PPT-Colloidal Graphene Quantum Dots for Energy

Applications Liang shi Li Indiana University DMR 1105185 We have studied the charge transfer involving the colloidal graphene quantum dots GQDs for solar cell applications and have investigated the effects of heteroatomdoping of the GQDs on their properties for other potential energy applications. Terzis Department of Physics University of Patras GR26504 Greece Received 21 July 2005 accepted 15 November 2005 published online 11 January 2006 The sizedependent band gap of semiconductor quantum dots is a wellknown and widely studied quantum con6 Spiros . Evangelou. . i. s it the same as for any other 2D lattice?. 1. . DISORDER: . diffusive to localized. quantum interference of electron waves in a random medium. . . TOPOLOGY:. . integrable. Arindam. . Ghosh. Organization of large number of nanostructures – scalability. Utilize natural forces. Organic, inorganic and biological systems. Physics research . on quantum dots. What are the active areas. Joel Q. Grim. , Sotirios Christodoulou, . Francesco Di . Stasio, Roman Krahne, . Roberto . Cingolani, . Liberato . Manna, . Iwan Moreels . Istituto. . Italiano. di . Tecnologia. ,. Genova, . Italy. and . Ultra-Efficient Solar Cells . 2008. “for the Layman”. Disclaimer. The information contained in this document is provided by Phoenix Alliance Corp. through its research sources and is obtained from sources that Phoenix Alliance Corp. believes to be reliable or are otherwise expressions of third party opinion. Whilst Phoenix Alliance Corp. has made reasonable efforts to ensure the accuracy, completeness and appropriateness of such information, any reliance on such information is entirely at the risk of the party using it, and it will not rely on such contents in substitution for making proper and appropriate enquiries from the relevant third parties. . Graphene. Arindam. . Ghosh. Department of Physics. Indian Institute of Science. Atin. Pal . et al. ACS . Nano. . 5,. 2075 (2011). Atin. Pal and . Arindam. . Ghosh. . PRL. . 102,. 126805 (2009). Founded Jan. 2007, Public . Company . OTCQB:QTMM. Located in . San . Marcos, . Texas (Austin Metroplex. ).. Quantum Dots Manufacturer with Industry-leading . production technology and a strong IP portfolio. Daniel Craft, Dr. John Colton, Tyler Park, Phil White, . Brigham Young University. Quantum Computing. Quantum states are the “1”s and “0”s of a classical computer. Certain tasks—like factoring large numbers—are exponentially faster. Bruno . Ullrich. Instituto de Ciencias Físicas, Universidad Nacional Autónoma de México, Cuernavaca, Morelos C.P. . 62210, . Mexico. Acknowledgements. Joanna Wang (WPAFB). Akhilesh. Singh (UNAM). Graphene/Graphene Oxide . Quantum Materials. Angela R. Hight Walker. National Institute of Standards and Technology. 3.2.1. graphene. graphene layer. single-layer graphene. monolayer graphene. single layer of carbon atoms with each atom bound to three neighbours in a honeycomb structure. Quantum well or quantum wire confinements give the electron at least one degree of freedom Although this kind of confinement leads to quantization of the electron spectrum which changes the density of Quantum Confinement. QD Synthesis. Colloidal Methods . Epitaxial Growth. Applications. Biological. Light Emitters. Additional Applications. Introduction. Definition: . Quantum dots (QD) are nanoparticles/structures that exhibit 3 dimensional quantum confinement, which leads to many unique optical and transport properties.. Jean Michel D. . Sellier. Yuling. . Hsueh. , . Hesameddin. . Ilatikhameneh. ,. Tillmann. Kubis, Michael . Povolotskyi. , Jim Fonseca, Gerhard Klimeck. Network for Computational Nanotechnology (NCN). Hugh . Higinbotham. 1. Photovoltaics. (PVs). Convert . light to . electric current. GHG neutral energy source. Currently . cheaper than coal/natural gas on the utility scale, but not efficient enough to be do well in current energy market.