{"id":16,"date":"2021-09-10T13:33:52","date_gmt":"2021-09-10T13:33:52","guid":{"rendered":"http:\/\/nurit.local\/?page_id=16"},"modified":"2021-09-11T11:43:54","modified_gmt":"2021-09-11T11:43:54","slug":"publications","status":"publish","type":"page","link":"http:\/\/nurit.local\/publications\/","title":{"rendered":"Publications"},"content":{"rendered":"\t\t
S. M. M. Reddy, E. Ra\u00dflenberg, S. Sloan-Dennison, T. Hesketh, O. Silberbush, T. Tuttle, E. Smith, D. Graham,\u00a0 K. Faulds,\u00a0 R. V. Ulijn, N. Ashkenasy<\/b>, A. Lampel\u00a0<\/sup>” Proton-Conductive Melanin-Like Fibers through Enzymatic Oxidation of a Self-Assembling Peptide<\/a>“,\u00a0Adv. Mat,\u00a0<\/i>32<\/b>, 2003511 (2020).<\/p><\/li> \u00a8\u00a0H. Manis-Levy; R. Eitan Abutbul; A. Grosman, H. Peled, Y. GolanC<\/sup>,\u00a0N. Ashkenasy<\/b>, A. Sa’ar, R. Shikler and G. Sarusi;\u00a0“The role of CdS doping in improving SWIR photovoltaic and photoconductive responses in solution grown CdS\/PbS heterojunctions<\/a>\u201d.\u00a0Nanotechnology<\/i>\u00a025<\/b>, 255502 (2020).<\/p><\/li> O. Silberbush, M. Engel, I. Sivron, S. Roy, N. Ashkenasy<\/b>, “Self-Assembled Peptide Nanotube Films with High Proton Conductivity<\/a>”\u00a0J. Phys. Chem. B<\/i>\u00a0123<\/b>, 9882-9888 (2019).<\/p><\/li> N. Kramer, S. Sarkar, L. Kronik and N. Ashkenasy<\/b>, “Systematic modification of the indium tin oxide work function via side-chain modulation of an amino-acid functionalization layer<\/a>”\u00a0Phys. Chem. Chem. Phys.<\/i>\u00a021<\/b>, 21875-21881 (2019).<\/p><\/li> R. Contreras-Montoya, G. Escolano, S. Roy,\u00a0<\/sup>M. T. Lopez-Lopez, J. M. Delgado-L\u00f3pez,\u00a0<\/sup>J. M. Cuerva, J. J. D\u00edaz-Moch\u00f3n,\u00a0<\/sup> \u00a0\u00a0\u00a0\u00a0\u00a0 N. Ashkenasy<\/b>, J. A. Gavira,\u00a0<\/sup>\u00a0L. \u00c1. de CienfuegosI<\/sup>,\u00a0“<\/i>\u201cCatalytic and Electron Conducting Carbon Nanotube\u2013Reinforced Lysozyme Crystals<\/a>”\u00a0Adv. Funct. Mat.\u00a0<\/i>29,\u00a0<\/b>1807351\u00a0<\/i>(2019).<\/p><\/li> M. Amit, S. Yuran, E. GaziI<\/sup>, M. Reches and\u00a0N.Ashkenasy<\/b>, ”\u00a0Tailor Made Functional Peptide Self-Assembling Nanostructures<\/a>”\u00a0Adv. Mat<\/i>.\u00a030,<\/i><\/b>\u00a01707083\u00a0<\/i>2018<\/i><\/b>.<\/i><\/p><\/li> <\/i>Y. Furmansky, S. Sergani, N. Ashkenasy<\/b>, I. Visoly-Fisher, “Photoconductance of ITO\/Conductive Polymer Junctions in the UV and Visible Ranges<\/a>”\u00a0J. Phys. Chem. C\u00a0<\/i>2018<\/i><\/b>,\u00a0<\/i>122<\/i><\/b>, 7288\u20137295.<\/i><\/p><\/li> <\/i>M. Amit, S. Roy, Y. Deng, E. Josberger, M. Rolandi and N. Ashkenasy<\/b>,\u00a0“Measuring Proton Currents of Bioinspired Materials with Metallic Contacts<\/a>”\u00a0ACS Applied Materials<\/i> & Interfaces<\/i>\u00a010<\/b>, 1933-1938 (2018).<\/p><\/li> O. Silberbush, M. Amit, S. Roy and N. Ashkenasy <\/b>“Significant enhancement of proton transport in bioinspired peptide fibrils by single acidic or basic amino acid mutation<\/a>” Adv. Func. Mat<\/i>. *Highlighted On Wiley-VCH news website<\/a> .<\/p><\/li> Maayan Matmor, George A. Lengyel, W. Seth Horne and Nurit Ashkenasy<\/b>, “Peptide-functionalized semiconductor surfaces: strong surface electronic effects from minor” alterations to backbone composition<\/a>“, Phys. Chem. Chem. Phys<\/i>,\u00a019<\/b>, 5709-5714\u00a0\u00a0(2017).<\/p><\/li> D. Ivnitski, M. Amit, O. Silberbush, Y. Atsmon-Raz, J. Nanda, R. Cohen-Luria, Y. Miller, G. Ashkenasy, and N. Ashkenasy<\/b>, “Structure Polymorphism Strongly Influences the Conductivity of Peptide Fibrils<\/a>”\u00a0Angewandte Chemie<\/i>,\u00a055<\/b>, 9988 (2016).<\/p><\/li> J. Lerner-Yardeni, M. Amit, G. Ashkenasy, and N. Ashkenasy,<\/b>\u00a0“<\/sup><\/b>Sequence Dependent Proton <\/a>Conduction in Self-Assembled Peptide Nanostructures<\/a>”\u00a0Nanoscale<\/i>, 8<\/b>, 235-2366 (2016).<\/p><\/li> P. Gordiichuk, D. Rimmerman, A. Paul, D. A. Gautier, A. Gruszka, M. Saller, J. W. de Vries, G.-J. Wetzelaer, M. Manca, W. Gomulya, M. Matmor, E. Gloukhikh, Mark Loznik, N. Ashkenasy, P. W. M. Blom, M. R\u00f6gner, M. A. Loi, S. Richter, and A. Herrmann, “Filling the green gap of a megadalton Photosystem I complex by conjugation of organic dyes<\/a>”\u00a0Bioconjugate Chem.,<\/i>\u00a027<\/b>, 33-41 (2016).<\/p><\/li> Y. Liebes-Peer, V. Bandalo, \u00dc. S\u00f6kmen, M. Tornow, and N.Ashkenasy<\/b>, “Fabrication of nanopores in multi-layered silicon – based membranes using focused electron beam induced etching with XeF2<\/sub>\u00a0gas<\/a>”\u00a0Microchim. Acta\u00a0<\/i>183<\/b>, 987-994 (2016).<\/p><\/li> D. A. Cannon, N. Ashkenasy, and T. Tuttle, “Influence of solvent in Controlling Peptide\u2212Surface Interactions<\/a>”\u00a0J. Phys. Chem. Lett.<\/i>\u00a06<\/b>, 3944-3949 (2015).<\/p><\/li> D. Ivnitski, M. Amit, B. Rubinov, R. Cohen-Luria, N. Ashkenasy<\/b>, and G. Ashkenasy “Introducing charge transfer functionality into prebiotically relevant \u03b2-sheet peptide fibrils<\/a>”\u00a0Chem. Commun.<\/i>\u00a050<\/b>, 6733-6736 (2014).<\/p><\/li> Y. Liebes-Peer, H. Rapaport, and N. Ashkenasy<\/b>, “Amplification of Single Molecule Translocation Signal Using \u03b2-Strand Peptide Functionalized Nanopores<\/a>“,\u00a0ACS Nano<\/i>\u00a08<\/b>, 6822-6832 (2014).<\/p><\/li> M. Amit, S. Appel, R. Cohen, G. Cheng, I. W. Hamley, and N. Ashkenasy<\/b>, “Hybrid Proton and Electron Transport in Peptide Fibrils<\/a>“,\u00a0Adv. Func. Mat.\u00a0<\/i>24<\/b>, 5873-5880 (2014).<\/p><\/li> M. Amit and N. Ashkenasy\u00a0<\/b>“Electronic properties of amyloid\u00a0b-based peptide filaments with different non-natural heterocyclic side chains<\/a>”\u00a0Isr. J. Chem<\/i>.\u00a054<\/b>, 703-707 (2014).<\/p><\/li> A. Atanassov, Z. Hendler, I. Berkovich, G. Ashkenasy, and N. Ashkenasy<\/b>, “Force modulated conductance of artificial coiled-coil protein monolayers<\/a>“, Biopolymers<\/i>, 100<\/b>, 93 (2013).<\/p><\/li> M. Matmor and N. Ashkenasy<\/b>, \u201cModulating semiconductor surface electronic properties by inorganic peptide-binder sequence design<\/a>\u201d, J. Amer. Chem. Soc., <\/i>134<\/b>, 20403 (2012).<\/p><\/li> Y. Furmansky, H. Sasson, P. A. Liddell, D. Gust, N. Ashkenasy<\/b>, and I. Visoly-Fisher, \u201cPorphyrins as ITO photosensitizers: \u200e Substituents control photo-induced electron transfer direction<\/a>\u201d, J. Mater. Chem.<\/i>, 22<\/b>, 20334 (2012).<\/p><\/li> B. Rubinov, N. Wagner, M. Matmor, O. Regev, N. Ashkenasy<\/b>, and G. Ashkenasy, “Transient fibril structures facilitating non-enzymatic self-replication<\/a>“, ACS Nano, <\/i>6<\/b>, 7893 (2012). *Research highlight: Nature Nanotech.<\/i>, 7<\/b>, 549 (2012).<\/p><\/li> M. Amit, G. Cheng , I. W. Hamley, and N. Ashkenasy<\/b>, “Conductance of amyloid \u03b2 based peptide filaments: structure\u2013function relations<\/a>“, Soft Matter<\/i>, 8<\/b>, 8690 (2012).<\/p><\/li> M. Mizrahi, A. Zakrassov, J. Lerner-Yardeni, and N. Ashkenasy<\/b>, “Charge transport in vertically aligned, self-assembled peptide nanotube junctions<\/a>“, Nanoscale<\/i>, 4<\/b>, 518 (2012).<\/p><\/li> A. Kovalev, D. Wainstein, A. Rashkovskiy, A. Osherov, Y. Golan, and N. Ashkenasy<\/b>, “Complex investigation of electronic structure transformations in Lead Sulphide nanoparticles using a set of electron spectroscopy techniques<\/a>“, Vacuum, 86<\/b>, 638 (2012).<\/p><\/li> V. Bourbo, M. Matmor, E. Shtelman, B. Rubinov, N. Ashkenasy<\/b>, and G. Ashkenasy “Self-assembly and self-replication of short amphiphilic \u03b2-sheet peptides<\/a>“, Orig. Life Evol. Biosph., 41<\/b>, 563 (2011).<\/p><\/li> A. Osherov, M. Matmor, N. Froumin, N. Ashkenasy<\/b>, and Y. Golan, \u201cSurface termination control in chemically deposited PbS films: aspects of nucleation and growth on gallium terminated GaAs(111)A and arsenic terminated GaAs(111)B<\/a>\u201d, J. Phys Chem. C<\/i>, 115<\/b>, 16501 (2011).<\/p><\/li> O. Vaknin, B. Khamaisi, and N. Ashkenasy<\/b>, \u201cControlling field-effect transistor biosensor electrical characteristics using immunosorbent assay<\/a>\u201d, Electroanalysis,<\/i>