Documents

• Technical Design Report for the Phase I Mu3e Experiment, September 2020

• Research Proposal to PSI, December 2012

• Letter of Intent to PSI, January 2012

• Mu3e Data Preservation and Access Policy, September 2018

2020

• K. Arndt et al. Technical design of the phase I Mu3e experiment, arXiv:2009.11690, 2020.
• A. Papa Towards a new generation of Charged Lepton Flavour Violation searches at the Paul Scherrer Institut: The MEG upgrade and the Mu3e experiment, EPJ Web Conf. 234 01011, 2020.
• F. Meier Aeschbacher, M. Deflorin, L. Noehte Mechanics, readout and cooling systems of the Mu3e experiment, arxiv:2003.11077, 2020.
• H. Klingenmeyer et al. Measurements with the technical prototype for the Mu3e tile detector, Nucl.Instrum.Meth.A 958, 162852, 2020.
• A. Bravar et al. The Mu3e scintillating fiber timing detector, Nucl.Instrum.Meth.A 958, 162564, 2020.
• D. vom Bruch Real-time data processing with GPUs in high energy physics, arxiv:2003.11491, 2020.
• A. Schöning et al. MuPix and ATLASPix - Architectures and Results, arxiv:2002.07253, 2020.

2019

• P. Cattaneo and A. Schöning MEG II and Mu3e status and plan, EPJ Web of Conferences 212, 01004, 2019.
• H. Augustin et al. Performance of the large scale HV-CMOS pixel sensor MuPix8, arxiv:1905.09309, JINST 14, C10011 (2019).
• F. Wauters The search for Lepton-Flavour Violation with the Mu3e Experiment , PoS NuFACT2018 140 (2019).
• S. Bravar The Mu3e Experiment at PSI, SciPost Phys.Proc. 1  037 (2019).

2018

• A.-K. Perrevoort The Rare and Forbidden: Testing Physics Beyond the Standard Model with Mu3e, arxiv:1812.00741, 2018, SciPost Phys.Proc. 1, 052 (2019).
• H. Augustin et al. MuPix8 – Large Area Monolithic HVCMOS Pixel Detector for the Mu3e Experiment, Nucl. Instr. Meth., A936 681 (2019).
• H. Augustin et al. Efficiency and timing performance of the MuPix7 high-voltage monolithic active pixel sensor, arxiv:1803.01581 (physics.ins-det), Nucl.Instr.Meth. A902, 158 (2018).
• E. Vilella et al. Report on recent activities in HV-CMOS detectors for Mu3e, ATLAS and RD50, JINST 13 C07002 (2018).
• A.-K. Perrevoort Searching for Lepton Flavour Violation with the Mu3e Experiment, arxiv:1802.09851 (physics.ins-det), Proceedings of the 19th International Workshop on Neutrinos from Accelerators (NUFACT 2017).
• D. Wiedner et al. Readout Electronics for the First Large HV-MAPS Chip for Mu3e, PoS(TWEPP-17)099, Proceedings of the topical workshop on electronics in particle physics (TWEPP 2017).

2017

• H. Augustin et al. Irradiation study of a fully monolithic HV-CMOS pixel sensor design in AMS 180 nm, arxiv:1712.03921 (physics.ins-det), Nucl.Instr.Meth. A905, 53 (2018)
• D. vom Bruch Online Data Reduction using Track and Vertex Reconstruction on GPUs for the Mu3e Experiment, EPJ Web Conf., 150 00013 (2017).
• A. Kozlinskiy Track reconstruction for the Mu3e experiment based on a novel Multiple Scattering fit, EPJ Web Conf., 150 00005 (2017).
• A. Bravar et al. Scintillating fibre detector for the Mu3e experiment, JINST 12, C07011 (2017).
• H.S. Chen et al. Characterization Measurement Results of MuTRiG - A Silicon Photomultiplier Readout ASIC with High Timing Precision and High Event Rate Capability, PoS TWEPP-17 008 (2017).
• D. Wiedner Status of the Mu3e Detector, JINST 12 C06028 (2017).
• A. Bravar The Mu3e Experiment, Nucl.Part.Phys.Proc. 287-288 169 (2017).
• A. Damayonova and A. Bravar Scintillating fiber detectors for precise time and position measurements read out with Si-PMs, Nucl.Instrum.Meth. A845 475 (2017).
• H. Augustin et al. The MuPix Telescope: A Thin, High-Rate Tracking Telescope, JINST 12 C01087 (2017).
• H. Chen et al. MuTRiG: a mixed signal Silicon Photomultiplier readout ASIC with high timing resolution and gigabit data link, JINST 12 C01043 (2017).

2016

• H. Augustin et al. MuPix7 - A fast monolithic HV-CMOS pixel chip for Mu3e, arXiv:1610:02210 (physics.ins-det), JINST 11 C11029 (2016).
• N. Berger et al. Ultra-low material pixel layers for the Mu3e experiment, arXiv:1610.02021 (physics.ins-det), JINST 11 C12006 (2016).
• N. Berger et al. A New Three-Dimensional Track Fit with Multiple Scattering, arXiv:1606.04990 (physics.ins-det), Nucl. Instrum. Meth. A 844C, 135 (2017).
• H. Augustin et al. The MuPix System-on-Chip for the Mu3e Experiment, arXiv:1603.08751 (physics.ins-det), Nucl. Instrum. Meth. A845 194 (2017).
• A. Bravar The Mu3e Experiment at PSI, PoS ICHEP2016 552 (2016).

2015

• I. Peric et al. Overview of HVCMOS pixel sensors, JINST 10 C05021 (2015).
• H. Augustin et al. The MuPix high voltage monolithic active pixel sensor for the Mu3e experiment, JINST 10 C03044 (2015).
• A. Bravar The Mu3e Experiment at PSI, Nucl.Part.Phys.Proc. 260, 155-159 (2015).

2014

• N. Berger et al. Multiple Coulomb Scattering in Thin Silicon JINST 9 P07007 (2014), arxiv:1405.2759.
• N. Berger The Mu3e Experiment Nucl. Phys. B (Proc. Suppl.) 248-250 35-40 (2014).
• S. Bachmann et al. The proposed trigger-less TBit/s readout for the Mu3e experiment, JINST 9 C01011 (2014).
• N. Berger et al. The ultra-lightweight support structure and gaseous helium cooling for the Mu3e silicon pixel tracker, JINST 9 C08023 (2014).
• A. Kozlinskiy et al. A new track reconstruction algorithm for the Mu3e experiment based on a fast multiple scattering fit, JINST 9 C12012 (2014).

2013

• I. Peric et al. High-voltage pixel detectors in commercial CMOS technologies for ATLAS, CLIC and Mu3e experiments, Nucl. Instrum. Meth. A731 131 (2013).
• N. Berger et al. A Tracker for the Mu3e Experiment based on High-Voltage Monolithic Active Pixel Sensors, Nucl. Instrum. Meth. A732 61; arxiv:1309.7895