If that was the only requirement, building such a detector wouldn't be so hard. The difficulty arises in the fact that there is radiation flying all over the place all the time that is not associated with dark matter, and our detector is sensitive to that as well. This is known as background. It's as if you were trying to have a conversation with someone at a loud party who refused to raise his voice. Because of all the background conversations, it would be very hard to understand what that person was saying. A dark matter detector has a similar problem. For example, because of energetic particles passing
through the atmosphere called cosmic rays and other ambient sources of radiation, a standard radiation detector (a Geiger counter is shown in the picture) goes off about 100 times per second. Or 10 million times a day. Or 3.7 billion times a year. And we want to be sensitive to 1 event. Imagine trying to hear what one particular person was saying when half of all the people on Earth were speaking at the same time and that's what dark matter experimentalists are trying to do.How do we plan to do this? First, we will put our detector underground (in an active nickel mine in Sudbury, ON). This has been done with great success by neutrino experiments in the past – if the detector is underground, the earth helps shield the detector from cosmic rays, knocking the background down to say just the population of the USA. Second, we want to use very clean materials in our detector – if you can purify and clean everything very well, you can get rid of many sources of background that are always just lying around. Specifically, we plan to use liquid argon or liquid neon as our detector materials. These elements are very easily purified, so that we can remove anything that might produce radiation before filling our detector. Argon and neon have the great property that when exposed to radiation, they will “scintillate” or produce light. That will be our signal, in that we will look for flashes of light produced by a WIMP interacting in the liquid. In addition, the size of an argon or neon detector can be quite large, helping increase the size of our dark matter “target.”
Finally, we hope to reduce the majority of our backgrounds by using the timing of the light produced by an interaction. Most backgrounds in our detector are caused by radiation scattering off of electrons – these are called “electronic recoils.” A dark matter event would occur from a WIMP scattering off a nucleus, or a “nuclear recoil.” These two types of events have different time signatures in the scintillation light, and we can use the timing to tell them apart.
Our plan is to build a sensitive detector, eliminate all the backgrounds, and listen for that one interesting conversation.
I understood this one very well, but it doesnt have any squiggly letters in italics! Perhaps moms like me are better off without them!
ReplyDeleteCongrats, Mom
is nuclear recoil only caused from WIMPs?
ReplyDeleteGreat question. Neutrons flying through the detector will give you nuclear recoils, and that's actually what we use to study nuclear recoils, a little neutron generator.
ReplyDeleteIn the large detector, there are a couple of things we can do to get rid of neutron backgrounds, and I'll probably talk about them at some point. The short answer is shielding - the whole detector will go in a water tank to help mitigate neutrons coming from the rock walls, and we may add a layer of acrylic inside to knock down neutrons coming from the glass and steel making up the detector itself. Also, a neutron has a pretty good probability of scattering twice in a big detector - a WIMP will only scatter once, so we can use that to tell them apart.