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   <ow:Publication rdf:about="oai:digibug.ugr.es:10481/63422">
      <dc:title>Non-covalent Functionalization of Graphene to Tune Its Band Gap and Stabilize Metal Nanoparticles on Its Surface</dc:title>
      <dc:creator>Arranz-Mascarós, Paloma</dc:creator>
      <dc:creator>López Garzón, Francisco Javier</dc:creator>
      <dc:description>Support from the Spanish Government (project no. RTI2018101558-B-C21), Autonomous Regional Government (Junta de Andalucia ', group nos. PAIDI FQM273 and RMN342), and University of Jaen (no. EI_FQM6-2019) is gratefully acknowledged. Technical and human support provided by SCAI of the University of Jaen (UJA, MINECO, Junta de Andalucia ', and FEDER) is also acknowledged.</dc:description>
      <dc:description>Controlling graphene conductivity is crucial for its potential applications. With this focus, this paper shows the effect&#xd;
of the non-covalent bonding of a pyrimidine derivative (HIS) on the electronic properties of graphene (G). Several G-HIS hybrids&#xd;
are prepared through mild treatments keeping unaltered the structures of both G and HIS. The attachment of HIS to G occurs by&#xd;
π−π stacking of the HIS-aromatic residue with the G surface. This partially blocks the pz electrons of G, giving rise to the splitting of&#xd;
both the valence and conduction bands. Moreover, the width of the splitting is directly related to the HIS content. This fact allows&#xd;
the fine-tuning of the band gap of G-HIS hybrids. Furthermore, HIS keeps its metal-complexing ability in the G-HIS hybrids. Taking&#xd;
advantage of this, a G-HIS−Cu(0) composite was prepared by H2 plasma reduction of a precursor of the G-HIS−Cu(II) type. GHIS−&#xd;
Cu(0) contains Cu(0) clusters stabilized on the G surface due to interactions with the COO− functions of HIS. In an&#xd;
analogous hybrid, G-HIS−Au(0), the Au(0) NPs are also stabilized by COO− functions. This material, consisting of the coupling of&#xd;
Au(0) NPs and G-HIS, photocatalyzed water reduction under visible light radiation producing 12.5 μmol·g−1·h−1of hydrogen.</dc:description>
      <dc:date>2020-09-16T11:06:58Z</dc:date>
      <dc:date>2020-09-16T11:06:58Z</dc:date>
      <dc:date>2020-07-22</dc:date>
      <dc:type>info:eu-repo/semantics/article</dc:type>
      <dc:identifier>ACS Omega 2020, 5, 18849−18861 [https://dx.doi.org/10.1021/acsomega.0c02006]</dc:identifier>
      <dc:identifier>http://hdl.handle.net/10481/63422</dc:identifier>
      <dc:identifier>10.1021/acsomega.0c02006</dc:identifier>
      <dc:language>eng</dc:language>
      <dc:rights>http://creativecommons.org/licenses/by-nc-nd/3.0/es/</dc:rights>
      <dc:rights>info:eu-repo/semantics/openAccess</dc:rights>
      <dc:rights>Atribución-NoComercial-SinDerivadas 3.0 España</dc:rights>
      <dc:publisher>American Chemical Society</dc:publisher>
   </ow:Publication>
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