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@ARTICLE{Rader:643494,
      author       = {Rader, Oliver and Pascarelli, Sakura and Attenkofer, Klaus
                      and Makarova, Anna A. and Holldack, Karsten and Rossnagel,
                      Kai and Temst, Kristiaan and Kourousias, George and
                      Carretta, Stefano and Biscari, Caterina and Dosch, Helmut},
      title        = {{S}ynchrotron {R}adiation for {Q}uantum {T}echnology},
      journal      = {Advanced functional materials},
      volume       = {x},
      issn         = {1616-301X},
      address      = {Weinheim},
      publisher    = {Wiley-VCH},
      reportid     = {PUBDB-2026-00241},
      pages        = {e01043},
      year         = {2025},
      note         = {cc-byonline firstLEAPS-INNOV WP9, funded from the European
                      Union Horizon 2020 programme under grant agreement no.
                      101004728. The work also received funding from the European
                      Union–NextGenerationEU, PNRR MUR Project PE0000023-NQSTI.},
      abstract     = {In recent years, quantum technology has undergone
                      transformative advancements, opening up unprecedented
                      possibilities in computation, metrology, sensing, and
                      communication and reshaping the landscape of scientific
                      research. Based on superposition, interference, and
                      entanglement of quantum states, quantum systems leverage the
                      core principles of quantum mechanics to achieve performances
                      that were once deemed impossible or computationally
                      insurmountable by classical methods. However, the practical
                      realization of devices hinges on the conservation of these
                      quantum states and their precise manipulation, requiring
                      materials engineering with atomic precision on many length
                      scales —a formidable challenge. Synchrotron light and
                      free-electron laser (FEL) facilities, widely employed across
                      diverse scientific and engineering disciplines, provide
                      important single techniques and suites of multimodal
                      non-destructive imaging and diagnostic tools to reveal
                      electronic, structural, and morphological properties of
                      matter on device level. This article delves into how these
                      tools can help to unlock the potential of quantum device
                      technologies, overcoming production barriers and paving the
                      way for future breakthroughs. Moreover, the article presents
                      quantum optics in the x-ray regime using synchrotron and FEL
                      light sources and addresses the potential of quantum
                      computing for synchrotron-radiation experiments.},
      cin          = {FS-SXQM / DIB},
      ddc          = {530},
      cid          = {I:(DE-H253)FS-SXQM-20190201 / I:(DE-H253)DIB-20120731},
      pnm          = {632 - Materials – Quantum, Complex and Functional
                      Materials (POF4-632)},
      pid          = {G:(DE-HGF)POF4-632},
      experiment   = {EXP:(DE-MLZ)NOSPEC-20140101},
      typ          = {PUB:(DE-HGF)16},
      doi          = {10.1002/adfm.202501043},
      url          = {https://bib-pubdb1.desy.de/record/643494},
}