D. L'Hote et al., Charge and heat collection in a 70 g heat/ionization cryogenic detector for dark matter search, J APPL PHYS, 87(3), 2000, pp. 1507-1521
We present detailed studies of the physical mechanisms underlying the colle
ction of the charge carriers and of the thermal energy in a heat/ionization
germanium particle detector operated at 20-28 mK, together with a presenta
tion of its main performances. This detector is devoted to the search of da
rk matter particles, taking advantage of the double signal to reject backgr
ound induced events. In what concerns the ionization channel, the current-v
oltage characteristics, energy resolution, time stability, and pulse height
bias dependence are presented. A mechanism is proposed to explain the fact
that the p-i-n diode maintains some rectifying properties in spite of the
very low temperature. The energy resolution is 1 keV full width at half max
imum (FWHM) at 86.5 keV, and the stability time is several days. A calculat
ion of the carrier trapping contribution to the energy resolution and bias
dependence is performed and its results compared to the data. The bias depe
ndence is interpreted within a "hot" carrier model in which the shape of th
e trapping cross section as a function of the electric field is investigate
d. The time stability behavior is interpreted in terms of a space charge ev
olution due to traps ionization. The reasons why the densities of ionized l
evels are minimized are discussed. It is shown that one of them is related
to the low currents obtained at rather large biases because of the choice o
f a p-i-n scheme. In what concerns the heat channel, an analysis of the hea
t flow in the thermal circuit is performed to explain the shape and amplitu
de of the heat pulses. The risetimes are well accounted for, allowing a det
ermination of the NTD electronic specific heat, (1.80 +/- 0.45) x 10(-6) T
J K-1 cm(-3). The analysis of the two decay times leads to an interpretatio
n in terms of partial thermalization of the ballistic phonons in the metall
ic parts of the detector. This mechanism allows to estimate the experimenta
l responsivities and energy resolutions [6 and 20 nV/keV; 1.25 and 2.8 keV
(FWHM) for sensor temperatures of respectively 20.5 and 28 mK]. Both the io
nization and heat channel results are used to draw guidelines for detector
performance improvements and mass increase. (C) 2000 American Institute of
Physics. [S0021-8979(00)02303-3].