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Molecular Electronic Devices: Metal/Molecule/Metal Publications [1] H. A. McNally, D. B. Janes, T. Rakshit, S. Datta, B. Kasibhatla and C. P. Kubiak, “Electrostatic Investigation into the Bonding of Aromatic Molecules to Gold,” Superlattices and Microstructures, Vol. 31, p. 239-245, May 2002. [2] S. Howell, D. Kuila, B. Kasibhatla, C. P. Kubiak, D. B. Janes, and R. Reifenberger, “Molecular Electrostatics of Conjugated Self-Assembled Monolayers on Au(111) using Electrostatic Force Microscopy,” Langmuir, Vol. 18, pp. 5120-5125, 2002. [3] J. Choi, K. Lee and D. B. Janes, “Nanometer Scale Gap made by Conventional Micro-scale Fabrication,” Nanoletters, Vol. 4, p. 1699-1703, 2004. [4] S. Howell and D. B. Janes, “Time Evolution Studies of the Electrostatic Surface Potential of LTG:GaAs Using Electrostatic Force Microscopy,” to appear in Journal of Applied Physics, 2005. [5] S. Ghosh, H. Halimun, A. Mahapatro, J. Choi, S. Lodha and D. B. Janes, “Device Structure for Electronic Transport Through Individual Molecules Using Nanoelectrodes,” Applied Physics Letters, Vol. 87, p. 233509-233511, 2005. [6] A. Mahapatro, S. Ghosh and D. B. Janes, “Nanometer Scale Electrode Separation (Nano-gap) Using Electromigration at Room Temperature,” IEEE Transactions on Nanotechnology, Vol. 5, No. 3, p. 232-236, May 2006. [7] A. Mahapatro, A. Manning, A. Scott and D. B. Janes, “Gold Surface with sub-nm Roughness Realized by Evaporation on a Molecular Adhesion Layer,” Applied Physics Letters, Vol. 88, p. 151917-9, 2006. [8] A. Mahapatro, K.-J. Jeong, G. Lee, and D. B. Janes, “Electrical Conduction through Polyion-Stabilized Double-Stranded DNA in Nanoscale Break Junctions,” to appear in Nanotechnology, 2007. |