![]() This breakthrough allows for a simplified fabrication thanks to an all-printed philosophy, and makes it possible to use only one glass substrate. The investigation of monolithic assemblies began before 2008, with the development of an electrically conductive carbon electrode obtained by printing. In parallel to these advances, Solaronix works actively on the future of Dye Solar Cells. Available in different colors and transparencies, these models were more recently designed into transparent solar panels for façades. Vastly optimized for after several years of optimization, and heavily tested in internal and external projects, these demonstration products led to the first commercial applications of our Dye Solar Cells. Our first models of SERIO, interconnected modules comprising several solar cells in a single assembly, emerged almost concomitantly. Today, its aspect can be further tuned in color and transparency. This led to our first model, PICTO, which can be decorated and customized in shape. In 1999, Solaronix began to explore different methods to make patterned solar cells. These materials now serve a worldwide customer base composed of academies and industrial partners. The production and the supply of the other ingredients quickly followed, and has grown into a portfolio of specialty chemicals and components for Dye Solar Cell fabrication. Soon after, the company began to produce the sensitizing dyes, not only to feed the internal needs, but also to supply customers who started investigating the technology. The solar cell activities at Solaronix began in 1996 with the elaboration of Dye Solar Cells at a laboratory scale. 2013 hybrid solid-state solar cells, perovskite solar cells.2008 Monolithic solar cells, MIMO modules.2003-2010 development and testing of materials and production techniques.2002 emergence of the SERIO interconnected solar modules.1999 patterned cells, first models of PICTO.Since our desire has always been to provide innovative solar energy solutions, it was natural for us to work in this direction. ![]() This, in turn, will lead to a multitude of technological breakthroughs. This new approach has opened a formidable range of possibilities for next generation photovoltaic devices. Solaronix is working to develop a 3rd generation photovoltaic technology in which that junction isn't necessarily uniform, and can employ other materials than simple semiconductors. Current commercial photovoltaic panels found today are largely of these two types. Our company acquired the first EPFL license for Dye Solar Cell technology in 1994, with the aim of transposing these scientific discoveries into industrial products.Ĭonventional solar cells consist of a single junction between a positively and negatively doped semiconductor such as silicon (1st generation), or multiple junctions of different semiconductors (2nd generation). Grätzel and his team at the Polytechnic School in Lausanne (EPFL) in the early 90's. Solaronix is developing new generation photovoltaic solar cells, following the scientific breakthrough realized by Prof.
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