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@ARTICLE{Teklishyn:364046,
      author       = {Teklishyn, Maksym and Sánchez, L. M. Collazo and
                      Frankenfeld, U. and Heuser, Johann and Kshyvanskyi, O. and
                      Lehnert, J. and Zaldivar, D. A. Ramírez and Garcés, D.
                      Rodríguez and Rodriguez, Tomas and Schmidt, C. J. and
                      Semeniuk, P. and Shiroya, Mehulkumar and Sharma, A. and
                      Toia, A. and Vasylyev, O.},
      title        = {{M}inimal material, maximum coverage: {S}ilicon {T}racking
                      {S}ystem for high-occupancy conditions},
      journal      = {Nuclear instruments $\&$ methods in physics research /
                      Section A},
      volume       = {1080},
      issn         = {0167-5087},
      address      = {[Amsterdam]},
      publisher    = {Elsevier},
      reportid     = {GSI-2026-00228},
      pages        = {170714},
      year         = {2025},
      note         = {This is an open access article under the CC BY license (
                      http://creativecommons.org/licenses/by/4.0/ )},
      abstract     = {Silicon strip sensors have long been a reliable technology
                      for particle detection. Here, we push the limits of silicon
                      tracking detectors by targeting an unprecedentedly low
                      material budget of $2\%–7\%$ X0 in an 8-layer 4 m2
                      detector designed for high-occupancy environments (≤ 10
                      MHz/cm2). To achieve this, we employ Double-Sided Double
                      Metal (DSDM) silicon microstrip sensors, coupled with
                      readout electronics capable of precise timing and energy
                      measurements. These 320μm thick sensors, featuring 2 ×
                      1024 channels with a 58μm pitch, are connected via
                      ultra-lightweight aluminum-polyimide microcables for signal
                      transmission and integrated with a custom SMX readout ASIC,
                      operating in free-streaming mode. This system enables the
                      simultaneous measurement of time (Δt≃5ns) and charge
                      deposition (0.1–100 fC), significantly enhancing the
                      detector’s capacity for high-precision track
                      reconstruction in high-occupancy and harsh radiation field
                      environments. The primary application of this technology is
                      the Silicon Tracking System (STS) for the CBM experiment,
                      with additional potential in projects like the J-PARC E16
                      experiment and future uses in medical physics, such as
                      advanced imaging telescopes. In this contribution, we
                      present the current status of CBM STS construction, with
                      almost one-third of the modules produced and tested. We also
                      discuss immediate applications and explore promising
                      prospects in both scientific and medical fields.},
      cin          = {CBM / CBM@FAIR},
      ddc          = {530},
      cid          = {I:(DE-Ds200)CBM-20080821OR102 / I:(DE-Ds200)Coll-FAIR-CBM},
      pnm          = {612 - Cosmic Matter in the Laboratory (POF4-612)},
      pid          = {G:(DE-HGF)POF4-612},
      experiment   = {$EXP:(DE-Ds200)External_experiment-20200803$},
      typ          = {PUB:(DE-HGF)16},
      doi          = {10.1016/j.nima.2025.170714},
      url          = {https://repository.gsi.de/record/364046},
}