Publications
Journal Publications
[28]. “Tunable Plasmons in Ultrathin Metal Films”, R. A. Maniyara, D. Rodrigo, R. Yu, J. C. Ferrer, D. S. Ghosh, R. Yongsunthon, D. E Baker, A. Rezikyan, F. J. G. Abajo, V. Pruneri, Nature Photonics, DOI: 10.1038/s41566-019-0366-x (2019)
[27]. “Influence of the average molar mass of poly(N-vinylpyrrolidone) on the dimensions and conductivity of silver nanowires”, L. Sonntag, F. Eichler, N. Weiß, L. Bormann, D. S. Ghosh, J. M. Sonntag, R. Jordan, N. Gaponik, K. Leo, A. Eychmueller , Physical Chemistry Chemical Physics, DOI: 10.1039/C9CP00680J (2019)
[26]. “Controlling Tamm-plasmons for organic narrowband NIR photodetectors”, A. Mischok, B. Siegmund, D. S. Ghosh, J. Benduhn, D. Spoltore, M. Bohm, H. Frob, C. Korner, K. Leo, K. Vandewal, ACS Photonics 4(9), 2228 (2017)
[25]. “Microcavity Enhanced Semitransparent Electrodes for Oligothiophene Small Molecule Organic Solar Cells”, D. S. Ghosh*, K. Leo, Advanced Electronic Materials 1600518 (2017) (Cover Page)
[24]. “Tunable complete optical absorption in multilayer structures including Ge2Sb2Te5 without lithographic patterns”, V. K. Mkhitaryan, D. S. Ghosh, M. Rude, J. C. Ferrer, R. A. Maniyara, K. K. Gopalan, V. Pruneri, Advanced Optical Materials 5, 1600452 (2017)
[23]. “An Antireflection Transparent Conductor with Ultralow Optical Loss (less than 2 %) and Electrical Resistance (less than 6 Ohm per square)”, R. A. Maniyara, V. K. Mkhitaryan, T. L. Chen, D. S. Ghosh, V. Pruneri, Nature Communications 7, 13771 (2016) (Highlighted in Phys.Org)
[22]. “Structural colouring of glass using dewetted nanoparticles and ultrathin films of metals”, R. Yu, P. Mazumder, N. F. Borrelli, A. Carrilero, D. S. Ghosh, R. A. Maniyara, D. Baker, F. J. G. Abajo, V. Pruneri, ACS Photonics 3(7), 1194 (2016) (Cover Page)
[21]. “Highly flexible transparent electrodes containing ultrathin silver for efficient polymer solar cells”, D. S. Ghosh*, Q. Liu, P. Mantilla, Tong Lai Chen, V. Mkhitaryan, M. Huang, S. Garner, J. Martorell, V. Pruneri, Advanced Functional Materials 25 (47), 7309 (2015)
[20]. “Nanopatterned graphene on polymer substrate by direct peel-off substrate”, T. L. Chen, D. S. Ghosh*, M. Marchena, J. Osmond, V. Pruneri, ACS Applied Materials and Interfaces 7, 5938 (2015)
[19]. “An ITO-free polymer solar cell on flexible glass”, N. Formica, P. Mantilla, D. S. Ghosh*, D. Janner, T. L. Chen, S. Garner, J. Martorell, V. Pruneri, ACS Applied Materials and Interfaces 7, 4541 (2015)
[18]. “An ultrathin transparent conductive polyimide foil embedding silver nanowires”, D. S. Ghosh*, T. L. Chen, V. Mkhitaryan, V. Pruneri, ACS Applied Materials and Interfaces 6(23), 20943 (2014)
[17]. “Solution processed metallic nanowire based transparent electrode capped with a multifunctional layer”, D. S. Ghosh*, T. L. Chen, V. Mkhitaryan, N. Formica, V. Pruneri, Applied Physics Letters 102, 221111 (2013)
[16]. “Indium-free transparent electrodes based on silver nanowire mesh integrated with hot pressed transferred graphene”, T. L. Chen, D. S. Ghosh†, V. Mkhitaryan, V. Pruneri, ACS Applied Materials and Interfaces 5(22), 11756 (2013)
[15]. “Ultrathin oxidized Ti to increase stability and smoothness of Al doped ZnO transparent conductors for high efficiency indium-free polymer solar cells ”, N. Formica, D. S. Ghosh*, A. Martinez, J. Martorell, V. Pruneri, Applied Physics Letters 103, 183304 (2013)
[14]. “Ultra-stable and atomically smooth ultra-thin silver films grown on a copper seed layer”, N. Formica*, D. S. Ghosh*, A. Carrilero, T. L. Chen, R. E. Simpson, V. Pruneri (*Equal contribution) ACS Applied Materials and Interfaces 5(8), 3048 (2013)
[13]. “Cu-Ag alloy and Ni capped transparent electrodes for indium-free organic photovoltaic and lighting device”, D. S. Ghosh*, N. Formica, T. L. Chen, J. Hwang, C. Eickhoff, V. Pruneri, Solar Energy Materials and Solar cells 116, 89 (2013)
[12]. “Graphene as an anti-permeation and protective layer for indium-free transparent electrodes”, T. L. Chen, D. S. Ghosh*, N. Formica, V. Pruneri, Nanotechnology 23, 395603 (2012)
[11]. “High figure-of-merit Ag/Al:ZnO nano-thick transparent electrodes for indium-free flexible photovoltaics”, D. S. Ghosh*, T. L. Chen, N. Formica, J. Hwang, I Bruder, V. Pruneri, Solar Energy Materials and Solar cells 107, 338 (2012)
[10]. “Highly stable Ag-Ni based transparent electrodes on PET substrates for flexible organic solar cells”, N. Formica, D. S. Ghosh*, T. L. Chen, C. Eickhoff, I. Bruder, V. Pruneri, Solar Energy Materials and Solar cells 107, 63 (2012)
[9]. “Efficient polymer solar cell employing an oxidized Ni capped Al:ZnO anode without the need of additional hole-transporting-layer”, T. L. Chen, R. Betancur, D. S. Ghosh*, J. Martorell, V. Pruneri, Applied Physics Letters 100, 13310 (2012)
[8]. “Highly stable Al-doped ZnO transparent conductors using an oxidized nickel capping layer at its percolation thickness”, T. L. Chen, D. S. Ghosh*, D. Krautz, S. Cheylan, V. Pruneri, Applied Physics Letters 99, 93302 (2011)
[7]. “Organic light emitting diode with indium free metallic bilayer as transparent anode”, S. Cheylan, D. S. Ghosh, D. Krautz, T. L. Chen, V. Pruneri, Organic Electronics 12, 818 (2011)
[6]. “Semi-transparent metal electrode of Cu-Ni as a replacement of ITO in organic photovoltaic cells”, D. S. Ghosh*, R. Betancur, T. L. Chen, V. Pruneri, J. Martorell, Solar Energy Materials and Solar Cells 95, 1228 (2011) (Highlighted in Nature Photonics “News and Views”)
[5]. “Ultrathin Cu-Ti bilayer transparent conductors with enhanced figure-of-merit and stability”, D. S. Ghosh*, T. L. Chen, V. Pruneri, Applied Physics Letters 96, 91106 (2010)
[4]. “High figure-of-merit ultrathin metal transparent electrodes incorporating a conductive grid”, D. S. Ghosh*, T. L. Chen, V. Pruneri, Applied Physics Letters 96, 41109 (2010)
[3]. “Nickel as an alternative semitransparent anode to indium tin oxide for polymer LED applications”, D. Krautz, S. Cheylan, D. S. Ghosh, V. Pruneri, Nanotechnology 25, 275204 (2009) (Highlighted in nanotechweb.org)
[2]. “Stable transparent Ni electrodes”, L. Martinez, D. S. Ghosh, S. Giurgola, P. Vergani, V. Pruneri, Optical Materials 31, 1115 (2009)
[1]. “Widely transparent electrodes based on ultrathin metals”, D. S. Ghosh*, L. Martinez, S. Giurgola, P. Vergani, V. Pruneri, Optics Letters 34, 325 (2009)