Direct detection refers to the observation of the effects of a WIMP-nucleus collision as the dark matter passes through a detector in an Earth laboratory. While most WIMP models indicate that a large enough number of WIMPs must be captured in large celestial bodies for indirect detection experiments to succeed, it remains possible that these models are either incorrect or only explain part of the dark matter phenomenon. Thus, even with the multiple experiments dedicated to providing indirect evidence for the existence of cold dark matter, direct detection measurements are also necessary to solidify the theory of WIMPs. Although most WIMPs encountering the Sun or the Earth are expected to pass through without any effect, it is hoped that a large number of dark matter WIMPs crossing a sufficiently large detector will interact often enough to be seen—at least a few events per year. The general strategy of current attempts to detect WIMPs is to find very sensitive systems that can be scaled to large volumes. This follows the lessons learned from the history of the discovery, and (by now routine) detection, of the neutrino.
Experimental techniques Cryogenic crystal detectors – A technique used by the
Cryogenic Dark Matter Search (CDMS) detector at the
Soudan Mine relies on multiple very cold germanium and silicon crystals. The crystals (each about the size of a hockey puck) are cooled to about 50
mK. A layer of metal (aluminium and tungsten) at the surfaces is used to detect a WIMP passing through the crystal. This design hopes to detect vibrations in the crystal matrix generated by an atom being "kicked" by a WIMP. The tungsten
transition edge sensors (TES) are held at the critical temperature so they are in the
superconducting state. Large crystal vibrations will generate heat in the metal and are detectable because of a change in
resistance.
CRESST,
CoGeNT, and
EDELWEISS run similar setups.
Noble gas scintillators – Another way of detecting atoms "knocked about" by a WIMP is to use
scintillating material, so that light pulses are generated by the moving atom and detected, often with PMTs. Experiments such as
DEAP at
SNOLAB and
DarkSide at the
LNGS instrument a very large target mass of liquid argon for sensitive WIMP searches.
ZEPLIN, and
XENON used xenon to exclude WIMPs at higher sensitivity, with the most stringent limits to date provided by the XENON1T detector, utilizing 3.5 tons of liquid xenon. Even larger multi-ton liquid xenon detectors have been approved for construction from the
XENON,
LUX-ZEPLIN and
PandaX collaborations.
Crystal scintillators – Instead of a liquid noble gas, an in principle simpler approach is the use of a scintillating crystal such as NaI(Tl). This approach is taken by
DAMA/LIBRA, an experiment that observed an annular modulation of the signal consistent with WIMP detection (see ''''). Several experiments are attempting to replicate those results, including
ANAIS,
COSINUS and
DM-Ice, which is codeploying NaI crystals with the
IceCube detector at the South Pole.
KIMS is approaching the same problem using CsI(Tl) as a scintillator.
Bubble chambers – The
PICASSO (Project In Canada to Search for Supersymmetric Objects) experiment is a direct dark matter search experiment that is located at
SNOLAB in Canada. It uses bubble detectors with
Freon as the active mass. PICASSO is predominantly sensitive to spin-dependent interactions of WIMPs with the fluorine atoms in the Freon. COUPP, a similar experiment using trifluoroiodomethane(CF3I), published limits for mass above 20 GeV/
c2 in 2011. The two experiments merged into PICO collaboration in 2012. A bubble detector is a radiation sensitive device that uses small droplets of superheated liquid that are suspended in a gel matrix. It uses the principle of a
bubble chamber but, since only the small droplets can undergo a
phase transition at a time, the detector can stay active for much longer periods. When enough energy is deposited in a droplet by ionizing radiation, the superheated droplet becomes a gas bubble. The bubble development is accompanied by an acoustic shock wave that is picked up by piezo-electric sensors. The main advantage of the bubble detector technique is that the detector is almost insensitive to background radiation. The detector sensitivity can be adjusted by changing the temperature, typically operated between 15 °C and 55 °C. There is another similar experiment using this technique in Europe called SIMPLE. PICASSO reports results (November 2009) for spin-dependent WIMP interactions on 19F, for masses of 24 Gev new stringent limits have been obtained on the spin-dependent cross section of 13.9 pb (90% CL). The obtained limits restrict recent interpretations of the DAMA/LIBRA annual modulation effect in terms of spin dependent interactions. PICO is an expansion of the concept planned in 2015.
Other types of detectors –
Time projection chambers (TPCs) filled with low pressure gases are being studied for WIMP detection. The
Directional Recoil Identification From Tracks (DRIFT) collaboration is attempting to utilize the predicted directionality of the WIMP signal. DRIFT uses a
carbon disulfide target, that allows WIMP recoils to travel several millimetres, leaving a track of charged particles. This charged track is drifted to an
MWPC readout plane that allows it to be reconstructed in three dimensions and determine the origin direction. DMTPC is a similar experiment with CF4 gas. The DAMIC (DArk Matter In CCDs) and SENSEI (Sub Electron Noise Skipper CCD Experimental Instrument) collaborations employ the use of scientific
Charge Coupled Devices (CCDs) to detect light Dark Matter. The CCDs act as both the detector target and the readout instrumentation. WIMP interactions with the bulk of the CCD can induce the creation of electron-hole pairs, which are then collected and readout by the CCDs. In order to decrease the noise and achieve detection of single electrons, the experiments make use of a type of CCD known as the Skipper CCD, which allows for averaging over repeated measurements of the same collected charge.
Recent limits There are currently no confirmed detections of dark matter from direct detection experiments, with the strongest exclusion limits coming from the
LUX and
SuperCDMS experiments, as shown in figure 2. With 370 kilograms of xenon, LUX is more sensitive than XENON or CDMS. The first results from October 2013 report that no signals were seen, appearing to refute results obtained from less sensitive instruments. This was confirmed after the final data run ended in May 2016. Historically, there have been four anomalous sets of data from different direct detection experiments, two of which have now been explained with backgrounds (
CoGeNT and CRESST-II), and two which remain unexplained (
DAMA/LIBRA and
CDMS-Si). In February 2010, researchers at CDMS announced that they had observed two events that may have been caused by WIMP-nucleus collisions.
CoGeNT, a smaller detector using a single germanium puck, designed to sense WIMPs with smaller masses, reported hundreds of detection events in 56 days. They observed an annual modulation in the event rate that could indicate light dark matter. However, a dark matter origin for the CoGeNT events has been refuted by more recent analyses, in favour of an explanation in terms of a background from surface events. Annual modulation is one of the predicted signatures of a WIMP signal, and on this basis the DAMA collaboration has claimed a positive detection. Other groups, however, have not confirmed this result. The CDMS data, made public in May 2004. exclude the entire DAMA signal region given certain standard assumptions about the properties of the WIMPs and the dark matter halo, and this has been followed by many other experiments (see Figure 2). The
COSINE-100 collaboration (a merging of KIMS and DM-Ice groups) published their results on replicating the DAMA/LIBRA signal in December 2018 in journal Nature; their conclusion was that "this result rules out WIMP–nucleon interactions as the cause of the annual modulation observed by the DAMA collaboration". In 2021, new results from COSINE-100 and
ANAIS-112 both failed to replicate the DAMA/LIBRA signal and in August 2022, COSINE-100 applied an analysis method similar to one used by DAMA/LIBRA and found a similar annual modulation suggesting the signal could be just a statistical artifact, supporting a hypothesis first put forward in 2020.
Future of direct detection The 2020s should see the emergence of several multi-tonne mass direct detection experiments, which will probe WIMP-nucleus cross sections orders of magnitude smaller than the current state-of-the-art sensitivity. Examples of such next-generation experiments are LUX-ZEPLIN (LZ) and XENONnT, which are multi-tonne liquid xenon experiments, followed by DARWIN, another proposed liquid xenon direct detection experiment of 50–100 tonnes. Such multi-tonne experiments will also face a new background in the form of neutrinos, which will limit their ability to probe the WIMP parameter space beyond a certain point, known as the neutrino floor. However, although its name may imply a hard limit, the neutrino floor represents the region of parameter space beyond which experimental sensitivity can only improve at best as the square root of exposure (the product of detector mass and running time). For WIMP masses below 10 GeV/
c2, the dominant source of neutrino background is from the
Sun, while for higher masses the background contains contributions from
atmospheric neutrinos and the
diffuse supernova neutrino background. In December 2021, results from
PandaX have found no signal in their data, with a lowest excluded cross section of at 40 GeV with 90% confidence level. In July 2023, the
XENONnT and
LZ experiment published the first results of their searches for WIMPs, the first excluding cross sections above at 28 GeV with 90% confidence level and the second excluding cross sections above at 36 GeV with 90% confidence level. == See also ==