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    • 3. 发明申请
    • Optoelectronic device and fabrication method
    • 光电器件及其制造方法
    • US20070181177A9
    • 2007-08-09
    • US10290119
    • 2002-11-05
    • Brian SagerMartin RoscheisenKlaus PetritschGreg SmestadJacqueline FidanzaGregory MillerDong Yu
    • Brian SagerMartin RoscheisenKlaus PetritschGreg SmestadJacqueline FidanzaGregory MillerDong Yu
    • H01L31/00
    • H01L51/4226H01L51/0034H01L51/0035H01L51/0036H01L51/0038H01L51/0052H01L51/0053H01L51/0064H01L51/0078H01L51/4253Y02E10/549Y02P70/521
    • Charge-splitting networks, optoelectronic devices, methods for making optoelectronic devices, power generation systems utilizing such devices and method for making charge-splitting networks are disclosed. An optoelectronic device may include a porous nano-architected (e.g., surfactant-templated) film having interconnected pores that are accessible from both the underlying and overlying layers. A pore-filling material substantially fills the pores. The interconnected pores have diameters of about 1-100 nm and are distributed in a substantially uniform fashion with neighboring pores separated by a distance of about 1-100 nm. The nano-architected porous film and the pore-filling, material have complementary charge-transfer properties with respect to each other, i.e., one is an electron-acceptor and the other is a hole-acceptor. The nano-architected porous, film may be formed on a substrate by a surfactant temptation technique such as evaporation-induced self-assembly. A solar power generation system may include an array of such optoelectronic devices in the form of photovoltaic cells with one or more cells in the array having one or more porous charge-splitting networks disposed between an electron-accepting electrode and a hole-accepting electrode.
    • 公开了电荷分解网络,光电子器件,制造光电器件的方法,利用这种器件的发电系统以及用于制造电荷分解网络的方法。 光电子器件可以包括具有互连孔的多孔纳米结构(例如,表面活性剂模板化)膜,其可以从下面的层和上层两者接近。 孔填充材料基本上填充孔。 相互连通的孔具有大约1-100nm的直径,并以基本上均匀的方式分布,其中相邻的孔分开约1-100nm的距离。 纳米结构的多孔膜和孔填充材料相对于彼此具有互补的电荷转移性质,即一个是电子受体,另一个是空穴受体。 纳米结构的多孔膜可以通过表面活性剂诱导技术如蒸发诱导的自组装形成在基底上。 太阳能发电系统可以包括光伏电池形式的这种光电子器件的阵列,阵列中的一个或多个电池具有设置在电子接受电极和空穴接受电极之间的一个或多个多孔电荷分解网络。
    • 4. 发明申请
    • Optoelectronic device and frabrication method
    • 光电器件及其制造方法
    • US20060174934A1
    • 2006-08-10
    • US11375413
    • 2006-03-13
    • Brian SagerMartin RoscheisenKlaus PetristschGreg SmestadJacqueline FidanzaGregory MillerDong Yu
    • Brian SagerMartin RoscheisenKlaus PetristschGreg SmestadJacqueline FidanzaGregory MillerDong Yu
    • H01L31/042H01L31/00
    • H01L51/4226H01L51/0034H01L51/0035H01L51/0036H01L51/0038H01L51/0052H01L51/0053H01L51/0064H01L51/0078H01L51/4253Y02E10/549Y02P70/521
    • Charge-splitting networks, optoelectronic devices, methods for making optoelectronic devices, power generation systems utilizing such devices and method for making charge-splitting networks are disclosed. An optoelectronic device may include a porous nano-architected (e.g., surfactant-templated) film having interconnected pores that are accessible from both the underlying and overlying layers. A pore-filling material substantially fills the pores. The interconnected pores have diameters of about 1-100 nm and are distributed in a substantially uniform fashion with neighboring pores separated by a distance of about 1-100 nm. The nano-architected porous film and the pore-filling material have complementary charge-transfer properties with respect to each other, i.e., one is an electron-acceptor and the other is a hole-acceptor. The nano-architected porous, film may be formed on a substrate by a surfactant temptation technique such as evaporation-induced self-assembly. A solar power generation system may include an array of such optoelectronic devices in the form of photovoltaic cells with one or more cells in the array having one or more porous charge-splitting networks disposed between an electron-accepting electrode and a hole-accepting electrode.
    • 公开了电荷分解网络,光电子器件,制造光电器件的方法,利用这种器件的发电系统以及用于制造电荷分解网络的方法。 光电子器件可以包括具有互连孔的多孔纳米结构(例如,表面活性剂模板化)膜,其可以从下面的层和上层两者接近。 孔填充材料基本上填充孔。 相互连通的孔具有大约1-100nm的直径,并以基本上均匀的方式分布,其中相邻的孔分开约1-100nm的距离。 纳米构造的多孔膜和孔隙填充材料相互之间具有互补的电荷转移性质,即一个是电子受体,另一个是空穴受体。 纳米结构的多孔膜可以通过表面活性剂诱导技术如蒸发诱导的自组装形成在基底上。 太阳能发电系统可以包括光伏电池形式的这种光电子器件的阵列,阵列中的一个或多个电池具有设置在电子接受电极和空穴接受电极之间的一个或多个多孔电荷分解网络。
    • 6. 发明授权
    • Solution-based fabrication of photovoltaic cell
    • 光伏电池基于解决方案的制造
    • US08366973B2
    • 2013-02-05
    • US11933357
    • 2007-10-31
    • Dong YuJacqueline FidanzaBrian M. Sager
    • Dong YuJacqueline FidanzaBrian M. Sager
    • H01B1/12
    • H01L31/06B82Y5/00B82Y10/00B82Y30/00C23C18/1204C23C18/1266C23C18/1295H01L31/0322H01L31/0749H01L31/18Y02E10/541Y02P70/521
    • An ink for forming CIGS photovoltaic cell active layers is disclosed along with methods for making the ink, methods for making the active layers and a solar cell made with the active layer. The ink contains a mixture of nanoparticles of elements of groups IB, IIIA and (optionally) VIA. The particles are in a desired particle size range of between about 1 nm and about 500 nm in diameter, where a majority of the mass of the particles comprises particles ranging in size from no more than about 40% above or below an average particle size or, if the average particle size is less than about 5 nanometers, from no more than about 2 nanometers above or below the average particle size. The use of such ink avoids the need to expose the material to an H2Se gas during the construction of a photovoltaic cell and allows more uniform melting during film annealing, more uniform intermixing of nanoparticles, and allows higher quality absorber films to be formed.
    • 公开了一种用于形成CIGS光伏电池有源层的墨水以及用于制备墨水的方法,制备活性层的方法和由活性层制成的太阳能电池。 油墨含有IB,IIIA和(任选地)VIA组分的纳米颗粒的混合物。 颗粒的直径在约1nm至约500nm之间的所需粒度范围,其中大部分颗粒的质量包括尺寸不超过平均粒度的约40%或以下的颗粒,或 如果平均粒度小于约5纳米,高于或低于平均粒度的不超过约2纳米。 使用这种墨水避免了在构建光伏电池期间将材料暴露于H 2 Se气体的需要,并且允许在膜退火期间更均匀的熔融,更均匀的纳米颗粒的混合,并且允许形成更高质量的吸收膜。
    • 10. 发明授权
    • Solution-based fabrication of photovoltaic cell
    • 光伏电池基于解决方案的制造
    • US08088309B2
    • 2012-01-03
    • US11933400
    • 2007-10-31
    • Dong YuJacqueline FidanzaBrian M. Sager
    • Dong YuJacqueline FidanzaBrian M. Sager
    • H01B1/22B05D5/12
    • H01L31/06B82Y5/00B82Y10/00B82Y30/00C23C18/1204C23C18/1266C23C18/1295H01L31/0322H01L31/0749H01L31/18Y02E10/541Y02P70/521
    • An ink for forming CIGS photovoltaic cell active layers is disclosed along with methods for making the ink, methods for making the active layers and a solar cell made with the active layer. The ink contains a mixture of nanoparticles of elements of groups IB, IIIA and (optionally) VIA. The particles are in a desired particle size range of between about 1 nm and about 500 nm in diameter, where a majority of the mass of the particles comprises particles ranging in size from no more than about 40% above or below an average particle size or, if the average particle size is less than about 5 nanometers, from no more than about 2 nanometers above or below the average particle size. The use of such ink avoids the need to expose the material to an H2Se gas during the construction of a photovoltaic cell and allows more uniform melting during film annealing, more uniform intermixing of nanoparticles, and allows higher quality absorber films to be formed.
    • 公开了一种用于形成CIGS光伏电池有源层的墨水以及用于制备墨水的方法,制备活性层的方法和由活性层制成的太阳能电池。 油墨含有IB,IIIA和(任选地)VIA组分的纳米颗粒的混合物。 颗粒的直径在约1nm至约500nm之间的所需粒度范围,其中大部分颗粒的质量包括尺寸不超过平均粒度的约40%或以下的颗粒,或 如果平均粒度小于约5纳米,高于或低于平均粒度的不超过约2纳米。 使用这种墨水避免了在构建光伏电池期间将材料暴露于H 2 Se气体的需要,并且允许在膜退火期间更均匀的熔融,更均匀的纳米颗粒的混合,并且允许形成更高质量的吸收膜。