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   1. < dc:title > 2D Van der Waals Heterostructures for Chemical Sensing </ dc:title >

   2. < dc:creator > Hou, Huilei </ dc:creator >

   3. < dc:creator > Anichini, Cosimo </ dc:creator >

   4. < dc:creator > Samorì, Paolo </ dc:creator >

   5. < dc:creator > Criado, Alejandro </ dc:creator >

   6. < dc:creator > Prato, Maurizio </ dc:creator >

   7. < dc:subject > 2D materials </ dc:subject >

   8. < dc:subject > Sensors </ dc:subject >

   9. < dc:subject > Van der Waals heterostructures </ dc:subject >

   10. < dc:description > [Abstract] During the last 15 years, 2D materials have revolutionized the field of materials science. Moreover, because of their highest surface-to-volume ratio and properties extremely susceptible to their interaction with the local environment they became powerful active components for the development the high-performance chemical sensors. By combining different 2D materials to form van der Waals heterostructures (VDWHs) it is possible to overcome the drawback of individual materials (such as inertness and zero-bandgap of pristine graphene and less environmental stability of transition metal dichalcogenides). Meanwhile, VDWHs possess unprecedented and fascinating properties arising from the intimate interaction between the components, which can yield superior sensitivities, higher selectivity, and stability when employed to detect gases, biomolecules, and other organic/inorganic molecules. Herein, the latest developments and advances in the field of chemical sensors based on VDWH of 2D materials, with specific insight into the sensing mechanisms, are reviewed and future directions, challenges, and opportunities for the development of the next generation of (bio)chemical sensors with potential impact in environmental sciences and biomedical applications, and more specifically in (bio)chemical defense, industrial safety, food, and environmental surveillance, and medical (early) diagnostics, are discussed. </ dc:description >

   11. < dc:description > The authors gratefully acknowledge the financial support from the University of Trieste, INSTM, the Italian Ministry of Education MIUR (Cofin Prot. 2017PBXPN4) and the Maria de Maeztu Units of Excellence Program from the Spanish State Research Agency (Grant No. MDM-2017-0720). The authors acknowledge financial support from the EC through the Graphene Flagship Core 3 project (GA-881603) and the ERC project SUPRA2DMAT (GA-833707), the Interdisciplinary Thematic Institute SysChem via the IdEx Unistra (ANR-10-IDEX-0002) within the program Investissement d’Avenir program, the International Center for Frontier Research in Chemistry and the Institut Universitaire de France (IUF). M.P. is AXA Chair of Bionanotechnology. A.C. thanks MINECO and Xunta de Galicia for his research grants (Ramon y Cajal No. RYC2020-030183-I, and Atracción de Talento No. ED431H 2020/17, respectively). H.-L.H. thanks MINECO for his research grant (Juan de la Cierva Incorporacion/No. IJC-2018-037396-I). Open access funding provided by Universita degli Studi di Trieste within the CRUI-CARE Agreement. </ dc:description >

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   10. < description > [Abstract] During the last 15 years, 2D materials have revolutionized the field of materials science. Moreover, because of their highest surface-to-volume ratio and properties extremely susceptible to their interaction with the local environment they became powerful active components for the development the high-performance chemical sensors. By combining different 2D materials to form van der Waals heterostructures (VDWHs) it is possible to overcome the drawback of individual materials (such as inertness and zero-bandgap of pristine graphene and less environmental stability of transition metal dichalcogenides). Meanwhile, VDWHs possess unprecedented and fascinating properties arising from the intimate interaction between the components, which can yield superior sensitivities, higher selectivity, and stability when employed to detect gases, biomolecules, and other organic/inorganic molecules. Herein, the latest developments and advances in the field of chemical sensors based on VDWH of 2D materials, with specific insight into the sensing mechanisms, are reviewed and future directions, challenges, and opportunities for the development of the next generation of (bio)chemical sensors with potential impact in environmental sciences and biomedical applications, and more specifically in (bio)chemical defense, industrial safety, food, and environmental surveillance, and medical (early) diagnostics, are discussed. </ description >

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