Acta Polytechnica


doi:10.14311/AP.2013.53.0555
Acta Polytechnica 53(Supplement):555–559, 2013 © Czech Technical University in Prague, 2013

available online at http://ojs.cvut.cz/ojs/index.php/ap

RESULTS FROM THE XENON100 EXPERIMENT

Rino Persiani∗

University of Bologna and INFN-Bologna, Bologna, Italy
∗ corresponding author: Rino.Persiani@bo.infn.it

Abstract. The XENON program consists in operating and developing double-phase time projection
chambers using liquid xenon as the target material. It aims to directly detect dark matter in the form
of WIMPs via their elastic scattering off xenon nuclei. The current phase is XENON100, located at
the Laboratori Nazionali del Gran Sasso (LNGS), with a 62 kg liquid xenon target. We present the
100.9 live days of data, acquired between January and June 2010, with no evidence of dark matter, as
well as the new results of the last scientific run, with about 225 live days. The next phase, XENON1T,
will increase the sensitivity by two orders of magnitude.

Keywords: dark matter, WIMP, xenon.

1. Introduction
Astronomical and cosmological observations indicate
that a large amount of the energy content in the Uni-
verse is made of dark matter [1]. Particle candidates
under the generic name of Weakly Interacting Mas-
sive Particles (WIMPs) arise naturally in many theo-
ries beyond the Standard Model of particle physics,
such as supersymmetry, universal extra dimensions,
or little Higgs models [2]. They may be observed
in underground-based detectors, sensitive enough to
measure the low-energy nuclear recoil resulting from
the coherent scattering of a WIMP with a target nu-
cleus [3].
The XENON dark matter project searches for nu-

clear recoils from WIMPs scattering off xenon nuclei.
In a phased approach, experiments with increasingly
larger mass and lower background are being operated
underground, at the INFN Laboratori Nazionali del
Gran Sasso (LNGS) in Italy [4]. XENON100 is the
current phase of the XENON program, which aims to
improve the sensitivity to dark matter interactions in
liquid xenon (LXe) with two-phase (liquid/gas) time-
projection chambers (TPCs) of large mass and low
background. The extraordinary sensitivity of XENON
to dark matter is due to the combination of a large,
homogeneous volume of ultra pure liquid xenon as the
WIMP target, in a detector which measures not only
the energy, but also the three spatial coordinates of
each event occurring within the active target. The
ability to localise events within millimetre resolution,
enables the selection of a fiducial volume in which the
radioactive background is minimised.
The simultaneous detection of the Xe scintillation

light (S1) at the few keVee level (keV electron equiva-
lent), and ionization (S2) at the single electron level,
allows to discriminate electronic recoils (ERs) from
nuclear recoils (NRs), providing the basis of one of
the major background techniques.

2. XENON100

2.1. Detector description

The XENON100 detector is a double-phase (liquid-
-gas) time projection chamber (TPC). A particle inter-
acting with the target generates scintillation light and
ionization electrons (Fig. 1). The primary light (S1) is
detected immediately by two photomultiplier (PMT)
arrays above and below the target. The light read-
out is based on 1"-square Hamamatsu R8520-06-Al
low-radioactive PMTs with quantum efficiencies up
to ∼ 35 %. 98 PMTs in the top array are arranged
to improve the position reconstruction, 80 PMTs on
the bottom to optimise the light collection. The other
64 PMTs are located in the LXe veto to reduce the
background.
Each interaction liberates electrons, which are

drifted upwards across the TPC by an electric field
(∼ 0.53 kV/cm) to the liquid-gas interface with a speed
of about 2 mm/µs. These electrons are then extracted
into the gas phase by a strong extraction field. In
the gas phase, the electrons generate very localised
secondary scintillation light (S2), which can be used
to determine the horizontal position of the interaction
vertex with a resolution < 3 mm (1σ). The time differ-
ence between these two signals gives the depth of the
interaction in the TPC with a resolution of 0.3 mm
(1σ).

The event positions can be fully reconstructed and
used to federalise the target volume in order to drasti-
cally reduce the radioactive background from external
sources. The high ionization density of nuclear recoils
(NRs) in LXe leads to larger S1 and smaller S2 signals
compared to electron recoils (ERs). The simultaneous
measurement of charge and light provides powerful dis-
crimination between NR signals and ER background
events via the ratio S2/S1.

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Rino Persiani Acta Polytechnica

Figure 1. Principle of a two-phase liquid xenon TPC.
A particle generates primary scintillation light (S1)
and ionization electrons. These are drifted upwards by
an electric field and detected via secondary scintillation
light in the gas phase (S2). The S2 hit pattern (xy) and
the drift time (z) give three-dimensional information
on the position of events. Additionally, the ratio S2/S1
allows event discrimination between nuclear recoils
(WIMPs, neutron) and electron recoils (γ,β).

2.2. Detector backgrounds
The background in XENON100 comes mainly from
external sources and from the materials used for the
construction of the detector itself.
In order to reduce the background from the ra-

dioactivity in the experiment’s environment, in the
laboratory walls, etc. [5], a passive shield has been
installed. An improved version of the XENON10
shield [6] was required to increase the sensitivity of the
XENON100 experiment. The detector is surrounded
(from inside to outside) by 5 cm of copper, followed
by 20 cm of polyethylene, and 20 cm of lead, where
the innermost 5 cm consist of lead with low 210Pb
contamination [7]. The entire shield rests on a 25 cm
thick slab of polyethylene. An additional outer layer
of 20 cm of water and polyethylene has been added on
top and on 3 sides of the shield to reduce the neutron
background further. Figure 2 shows a picture of the
XENON100 detector in front of its shield. In order to
minimise the radioactive background in the detector,
the cryogenic system is located outside the passive
shield.
To reduce the radioactivity from the detector and

the shielding materials, radioactivity screening was
performed with a 2.2 kg high purity Ge detector in an
ultra-low background Cu cryostat and Cu/Pb shield,
operated at LNGS [8]. The radioactive contaminations
of each material screened can be found in reference [7].
The radioactivity of all the components has been

measured and is used as input for detailed Monte-
-Carlo simulations of the γ and neutron background
of the experiment. Gammas from the decay chains
of the radioactive contaminants in the detector ma-
terials dominate the electron recoil background. The
activity of the PMTs is the major contributor to the
current XENON100 electron recoil background (about
65 % of the total background from all detector and

Figure 2. XENON100 with opened shield door. The
circular copper pipe around the detector is used for
inserting calibration sources from outside the shield.
The Pb brick visible at the front is necessary to block
gamma rays from the AmBe source during neutron
calibration.

shield materials). This background in XENON100 is
6 × 10−3 dru. After 99 % electron recoil rejection we
obtain a conservative background rate of 6 × 10−5 dru.

A potentially dangerous background for XENON100
is the gamma background from the decay chain of
222Rn daughters inside the shield cavity. The aver-
age measured radon activity in the LNGS tunnel is
about 350 Bq/m3. Therefore, the shield cavity is con-
stantly flushed with nitrogen gas when the shield door
is closed. The 222Rn concentration in the cavity is
continuously monitored and the measured values are
at the limit of the sensitivity of the radon monitor
itself. Without the veto cut, the background rate from
1 Bq/m3 of 222Rn in the shield is 6 × 10−3 dru for the
entire target mass of 62 kg and 2 × 10−4 dru in the
30 % kg FV. This background is less than 2 % of the
background from the detector and shield materials.
Moreover, the measured radon concentration is well
below 1 Bq/m3.
There is no long-lived radioactive xenon isotope,

with the exception of the potential double beta emitter
136Xe, but its half-life is so long that it does not
limit the sensitivity of the detector. Another LXe
intrinsic background is due to 85Kr, which is a beta
emitter with an endpoint of 687 keV and a half-life of
10.76 years.

Its concentration in the detector can be measured
using a second decay mode (in a metastable state of
Rb) with a 0.454 % branching ratio. Commercially
available xenon gas has a concentration of natural
krypton at the ppm level and 85Kr has an isotopic
abundance of 85Kr/natKr ∼ 2 × 10−11. For the 85Kr-
-induced background to be subdominant, the fraction
of natKr in Xe must be at the level of 100 ppt. A
natKr/Xe ratio of 100 ppt would contribute a rate of
∼ 2 mdru from 85Kr [9]. To reduce the Kr level in Xe,
a small-scale cryogenic distillation column [10] was

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vol. 53 supplement/2013 Results from the XENON100 Experiment

Figure 3. Electronic (blue dots) and nuclear (red
dots) recoil bands in the log10(S2/S1) vs. energy
space. The electronic recoil band is obtained with
60Co and 232Th calibrations, performed weekly during
a dark matter search run. The nuclear recoil band is
measured with an AmBe source shielded by 10 cm of
lead. This calibration is performed at the beginning
or at the end of a dark matter search run, because of
neutron activation of Xe and other materials.

produced and integrated into the XENON100 system
underground. The column is designed to deliver a
factor 1000 in Kr reduction in a single pass.
The nuclear recoil background is estimated by

Monte-Carlo simulations and is based on the mea-
sured radioactivity concentrations. It takes into ac-
count the neutron spectra and the total production
rates from spontaneous fission and (α, n) reactions
in the detector, the shielding materials, and the
surrounding concrete-rock, calculated with a mod-
ified SOURCES4A code [11]. The muon flux at the
3600 mw.e. Gran Sasso depth is 24 muons/m2/day.
Muons will produce neutrons in the shielding materi-
als due to electromagnetic and hadronic showers and
through direct spallation.

High energy muon interacting in the rock-concrete
can produce highly penetrating neutrons with ener-
gies up to a few GeV. The impact of muon-induced
neutrons is obtained from simulations and contributes
70 % to the total NRs background.

2.3. Detector calibrations
To characterise the detector performances and its
stability in time, calibration sources are regularly
inserted in the XENON100 shield through a copper
tube surrounding the cryostat (see Fig. 2). While the
vertical position of sources is restricted to the TPC
centre, they can be placed at all azimuthal angles.
The electronic recoil band in log10(S2/S1) vs. en-

ergy space defines the region of background events
from β- and γ-particles (blue dots in Fig. 3). It is
measured using the low energy Compton tail of high-
energy γ-sources such as 60Co and 232Th. In the
225 day dark matter search, the amount of electronic

Figure 4. Results of AmBe calibration data. Besides
the NR recoil band due to neutron elastic scatter off
Xe nuclei, this calibration provides additional gamma
lines from neutron activation of xenon and fluorine (in
the teflon) nuclei at 40 keV (129Xe), 80 keV (131Xe),
110 keV (19F), 164 keV (131mXe), 197 keV (19F) and
236 keV (129mXe).

recoil calibration data taken is a significant increase
over that taken during the 100.9 day dark matter
search. The detector response to single scatter nu-
clear recoils, the expected signature of a WIMP scat-
tering off a nucleus, is measured with an AmBe (α, n)
source (red dots in Fig. 3). This source is shielded
by 10 cm of lead in order to suppress the contribu-
tion from its high energy gamma rays (4.4 MeV). The
comparison of the charge/light ratio allows to define
a region where most of the neutrons are, and only few
gammas. The discrimination power is ∼ 99.5 % at
low energies for 50 % neutron acceptance. Besides the
definition of the nuclear recoil band and a benchmark
WIMP search region, the AmBe calibration provides
additional gamma lines from inelastic scattering as
well as from xenon or fluorine (in the Teflon) neutron
activation at 40 keV (129Xe), 80 keV (131Xe), 110 keV
(19F), 164 keV (131mXe), 197 keV (19F) and 236 keV
(129mXe). These lines are clearly visible in Fig. 4 as
ellipsoids over the nuclear recoils band due to neutron
elastic scatters off xenon nuclei.

In order to get a uniform proportional scintillation
S2 signal, the liquid-gas interface has to be adjusted
at the optimal distance from the anode to optimise the
S2 resolution. This levelling was performed at the be-
ginning of the run with a 137Cs source, by varying the
overall liquid xenon level until the best resolution of
the full absorption S2 peak was found. After detector
levelling, two independent effects remain that have an
impact on the size of the proportional scintillation S2
signal from the charge: a) the absorption of electrons
as they drift (finite electron lifetime), leading to a
z-dependent correction, b) the reduced S2 light col-
lection efficiency at large radii, non-functional PMTs,
quantum efficiency differences between neighbouring
PMTs, as well as non-uniformities in the proportional
scintillation gap, leading to an S2 correction that de-
pends on the (x,y)-position of the S2 signal. Regular

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Rino Persiani Acta Polytechnica

Figure 5. New result on spin-independent WIMP-nucleon scattering from XENON100: The expected sensitivity
of this run is shown by the green/yellow band (1σ/2σ) and the resulting exclusion limit (90 % CL) in blue. For
comparison, the XENON100 exclusion limit of the last 100.9 day run and other experimental results are also
shown, together with regions (1σ/2σ) preferred by supersymmetric (CMSSM) models. The projected sensitivity for
XENON1T is shown in red.

137Cs calibration runs are taken in order to determine
the mean lifetime for electrons transversing the liquid
xenon volume (free electrons are removed through
ionization of impurities). The LXe is continuously
purified through a hot getter in order to reduce the
impurity level. In the 100.9 day dark matter search,
the mean electron lifetime increased from 230 µs to
380 µs, while in the last run (225 days) it increased
(constantly, if the maintenance periods are not taken
into account) from around 300 µs to 650 µs.

2.4. Data analysis
The data used in the analysis were selected from pe-
riods with stable detector operating conditions. We
excluded from the analysis all periods with xenon
pressure and temperature values that were more than
5 sigma away from the average value. After this selec-
tion, other parameters were found to be stable during
the whole science run. The radon concentration in the
XENON100 room and inside the shield cavity were
measured using a dedicated radon monitor, and the
concentration was stable for the whole period.
Two parallel analyses were performed to interpret

these data in a spin-independent WIMP-nucleon in-
teraction framework. The energy region used for both
analyses was (4 ÷ 30) PE in S1 corresponding to

(8.4 ÷ 44.6) keVnr. This energy region was lowered
from 4 PE to 3 PE for the analysis of the last run
(225 days). Before unblinding, it was decided to use
the Profile Likelihood analysis method [12] as the pri-
mary interpretation method which does not employ
a fixed discrimination in S2/S1 parameter space. A
cut-based analysis was also performed in [13] to cross
check the results.

The criteria applied to the science data to select can-
didate events in the region of interest are grouped into:
data quality cuts, energy selection and a threshold cut
on S2, selection of single scatter events, consistency
cuts, selection of the fiducial volume, and selection of
the signal region for the cut-based analysis [14].

3. Results
3.1. 100 live days DM search
The dark matter data analysed for this run was ac-
quired between January 13 and June 8, 2010. About
2 % of the exposure was rejected due to variations in
detector operation parameters. In addition, 18 live
days of data taken in April were rejected due to an
increased electronic noise level. Removing all the cali-
bration runs during the data-taking period, this led to
a dataset of 100.9 live days. The expected background

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vol. 53 supplement/2013 Results from the XENON100 Experiment

in the WIMP search region is the sum of the Gaussian
leakage from the ER background, of the non-Gaussian
leakage, and of the NRs from neutron interactions.
The total background prediction for 99.75 % ER rejec-
tion, 100.9 days of exposure and 48 kg fiducial mass
is (1.8 ± 0.6) events.
After unblinding the pre-defined WIMP search re-

gion, a population of events was observed that passed
the S1 coincidence requirement only because of the
correlated electronic noise. These events are mostly
found below the S1 analysis threshold, with 3 events
from this population leaking into the WIMP search
region close to the 4 PE lower bound. This population
was identified and rejected with a cut that takes into
account the correlated pick-up noise. Once they have
been removed, 3 events pass all quality criteria for
single-scatter NRs and fall in the WIMP search region.
Given the background expectation, the observation of
3 events does not constitute evidence for dark matter,
as the chance probability of the corresponding Poisson
process resulting in 3 or more events is 28 %.

3.2. 225 live days DM search
The last run of XENON100 represents 224.6 live days
of dark matter search data. Purification through a
dedicated krypton removal column saw the intrinsic
background of the liquid xenon drop by more than a
factor of 10. In the last run, for unblinded data (above
99.75 ER rejection) and a 30 kg fiducial mass, about
2 single-scatter events are observed per day below
30 PE in S1. These values illustrate the low count
rate in the electron recoil background in XENON100
and the improvement made with the reduction of the
intrinsic krypton background. Moreover, the trigger
threshold was lowered from 300 PE to 150 PE in S2.
The dark matter data analysed for this run was

acquired over 13 months in 2011 and 2012. A blind
analysis of 224.6 live days × 34 kg exposure yielded no
evidence for dark matter interactions. The two candi-
date events observed in the pre-defined nuclear recoil
energy range of 6.6 ÷ 30.5 keVnr are consistent with
the background expectation of (1.0 ± 0.2) events [15].

4. XENON1T
In parallel with the successful operations of
XENON100, the Collaboration has already designed
the next generation detector: XENON1T. The detec-
tor is based on an LXe TPC with a fiducial mass of
1 ton and a total mass of 2.4 tons of LXe, viewed by
low radioactivity photomultiplier tubes and housed
in a water Cherenkov muon veto at LNGS. Detailed
simulation studies informed by results from previous
XENON and other LXe detectors indicate that an
increase in the light yield of XENON1T relative to
XENON100 is achievable by adopting relatively mod-
est modifications to the design of the TPC, such as
greater coverage of non-reflective surfaces with PTFE
of near unity reflectivity, greater optical transmission

of electrode structures and, especially, greater quan-
tum efficiency of photomultiplier tubes. The back-
ground can be reduced through the selection of every
component used in the experiment, based on an ex-
tensive radiation screening campaign, using a variety
of complementary techniques and dedicated measure-
ments. Moreover the self-shielding of LXe is exploited
to attenuate and moderate radiation from material
components within the TPC and simultaneously a
fiducial volume will be defined, thanks to the TPC
event imaging capability. The experiment aims to
reduce the background from all expected sources such
that the fiducial mass and the low energy threshold
will allow XENON1T to achieve unprecedent sensitiv-
ity. With 2 years live-time and 1.1 ton fiducial mass,
XENON1T reaches sensitivity of 2 × 10−47 cm2 at
90 % CL for 50 GeV/c2 WIMPs, as shown in Fig. 5.

Acknowledgements
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559


	Acta Polytechnica 53(Supplement):555–559, 2013
	1 Introduction
	2 XENON100
	2.1 Detector description
	2.2 Detector backgrounds
	2.3 Detector calibrations
	2.4 Data analysis

	3 Results
	3.1 100 live days DM search
	3.2 225 live days DM search

	4 XENON1T
	Acknowledgements
	References