太阳能光伏材料的研究进展

近年来,不同体系及不同结构的太阳能电池材料的研究都取得了很好的效果。简要概述了3代太阳能电池的发展,综述了有机和无机2大类光伏发电材料的发展情况,并对作为太阳能电池前沿材料(如:石墨烯)的发展趋势进行了展望。

浅谈太阳能光伏发电材料的研究进展及发展前景

随着我国社会经济的不断发展,对能源资源需求总量也在不断提高,绿色能源发展提供了广阔的契机,太阳能作为目前最重要的绿色能源被人们广泛关注。利用上转换机制、多光子吸收机制、多机子产生机制和下转换机制,提高太阳能电池的效率,实现能量的快速转换。对光伏材料方面硅材料、低维纳米材料、薄膜材料也能够直接影响太阳能光伏发电的效率。

BiFeO_(3)系固溶体钙钛矿窄禁带铁电半导体光伏材料

铁电半导体能够单片式集成半导体p-n结光伏与铁电体光伏,有望突破太阳能光伏电池能量转换效率的Shockley-Queisser理论极限.本研究采用Mn^(4+)、Co^(2+)等磁性离子替代技术在BiFeO_(3)系固溶体钙钛矿中成功创制出一系列窄禁带室温铁电半导体,应用传统固相反应法制备了0.50BiFeO_(3)-0.25A_(1)MnO_(3)-0.25A_(2)TiO_(3)(A_(1)=Ca、Sr、Ba,A_(2)=Sr、Ba、Pb)和0.49BiFeO_(3)-0.26BaTiO_(3)-0.25(Sr_(1–x)Ba_(x))(Co_(1/3)Nb_(2/3))O_(3)单相钙钛矿陶瓷.室温拉曼散射光谱测试表明这些固溶体钙钛矿空间中心反演对称破缺,与应用Vegard规则估算它们是室温铁电相的结果一致.紫外-可见-近红外波段吸光度测试表明它们是禁带宽度E_(g)在0.75~1.0 eV的直接带隙半导体.变温电学测试表明其电阻率为~10^(6)Ωcm(40°C)量级、缺陷激活能E_(a)~0.5 eV.与卤化物钙钛矿相比,E_(g)~0.9 eV的BiFeO_(3)系固溶体钙钛矿对太阳能光谱的吸收已深入近红外波段.通过分析铁电半导体禁带宽度与磁性离子d电子组态、μ×r_(A)/r_(B)系综描述符(μ、r_(A)和r_(B)分别为原胞的约合质量、A位和B位离子半径)之间的因果关系,为下一步优选集成半导体p-n结光伏和铁电体光伏太阳能电池的功能元,提供了材料预测设计的物理模型.

Development of small-molecule materials for high-performance organic solar cells

With the rapid development in recent years, small-molecule organic solar cell is challenging the dominance of its counterpart, polymer solar cell. The top power conversion efficiencies of both single and tandem solar cells based on small molecules have surpassed 9%. In this mini review, achievements of small molecules with impressive photovoltaic performance especially reported in the last two years were highlighted. The relationship between molecular structure and device performance was analyzed, which draws some rules for rational molecular design. Five series of p- and n-type small molecules were selected based on the consideration of their competitiveness of power conversion efficiencies.