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000626193 1001_ $$0P:(DE-H253)PIP1102343$$aDavis, Naomi$$b0$$eCorresponding author$$udesy
000626193 1112_ $$aProceedings of the Vienna Conference on Instrumentation$$cVienna$$d2025-02-17 - 2025-02-21$$gVCI2025$$wAustria
000626193 245__ $$aSimulation of CMOS strip sensors
000626193 260__ $$a[Amsterdam]$$bElsevier$$c2025
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000626193 520__ $$aIn high-energy physics, there is a need to investigate silicon sensor concepts that offer large-area coverage and cost-efficiency for particle tracking detectors. Sensors based on CMOS imaging technology present a promising alternative silicon sensor concept. As this technology follows an industry process, it can lower sensor production costs and enable fast and large-scale production from various vendors. The CMOS strips project investigates passive CMOS strip sensors fabricated by LFoundry in a 150nm technology. The stitching technique was employed to develop two different strip sensor formats. The strip implant layout varies in doping concentration and width, allowing the study of various depletion concepts and electric field configurations. The performance of the first CMOS strip sensor prototype was evaluated based on several test beam campaigns conducted at the DESY II Test Beam Facility. In order to understand and validate the test beam data results, the detector response was simulated. This study shows how performance differences of the various strip sensor layouts can be investigated using Monte Carlo methods combined with TCAD Device simulations. In particular, the detector response simulated with Allpix2 is presented and compared to test beam data.
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000626193 650_7 $$2autogen$$aCMOS
000626193 650_7 $$2autogen$$aSilicon strip sensors
000626193 650_7 $$2autogen$$aTest beam
000626193 650_7 $$2autogen$$aTCAD
000626193 650_7 $$2autogen$$aAllpix
000626193 650_7 $$2autogen$$aMonte Carlo simulation
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000626193 7001_ $$0P:(DE-H253)PIP1022800$$aArling, Jan-Hendrik$$b1$$udesy
000626193 7001_ $$aBaselga, Marta$$b2
000626193 7001_ $$aDiehl, Leena$$b3
000626193 7001_ $$aDingfelder, Jochen$$b4
000626193 7001_ $$aGregor, Ingrid-Maria$$b5
000626193 7001_ $$aHauser, Marc$$b6
000626193 7001_ $$aHügging, Fabian$$b7
000626193 7001_ $$aJakobs, Karl$$b8
000626193 7001_ $$aKaragounis, Michael$$b9
000626193 7001_ $$aKoppenhöfer, Roland$$b10
000626193 7001_ $$aKröninger, Kevin$$b11
000626193 7001_ $$aLex, Fabian$$b12
000626193 7001_ $$aParzefall, Ulrich$$b13
000626193 7001_ $$aSari, Birkan$$b14
000626193 7001_ $$aSorgenfrei, Niels$$b15
000626193 7001_ $$aSpannagel, Simon$$b16
000626193 7001_ $$aSperlich, Dennis$$b17
000626193 7001_ $$0P:(DE-H253)PIP1021838$$aVelyka, Anastasiia$$b18$$udesy
000626193 7001_ $$aWeingarten, Jens$$b19
000626193 7001_ $$aWei, Yingjie$$b20
000626193 7001_ $$aZatocilova, Iveta$$b21
000626193 773__ $$0PERI:(DE-600)1466532-3$$a10.1016/j.nima.2025.170807$$gVol. 1080, p. 170807 -$$p170807$$tNuclear instruments & methods in physics research / Section A$$v1080$$x0167-5087$$y2025
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