Whether this rumor turns out to be accurate or not, the technology used in the CDMS collaboration's dark matter search is quite interesting. Working down the hall from these folks in graduate school definitely gave me an appreciation for the challenges they face, as well as teaching me some neat condensed matter physics and experimental knowledge.
The basic challenge in dark matter detection is that weakly interacting particles are, well, very weakly interacting. We have all kinds of circumstantial evidence (rotation curves of galaxies; gravitational lensing measurements of mass distributions; particular angular anisotropies in the cosmic microwave background) that there is a lot of mass out there in the universe that is not ordinary baryonic matter (that is, made from protons and neutrons). The dark matter hypothesis is that there are additional (neutral) particles out there that couple only very weakly to normal matter, certainly through gravity, and presumably through other particle physics interactions with very small cross-sections. A reasonable approach to looking for these particles would involve watching for them to recoil off the nuclei of normal matter somehow. These recoils would dump energy into the normal matter, but you'd need to distinguish between these events and all sorts of others. For example, if any atoms in your detector undergo radioactive decay, that would also dump energy into the detector material's lattice. Similarly, if a cosmic ray came in and banged around, that would deposit energy, too. Those two possibilities also deposit charge into the detector, though, so the ability to identify and discount recoil events associated with charged particles would be essential. Neutrons hitting the detector material would be much more annoying.
The CDMS detectors consist of ~ cm-thick slabs of Si (ok) and Ge (better, because Ge is heavier and therefore has more nuclear material), each with an electrical ground plane (very thin low-Z metal film) on one side and an array of meandering tungsten micro-scale wires on the other side. The tungsten meanders are "superconducting transition edge bolometers". The specially deposited tungsten films have a superconducting transition somewhere near 75 mK. By properly biasing them electrically (using "electrothermal feedback"), they sit right on the edge of their transition. If any extra thermal energy gets dumped into the meander, a section of it is driven "normal". This leads to a detectable voltage pulse. At the same time, because that section now has higher resistance, current flow through there decreases, allowing the section to cool back down and go superconducting again. By having very thin W lines, their heat capacity is very small, and this feedback process (recovery time) is fast. A nuclear recoil produces a bunch of phonons which propagate in the crystal with slightly varying sound speeds depending on direction. By having an array of such meanders and correlating their responses, it's possible to back out roughly where the recoil event took place. (They had an image on the cover of Physics Today back in the 90s some time showing beautiful ballistic phonon propagation in Si with this technique.) Moreover, there is a small DC voltage difference between the transition edge detectors and the ground plane. That means that any charge dumped into the detector will drift. By looking for current pulses, it is possible to determine which recoil events came along with charge deposition in the crystal. The CDMS folks have a bunch of these slabs attached via a cold finger to a great big dilution refrigerator (something like 4 mW cooling power at 100 mK, for those cryo experts out there) up in an old salt mine in Minnesota, and they've been measuring for several years now, trying to get good statistics.
To get a flavor for how challenging this stuff is, realize that they can't use ordinary Pb-Sn solder (which often comes pre-tinned on standard electronic components) anywhere near the detector. There's too high an abundance of a radioisotope of Pb that is produced by cosmic rays. They have to use special solder based on "galley lead", which gets its name because it comes from Roman galleys that have been sunk on the bottom of the Mediterranean for 2000 years (and thus not exposed to cosmic rays). I remember as a grad student hearing an anecdote about how they deduced that someone had screwed up and used a commercial pre-tinned LED because they could use the detector itself to see clear as day the location of a local source of events. I also remember watching the challenge of finding a wire-bonder that didn't blow up the meanders due to electrostatic discharge problems. There are competing techniques out there now, of course.
Well, it'll be interesting to see what comes out of this excitement. These are some really careful people. If they claim there's something there, they're probably right.
JI Collar's perfluorocarbon and Halon supercritical liquid bubble chambers scale to very large volumes without sacrificing dark matter collision sensitivity or low noise background. Alas, there is not nearly enough expense or sci-fi in them to be sexy, grant funding-wise.
ReplyDeleteThat can be fixed. I(CF3)7 boils at 0 C, has I (mass) and F (spin-1/2) for detection (both being monoisotopic), has no static molecular structure, and costs a fortune. Play to the politics of grant funding.
When did you last meet a gas that was 21 times heavier than air? SF6 is only 5X.
Al, look up the liquid xenon collaboration. They're more along your lines. The people doing this aren't trying to be "sexy, grant funding-wise". The constraints required to do dark matter detection are formidable.
ReplyDeleteHi Doug,
ReplyDeleteinteresting that you would mention the directionality of ballistic phonon transport. There are actually many aesthetically pleasing pictures of this effect for different crystal structures. Jim Wolfe from Urbana-Champaign wrote the book on this (Imaging Phonons) (http://www.cambridge.org/us/catalogue/catalogue.asp?isbn=0521620619), the title image is very nice as well.
One way to measure this directionality other than using superconducting bolometers is to look at the emission spectrum of an exciton gas at one crystal surface - the ratio and amount of photoluminescence from defect-bound and free excitons depends on the flux of non-equilibrium phonons present. A method also pioneered by Jim Wolfe. My Master's work in Germany was to improve on the spatial resolution and sensitivity of this scheme.
>These are some really careful
ReplyDelete>people. If they claim there's
>something there, they're probably
>right.
What about the Valentine's day monopole massacre?
Anon. - I meant what I said. Cabrera was careful never to have claimed discovery of a monopole. (You should see the original data, by the way. Very striking.) He built a bigger, more sensitive detector, ran it longer, and found nothing. As far as I can tell (not being an expert in the dark matter community), CDMS has been very cautious.
ReplyDeleteDoug,
ReplyDeleteyou are probably thinking of the Soudan Mine in northern Minnesota. it was an iron mine, not a salt mine.
i took a tour of it over thirty years ago, before the UofMN started experiments there.
Doug, you support my contention. Xenon boils at -108 C and is expensive. It sexies up ion engines by making them unaffordable (and unobtainable in aggregate). Collar's metastable (OK, not supercritical) fluids run at or above room temp. They are flat out cheap before Enviro-whiner levies to Save The Ozone Layer (whose politically winsome destruction kinetics are maintained by hydrochlorofluorocarbons).
ReplyDeleteMy personal opinion is "no dark matter, no Higgs boson." Theoretical physics has lost its way for demanding fundamental symmetries that the universe does not employ - and testably so,
http://www.mazepath.com/uncleal/erotor1.jpg
I'm slightly amused that Science dignifies rumors on blogs with a short comment :) http://sciencenow.sciencemag.org/cgi/content/full/2009/1209/1?etoc
ReplyDeletePing!
ReplyDeleteRumor or no rumor, it seems quite interesting though.
ReplyDelete