用于太阳能转换和储存的光敏氧化钛溶胶和凝胶Photosensitive titanium oxide sols and gels for solar energy conversion and storage |
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课程网址: | http://videolectures.net/slonano07_richard_pto/ |
主讲教师: | Mireille Richard |
开课单位: | 南特大学 |
开课时间: | 2008-01-18 |
课程语种: | 英语 |
中文简介: | 由于在环境保护领域的潜在应用,TiO 2的光化学在研究和商业活动方面是快速增长的领域。除了金红石和锐钛矿(例如油漆和化妆品)的白色颜料特性外,二氧化钛还用于多相催化和光催化(水净化,空气净化),光电化学太阳能电池中用于生产氢和电,作为活性物质在电致变色器件的设计中,作为气体传感器,作为腐蚀保护涂层,在陶瓷和诸如变阻器的电子器件中的层,仅举几例。在这些应用中,可以通过对材料形态的特定纳米结构控制来优化氧化钛的性能。在UV照射下,在TiO 2中产生电子空穴对,然后技术装置基于化学反应或诱导电子转移。由于TiO 2,(3.2eV)的大带隙,仅使用10%的太阳光谱。未来工作的主要目标是开发能够利用可见光和UV光的半导体光催化剂膜。纳米科学有可能提供全新类别的材料,这些材料具有超越这些限制的能力,并产生基于可持续能源的可行经济所需的性能突破。最近在该领域的研究使我们能够通过控制钛物质在非水溶剂中的缩合来合成新型光敏氧化钛溶胶和凝胶。取决于不同的参数,例如Ti ^^ 4 ^^中的浓度,老化或热处理,为了强调少数,无机骨架的结构化导致各种层状结构。吸附的有机物质控制溶胶或凝胶中存在的纳米物体的生长。由于增强的表面积与体积比,这些纳米结构的溶胶和凝胶产生奇异的光电化学性质,这与其大块对应物完全不同。当照射时,这些材料可以吸收能量低于原始半导体的带隙能量的光子,因此预期常规太阳能电池的限制效率显着增加。这些新材料的主要特征是部分占据的中间带,与价带和导带隔离。我们的目的是在第三代光电化学太阳能电池和光电池(超级电容器)中使用这些中间带材料作为敏化剂。 |
课程简介: | Due to the potential applications in the field of environmental protection, the photochemistry of TiO,,2,, is a fast growing area both in terms of research and commercial activity. Beside to the white pigment properties of rutile and anatase (e.g. paints and cosmetic products), titanium dioxide is used in heterogeneous catalysis and photocatalysis (water purification, air cleaning), in photoelectrochemical solar cells for the production of hydrogen and electricity, as an active layer in the design of electrochromic devices, as a gas sensor, as a corrosion-protective coating, in ceramics and in electric devices such as varistors, to name few. In such applications, the performance of titanium oxide could be optimized with specific nanostructural control over the morphology of the material. Under UV irradiation, an electron-hole pair is generated in TiO,,2,, then technological devices are based on chemical reactions or induced electron transfers. Due to the large band gap of TiO,,2,, (3.2eV), only 10% of the solar spectrum is used. A major objective for future work is the development of a semiconductor photocatalyst film which is able to utilize visible as well as UV light. Nanoscience has the potential to provide entirely new classes of materials with capabilities that transcend these limitations and generate the performance breakthroughs required for a viable economy based on sustainable energy. Recent investigations in this area allowed us to synthesize novel photo-sensitive titanium oxide sols and gels by controlling the condensation of titanium species in non aqueous solvents. Depending on different parameters such as concentration in Ti^^4+^^, ageing or thermal treatment, to emphasise few, the structuration of the inorganic framework leads to various layered structure. The adsorbed organic species control the growth of the nano-objects present in the sol or gel. Due to the enhanced surface area to volume ratio, these nanostructured sols and gels produce singular photo-electrochemical properties that are drastically different from their bulk counterparts. When irradiated, these materials can absorb photons with a lower energy than the bandgap energy of the original semiconductor, and thus a significant increase in the limiting efficiency of conventional solar cells is expected. These new materials are principally characterized by a partially occupied intermediate band, isolated from the valence and conduction bands. Our purpose is to use these intermediate band materials as sensitizers in both third generation photoelectrochemical solar cells and photo-batteries (ultracapacitors). |
关 键 词: | 环境保护; 光化学; 纳米结构 |
课程来源: | 视频讲座网 |
最后编审: | 2019-09-21:cwx |
阅读次数: | 56 |