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@ARTICLE{Anders:1016535,
      author       = {Anders, Jens and Babaie, Masoud and Bardin, Joseph C. and
                      Bashir, Imran and Billiot, Gérard and Blokhina, Elena and
                      Bonen, Shai and Charbon, Edoardo and Chiaverini, John and
                      Chuang, Isaac L. and Degenhardt, Carsten and Englund, Dirk
                      and Geck, Lotte and Le Guevel, Loïck and Ham, Donhee and
                      Han, Ruonan and Ibrahim, Mohamed I. and Krüger, Daniel and
                      Lei, Ka Meng and Morel, Adrien and Nielinger, Dennis and
                      Pillonnet, Gaël and Sage, Jeremy M. and Sebastiano, Fabio
                      and Staszewski, Robert Bogdan and Stuart, Jules and
                      Vladimirescu, Andrei and Vliex, Patrick and Voinigescu,
                      Sorin P.},
      title        = {{CMOS} {I}ntegrated {C}ircuits for the {Q}uantum
                      {I}nformation {S}ciences},
      journal      = {IEEE transactions on quantum engineering},
      volume       = {4},
      issn         = {2689-1808},
      address      = {New York, NY},
      publisher    = {IEEE},
      reportid     = {FZJ-2023-03701},
      pages        = {5100230},
      year         = {2023},
      abstract     = {Over the past decade, significant progress in quantum
                      technologies has been made, and hence, engineering of these
                      systems has become an important research area. Many
                      researchers have become interested in studying ways in which
                      classical integrated circuits can be used to complement
                      quantum mechanical systems, enabling more compact,
                      performant, and/or extensible systems than would be
                      otherwise feasible. In this article—written by a
                      consortium of early contributors to the field—we provide a
                      review of some of the early integrated circuits for the
                      quantum information sciences. Complementary metal--oxide
                      semiconductor (CMOS) and bipolar CMOS (BiCMOS) integrated
                      circuits for nuclear magnetic resonance,
                      nitrogen-vacancy-based magnetometry, trapped-ion-based
                      quantum computing, superconductor-based quantum computing,
                      and quantum-dot-based quantum computing are described. In
                      each case, the basic technological requirements are
                      presented before describing proof-of-concept integrated
                      circuits. We conclude by summarizing some of the many open
                      research areas in the quantum information sciences for CMOS
                      designers.},
      cin          = {ZEA-2},
      ddc          = {621.3},
      cid          = {I:(DE-Juel1)ZEA-2-20090406},
      pnm          = {5223 - Quantum-Computer Control Systems and Cryoelectronics
                      (POF4-522)},
      pid          = {G:(DE-HGF)POF4-5223},
      typ          = {PUB:(DE-HGF)16},
      UT           = {WOS:001376834500001},
      doi          = {10.1109/TQE.2023.3290593},
      url          = {https://juser.fz-juelich.de/record/1016535},
}