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¹Ì·¡Ã¢Á¶°úÇкΠ±Û·Î¹úÇÁ·ÐƼ¾î (Àç)¸ÖƼ½ºÄÉÀÏ ¿¡³ÊÁö ½Ã½ºÅÛ ¿¬±¸´ÜÀº ³ª³ë±â¼ú°ú ¿¡³ÊÁö ±â¼úÀÇ À¶ÇÕÀ» ÅëÇÏ¿© Çõ½ÅÀû ¹Ì·¡ ±¤¿¡³ÊÁö¿Í ºÐÀÚ¿¡³ÊÁö ¿øõ±â¼ú °³¹ßÀ» ¸ñÇ¥·Î ÇÏ´Â ¸ÖƼ½ºÄÉÀÏ ¿¡³ÊÁö ½Ã½ºÅÛ ¿¬±¸»ç¾÷À» ÃßÁøÇÏ°í ÀÖ½À´Ï´Ù. ¿¬±¸´Ü¿¡¼ ±¹Á¦ Àú¸íÀλç ÃÊû ¸ÖƼ½ºÄÉÀÏ ¿¡³ÊÁö °Á¸¦ °³ÃÖÇÕ´Ï´Ù. °ü½É ÀÖ´Â ºÐµéÀÇ ¸¹Àº Âü¼® ¹Ù¶ø´Ï´Ù.
1. Á¦ ¸ñ : Emerging materials for solar energy: halide perovskites and beyond
2. ¿¬ »ç : Aron Walsh(Department of Materials, Imperial College London, UK)
3. ÀÏ ½Ã : 2017³â 4¿ù 18ÀÏ (È), 16:00~17:00
4. Àå ¼Ò : ¼¿ï´ëÇб³ 301µ¿ 1419È£
5. ³» ¿ë : There are a large variety of materials being developed for application in solar energy conversion. The majority are based upon naturally occurring minerals (so-called solar mineralogy). The general procedure has been to take a multi-component system and tune the chemical composition to optimise optical absorption for the terrestrial solar spectrum. Other factors also determine whether a material can be practically employed in a photovoltaic or photoelectrochemical system, for example, the absolute band energies (work functions), defect physics, and chemical stability. I will present our recent progress into the design and optimisation of new solar energy materials with an emphasis on computing photovoltaic performance descriptors from materials simulations [1-5], including advances in structure-property relationships in the kesterite (e.g. Cu2ZnSnS4) and perovskite (e.g. CsSnI3 and CH3NH3PbI3) families, in addition to the matlockite (PbFCl type) and herzenbergite (SnS type) systems. New directions in the field, such as the development of photoferroic materials, will also be addressed.
[1] ¡°The steady rise of kesterite solar cells¡±, ACS Energy Lett. 2, 776 (2017)
[2] ¡°Indirect to direct bandgap transition in methylammonium lead halide perovskite¡±,
Energy Environ. Sci. 10, 509 (2017)
[3] ¡°Metastable cubic tin sulfide: A novel phonon-stable chiral semiconductor¡±,
APL Mater. 5, 6101 (2017)
[4] ¡°Relativistic origin of slow electron-hole recombination in hybrid halide perovskite solar cells¡±,
APL Mater. 4, 91501 (2016)
[5] ¡°Ferroelectric materials for solar energy conversion: photoferroics revisited¡±
Energy & Environmental Science 8, 838 (2015)
6. ¾à ·Â :
Aron Walsh is Professor of Materials Design in the Department of Materials at Imperial College London. He was awarded his Ph.D in chemistry from Trinity College Dublin, completed a postdoctoral position at the National Renewable Energy Laboratory (USA), and held a Marie Curie fellowship at University College London. He began his independent research career at the University of Bath and held a Royal Society University Research Fellowship in the Department of Chemistry. His research combines technique development and applications at the interface between solid-state chemistry and physics. He has published over 200 papers with an h-index of 62. In 2015 he was awarded the EU-40 prize from the Materials Research Society for his work on the theory of solar energy materials.
¹® ÀÇ : ¸ÖƼ½ºÄÉÀÏ ¿¡³ÊÁö ½Ã½ºÅÛ ¿¬±¸´Ü ¿¬±¸Áö¿øº»ºÎ (¢Î 889-6669,6670)
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