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@PHDTHESIS{Malygina:218538,
author = {Malygina, Hanna},
othercontributors = {Senger, Peter and Stroth, Joachim},
title = {{H}it reconstruction for the {S}ilicon {T}racking {S}ystem
of the {CBM} experiment},
school = {Johann Wolfgang Goethe-Universität},
type = {Dissertation},
reportid = {GSI-2019-00457},
pages = {155},
year = {2018},
note = {Dissertation, Johann Wolfgang Goethe-Universität, 2018},
abstract = {The mission of the Compressed Baryonic Matter (CBM)
experiment is to investigate the phase diagram of strongly
interacting matter in the region of high net-baryon
densities and moderate temperatures. According to various
transport models, matter densities of more than 5 times
saturation density can be reached in collisions between gold
nuclei at beam energies between 5 and 11 GeV per nucleon,
which will be available at FAIR. The core detector of the
CBM experiment is the Silicon Tracking System (STS), which
is used to measure the tracks of up to 700 particles per
collision with high efficiency $(>95\%)$ and good momentum
resolution $(<1.5\%).$ The technological and experimental
challenge is to realize a detector system with very low
material budget, in order to reduce multiple scattering of
the particles, and a free-streaming data readout chain, in
order to achieve reaction rates up to 10 MHz together with
an online event reconstruction and selection. The STS
comprises 8 tracking stations positioned between 30 cm and
100 cm downstream the target inside a magnetic field,
covering polar emission angles up to 25 degrees. A station
consists of vertical structures with increasing number
(between 8 and 16, depending on station number), each
structure carrying between 2 and 10 double-sided microstrip
silicon sensors, which are connected through low-mass
microcables to the readout electronics placed at the
detector periphery outside the active detector area. The
work presented in this thesis focuses on the detector
performance simulation and local hit pattern reconstruction
in the STS. For efficient detector design and reconstruction
performance, a reliable detector response model is of utmost
importance. Within this work, a realistic detector response
model was designed and implemented in the CBM software
framework. The model includes non-uniform energy loss of an
incident particle within a sensor, electric field of a
planar p-n junction, Lorentz shift of the charge carriers,
their diffusion, and the influence of parasitic
capacitances. The developed model has been verified with
experimental data from detector tests in a relativistic
proton beam. Cluster size distributions at different beam
incident angles are sensitive to charge sharing effects and
were chosen as an observable for the verification. Taking
into account parasitic capacitances further improves the
agreement with measured data. Using the developed detector
response model, the cluster position finding algorithm was
improved. For two-strip clusters, a new, unbiased algorithm
has been developed, which gives smaller residuals than the
Centre-Of-Gravity algorithm. For larger clusters, the
head-tail algorithm is used as the default one. For an
estimate of the track parameters, the Kalman Filter based
track fit requires not only hit positions but their
uncertainties as an input. A new analytic method to estimate
the hit position errors has been designed in this work. It
requires as input neither measured spatial resolution nor
information about an incident particle track. The method
includes all the sources of uncertainties independently,
namely: the cluster position finding algorithm itself, the
non-uniform energy loss of incident particles, the
electronics noise, and the discretisation of charge in the
readout chip. The verification with simulations shows
improvements in hit and track pull distributions as well as
x²-distributions in comparison to the previous simple
approach. The analytic method improves the track parameters
reconstruction by $5-10\%.$ Several STS module prototypes
have been tested in a relativistic proton beam. A signal
to-noise ratio was obtained at the level of 10-15 for
modules made of 30 cm long microcable and of either one or
two 6.2 x 6.2 cm² CiS sensors. First simulations have shown
that this signal-to-noise ratio is sufficient to reach the
required efficiency and momentum resolution. The
high-radiation environment of CBM operation will deteriorate
the sensor performance. Radiation hardness of sensors has
been studied in the beam with sensors irradiated to 2 x
10[hoch 14] 1MeV [neq/cm²], twice the lifetime dose
expected for CBM operation. Charge collection efficiency
drops by $17-25\%,$ and simultaneously noise levels increase
1.5-1.75 times. The simulations show that if all sensors in
the STS setup are exposed to such a fluence uniformly, the
track reconstruction efficiency drops from $95.5\%$ to
$93.2\%$ and the momentum resolution degrades from $1.6\%$
to $1.7\%.$},
cin = {CBM / CBM@FAIR},
cid = {I:(DE-Ds200)CBM-20080821OR102 / I:(DE-Ds200)Coll-FAIR-CBM},
pnm = {612 - Cosmic Matter in the Laboratory (POF3-612) /
SUC-GSI-Frankfurt - Strategic university cooperation GSI-U
Frankfurt/M (SUC-GSI-FR) / HGS-HIRe - HGS-HIRe for FAIR
(HGS-HIRe)},
pid = {G:(DE-HGF)POF3-612 / G:(DE-Ds200)SUC-GSI-FR /
G:(DE-Ds200)HGS-HIRe},
typ = {PUB:(DE-HGF)11},
urn = {urn:nbn:de:hebis:30:3-464018},
url = {https://repository.gsi.de/record/218538},
}
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