure, in stark contrast to the quark sector where the CKM matrix displays a very hierarchical structure. In other words, neutrinos would prove to be anarchic. That would mean that anarchy is at rule, at least in the lepton sector, for the first time since Barcelona'36.
The angles in the quark sector have been measured from every angle. The final conclusion is that what they taught at school was right: the sum of the angles in a (unitarity) triangle is equal to 180 degrees. In the lepton sector, experiment is lagging behind: so far we know only two of the angles. The one known as the atmospheric or $\theta_{23}$ angle (responsible in particular for the transitions of atmospheric muon neutrinos into tau ones) is close to 45 degrees. The solar or $\theta_{12}$ angle (responsible for the vanishing of electron neutrinos produced in the Sun) turned out to be a bit smaller, about 30 degrees. For the last angle, at the moment we have only an upper bound from the CHOOZ reactor experiment: $\theta_{13} < 11$ degrees at 90 percent C.L.
Now what have demons to do with it? I recently came across a talk from the MINOS collaboration a few month ago in Fermilab. MINOS, when on leave from Hades, studies the muon neutrino beam sent over the distance of 735 kilometers from Fermilab to a far detector located in the Soudan mine in Minnesota. One reason to bother (just imagine what it takes to dig such a long tunnel to send the neutrino beam over several states) is a precise measurement of the angle $\theta_{23}$ which controls the fraction of muon neutrinos that disappear on the way. But there may be more fun than that. Most of the muon neutrinos that vanish turn into tau neutrinos who escape detection. However, if $\theta_{13}$ is non-zero then a small fraction of the muon neutrinos should turn into electron neutrinos, and those receive a warm welcome in Soudan. Thus, MINOS is one in a long queue of experiments trying to pinpoint $\theta_{13}$.
In February this year MÌNOS announced their first results concerning the electron neutrino appearance. They see 35 electron event, roughly 1.5 sigma above the expected background of $27$ events. Not too significant, but already tantalizing. Moreover, if the MINOS data are combined with all available neutrino data the hint for a non-zero $\theta_{13}$ is strengthened to 2 sigma. The central value for $\theta_{13}$ inferred from the overall fit is 8 degrees (plus minus 4) - just below the CHOOZ limit.
If the current hints converge to a full-fledged measurement of $\theta_{13}$ in the 5-10 degrees ballpark then there are some far reaching consequences. First of all, measuring the $\theta_{13}$ angle paves the way to measuring yet another angle (isn't particle physics exciting?), more precisely the CP violating phase in the neutrino mixing matrix. Secondly, it would appear that the mixing angles in the lepton sector are pretty random numbers with no structure, in stark contrast to the quark sector where the CKM matrix displays a very hierarchical structure. In other words, neutrinos would prove to be anarchic. That would mean that anarchy is at rule, at least in the lepton sector, for the first time since Barcelona'36.
Friday, 12 June 2009
Boston Tea Party
Last weekend I made a trip to Boston and had a privilege to see bits of the SUSY'09 conference. Backreaction and Quantum Diaries have already run their stories but in my opinion they did not fully capture the grandeur of the event. 9 days in a row, including foreplay. Over 400 participants, not counting squatters. 42 plenary speakers, most of whom witnessed the glorious days when supersymmetry was conceived. Seven parallel parallel sessions to cover every aspect of supersymmetry that has not yet been covered thoroughly enough. Royal coffee break menu fully adequate to the royal conference fee. And so on and on since 16 years and into the future.
Meanwhile, there is no single hint from experiment that supersymmetry is realized in nature... but that should not upset anyone. As my fellow blogger skillfully put it, supersymmetry is the "shining beacon", the "raison d’etre" and for this reason "the conundrum is how it will be discovered, not if". That's why every year we come together to enjoy old familiar faces and old familiar talks. The point is, while waiting for the inevitable, to maintain that kind of spirit that David Lodge praised in his books.
On the picture below, the photographer about to make a photograph of the SUSY'09 participants.
Meanwhile, there is no single hint from experiment that supersymmetry is realized in nature... but that should not upset anyone. As my fellow blogger skillfully put it, supersymmetry is the "shining beacon", the "raison d’etre" and for this reason "the conundrum is how it will be discovered, not if". That's why every year we come together to enjoy old familiar faces and old familiar talks. The point is, while waiting for the inevitable, to maintain that kind of spirit that David Lodge praised in his books.
On the picture below, the photographer about to make a photograph of the SUSY'09 participants.
Tuesday, 9 June 2009
Life After FERMI
I mean, after FERMI's first electron data that shed new light on the currently hottest topic in astroparticle physics - the origin of the cosmic-ray positron excess measured by PAMELA. The PAMELA anomaly trumpeted last summer, combined with the data from ATIC (who claims a spectacular excess of electrons at few hundred GeV), prompted zillions of publications that speculate of its dark matter origin. A few weeks ago FERMI revealed their first measurement of the electron+positron cosmic ray spectrum up to 1 TeV. Here is my summary of what that implies for the models of dark matter.
Let's begin with a handful of facts:
In fact, the new FERMI data did not really lead to a slaughter of the dark matter models or its authors. New papers keep appearing in which the excess is fitted with axions, neutralinos, winos, KK particles, F-theory or three little pigs. But Occam is waving his razor menacingly, and we are reaching the point where boring astrophysics becomes the simplest explanation of all available data. The dark matter models, although still viable, have to be intelligently designed to yield observable signals in the positron and electron channels, but none in antiprotons, gamma rays or neutrinos. Incidentally, the electron channel is the one where the astrophysical background is most difficult to control...
The cool thing is that by the end of this summer we may further disfavor dark matter or return it to grace. The new crucial piece of information will be FERMI's measurement of the diffuse gamma ray spectrum that will extend its previous measurement to larger energies. If the electrons and positrons observed by PAMELA and FERMI originate from dark matter it means that they are produced all over the galaxy. Once produced, the electrons lose their energy by scattering on starlight and on the CMB or by synchrotron radiation in the galactic magnetic fields, which leads to a diffuse flux of photons at energies of a few hundred GeV. Given the number of electrons needed to explain PAMELA and FERMI, the diffuse signal should be detectable by 1-year FERMI data. The important thing is that boring astrophysics cannot easily fake that signal. On the other hand, the absence of features in diffuse gamma would be a huge setback for the dark matter interpretation. The experimental data are expected on August 12, so just a little patience please...
For more details and plots see the slides of Alessandro Strumia's talk at Planck'09; check also for the connection between dark matter and dialectic materialism.
Let's begin with a handful of facts:
- Thanks to FERMI and HESS we now have a pretty accurate picture of the cosmic-ray electron+positron spectrum. Up to 1 TeV, the spectrum is well approximated by power law, $\sim E^{-3}$, while above TeV it becomes softer (larger power).
- ATIC screwed: there is no clear feature in the electron spectrum. In principle, one should describe the present situation as "two experiments giving inconsistent results", given that ATIC's brand new data continue displaying a distinct bump with even smaller errorbars. But, somehow, the public opinion prefers a fancy high-tech satellite over a dirty leaking balloon somewhere in the cold Antarctica. More seriously, FERMI simply beats ATIC with a hundred times more statistics.
- The electron spectrum near TeV is above the background predicted by conventional cosmic-ray propagation models (which prefer a larger power, $\sim E^{-3.3}$) in which the electrons are produced by scattering of cosmic ray protons. But that alone is hardly an anomaly, and the spectrum can be easily fitted by cranking up the propagation model.
- However, combining FERMI with the PAMELA positron data strongly indicates the presence of a new primary component of electrons/positrons (as opposed to the secondary production by protons) .
- The primary component could be injected by nearby pulsars, or by another so far unidentified astrophysical process, or by dark matter annihilating or decaying in our galaxy. We have to wait for the jury to reach the verdict.
- But, light (less than 1 TeV) dark matter particle as a source of the PAMELA and FERMI excess is now strongly disfavored. The reason is that a light particle would lead to sharp spectral features at energies comparable to its mass, whereas FERMI sees none of that. If dark matter is the cause of the excess, it has to be relatively heavy, 1 TeV or more.
In fact, the new FERMI data did not really lead to a slaughter of the dark matter models or its authors. New papers keep appearing in which the excess is fitted with axions, neutralinos, winos, KK particles, F-theory or three little pigs. But Occam is waving his razor menacingly, and we are reaching the point where boring astrophysics becomes the simplest explanation of all available data. The dark matter models, although still viable, have to be intelligently designed to yield observable signals in the positron and electron channels, but none in antiprotons, gamma rays or neutrinos. Incidentally, the electron channel is the one where the astrophysical background is most difficult to control...
The cool thing is that by the end of this summer we may further disfavor dark matter or return it to grace. The new crucial piece of information will be FERMI's measurement of the diffuse gamma ray spectrum that will extend its previous measurement to larger energies. If the electrons and positrons observed by PAMELA and FERMI originate from dark matter it means that they are produced all over the galaxy. Once produced, the electrons lose their energy by scattering on starlight and on the CMB or by synchrotron radiation in the galactic magnetic fields, which leads to a diffuse flux of photons at energies of a few hundred GeV. Given the number of electrons needed to explain PAMELA and FERMI, the diffuse signal should be detectable by 1-year FERMI data. The important thing is that boring astrophysics cannot easily fake that signal. On the other hand, the absence of features in diffuse gamma would be a huge setback for the dark matter interpretation. The experimental data are expected on August 12, so just a little patience please...
For more details and plots see the slides of Alessandro Strumia's talk at Planck'09; check also for the connection between dark matter and dialectic materialism.
Wednesday, 27 May 2009
News and Gossips from the LHC
Since two weeks Planck stands first of all for a satellite CMB observatory, but it's also the name for an annual series of conferences on physics beyond the standard model. This year's edition is taking place in the furnace of Padova. Since Tommaso is around, he will surely describe everything in great detail, including color of the tie of each speaker, while I should later write a summary of the interesting ideas discussed here in case there is any. But for now I'd like to share a handful of interesting facts about the progress of the LHC that I learned from a supercool talk delivered here by Jörg Wenninger. I guess most of what's below is not new and should be familiar to those closely following the LHC saga.
One interesting fact I was not aware of: a quench (a phase transition from superconductivity to normal conductivity) of an LHC magnet can be induced by just a few milijoules of energy. That energy may be provided by a bunch of strayed protons from the beam . To avoid quenching, LHC cannot lose more than a millionth part of its beam. For comparison, the Tevatron loses about one thousandth of its beam during acceleration. In that respect, Jörg was very convincing that the LHC would ever work ;-) But then, miracles do happen, sometimes.
Another interesting part of the talk was the explanation why the LHC will run at 10 TeV in the center of mass, instead of the nominal 14 TeV. The story goes as follows. Before installing, the LHC magnets have to be "trained", that is to say, to undergo a series of quenches to let their coils settle down at stable positions. After being installed in the tunnel they are supposed to come back to their test performance with no or few quenches. It turns out that the magnets provided by one of the three manufacturing companies need an extraordinary number of quenches to settle down. Although the company in question was not pointed at, everybody knows that the name is Ansaldo. In the case of that company, the number of quenches required for stable operation at 7 TeV per beam is currently unknown, it is probably somewhere between a hundred and a thousand. At the moment it is not clear if the LHC will ever reach 14 TeV; 12-13 TeV might be a more realistic goal.
The talk gave also a detailed account of the incident of September 19 known as the 9/11 of particle physics. Although the evidence has evaporated, one can quite reliably outline the sequence of events. An abnormally large resistance in one of the magnets acted as a heat source that quenched the superconducting cable at one interconnection. In case of a quench the current should start flowing or a few minutes through the copper bus-bar that encloses the cable until the energy stored in the magnet is removed. However, due to bad soldering of an interconnection the current could not flow normally and an electric arc was created. This melted copper, punctured the helium enclosure which led to spilling of 6 tons of helium into the tunnel. The logo of the company that made the faulty magnet is always erased in the pictures, although everybody knows that the name is Ansaldo.
So what's next? The repairs of the damaged sector are almost finished. The current plan is to head for collisions this year (with a caveat "depends how one defines collisions"). Beam commissioning is scheduled for September/October and the first collisions could happen in November. The schedule is very tight and, moreover, the quality control of has revealed problems like bad soldering or reduced electrical contact in a number of places, including sectors that are already cold. The rumor is that some of the LHC magnets in reality turned out to be electric kettles.
The slides here.
One interesting fact I was not aware of: a quench (a phase transition from superconductivity to normal conductivity) of an LHC magnet can be induced by just a few milijoules of energy. That energy may be provided by a bunch of strayed protons from the beam . To avoid quenching, LHC cannot lose more than a millionth part of its beam. For comparison, the Tevatron loses about one thousandth of its beam during acceleration. In that respect, Jörg was very convincing that the LHC would ever work ;-) But then, miracles do happen, sometimes.
Another interesting part of the talk was the explanation why the LHC will run at 10 TeV in the center of mass, instead of the nominal 14 TeV. The story goes as follows. Before installing, the LHC magnets have to be "trained", that is to say, to undergo a series of quenches to let their coils settle down at stable positions. After being installed in the tunnel they are supposed to come back to their test performance with no or few quenches. It turns out that the magnets provided by one of the three manufacturing companies need an extraordinary number of quenches to settle down. Although the company in question was not pointed at, everybody knows that the name is Ansaldo. In the case of that company, the number of quenches required for stable operation at 7 TeV per beam is currently unknown, it is probably somewhere between a hundred and a thousand. At the moment it is not clear if the LHC will ever reach 14 TeV; 12-13 TeV might be a more realistic goal.
The talk gave also a detailed account of the incident of September 19 known as the 9/11 of particle physics. Although the evidence has evaporated, one can quite reliably outline the sequence of events. An abnormally large resistance in one of the magnets acted as a heat source that quenched the superconducting cable at one interconnection. In case of a quench the current should start flowing or a few minutes through the copper bus-bar that encloses the cable until the energy stored in the magnet is removed. However, due to bad soldering of an interconnection the current could not flow normally and an electric arc was created. This melted copper, punctured the helium enclosure which led to spilling of 6 tons of helium into the tunnel. The logo of the company that made the faulty magnet is always erased in the pictures, although everybody knows that the name is Ansaldo.
So what's next? The repairs of the damaged sector are almost finished. The current plan is to head for collisions this year (with a caveat "depends how one defines collisions"). Beam commissioning is scheduled for September/October and the first collisions could happen in November. The schedule is very tight and, moreover, the quality control of has revealed problems like bad soldering or reduced electrical contact in a number of places, including sectors that are already cold. The rumor is that some of the LHC magnets in reality turned out to be electric kettles.
The slides here.