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@ARTICLE{Glier:422541,
      author       = {Glier, Tomke Eva and Akinsinde, Lewis and Paufler, Malwin
                      and Otto, Ferdinand and Hashemi, Maryam and Grote, Lukas and
                      Daams, Lukas and Neuber, Gerd and Grimm-Lebsanft, Benjamin
                      and Biebl, Florian and Rukser, Dieter and Lippmann, Milena
                      and Ohm, Wiebke and Schwartzkopf, Matthias and Brett, Calvin
                      J. and Matsuyama, Toru and Roth, Stephan V. and Rübhausen,
                      Michael},
      title        = {{F}unctional {P}rinting of {C}onductive {S}ilver-{N}anowire
                      {P}hotopolymer {C}omposites},
      journal      = {Scientific reports},
      volume       = {9},
      number       = {1},
      issn         = {2045-2322},
      address      = {London [u.a.]},
      publisher    = {Springer Nature},
      reportid     = {PUBDB-2019-02227},
      pages        = {6465 (1-7)},
      year         = {2019},
      abstract     = {We investigated the fabrication and functional behaviour of
                      conductive silver-nanowire-polymer composites for
                      prospective use in printing applications. Silver-nanowires
                      with an aspect ratio of up to 1000 were synthesized using
                      the polyol route and embedded in a UV-curable and printable
                      polymer matrix. Sheet resistances in the composites down to
                      13 Ω/sq at an optical transmission of about $90\%$ were
                      accomplished. The silver-nanowire composite morphology and
                      network structure was investigated by electron microscopy,
                      atomic force microscopy, profilometry, ellipsometry as well
                      as surface sensitive X-ray scattering. By implementing
                      different printing applications, we demonstrate that our
                      silver nanowires can be used in different polymer
                      composites. On the one hand, we used a tough composite for a
                      2D-printed film as top contact on a solar cell. On the other
                      hand, a flexible composite was applied for a 3D-printed
                      flexible capacitor.},
      cin          = {DOOR ; HAS-User / FS-PE / FS-TI},
      ddc          = {600},
      cid          = {I:(DE-H253)HAS-User-20120731 / I:(DE-H253)FS-PE-20120731 /
                      I:(DE-H253)FS-TI-20120731},
      pnm          = {6214 - Nanoscience and Materials for Information Technology
                      (POF3-621) / 6G3 - PETRA III (POF3-622) / SWEDEN-DESY -
                      SWEDEN-DESY Collaboration $(2020_Join2-SWEDEN-DESY)$},
      pid          = {G:(DE-HGF)POF3-6214 / G:(DE-HGF)POF3-6G3 /
                      $G:(DE-HGF)2020_Join2-SWEDEN-DESY$},
      experiment   = {EXP:(DE-H253)P-P03-20150101},
      typ          = {PUB:(DE-HGF)16},
      pubmed       = {pmid:31015552},
      UT           = {WOS:000465218400016},
      doi          = {10.1038/s41598-019-42841-3},
      url          = {https://bib-pubdb1.desy.de/record/422541},
}