近年來能源問題以及環境議題備受討論，太陽能作為一種具發展性的可再生能源已經逐漸受到關注，而這當中有機太陽能電池製程有著低成本、輕巧且可重複利用的特性而受到大量的研究以及開發，未來將朝著元件之高光電轉換效率的方向邁進。
　　在有機太陽能電池模組化製程中會進行子元件的串聯，子元件串聯會產生難以發電的部分區域，這個部分區域稱為死區(Dead zone)，有著影響太陽能電池效率決定性的因素。本論文之目的為探討如何優化降低死區製程之模組，其中包含新蒸鍍樣式遮罩、改良製程模組上的各式因素並且做比較來提升元件之能量轉換效率與填充因子，希望可以在固定的量測面積下增加其有效發電區域。

關鍵字:有機太陽能電池、刮刀塗佈製程、填充因子、提升有效發電區域、二元系統

In recent years, energy issues and environmental issues have been much discussed. Solar energy, as a promising renewable energy source, has gradually attracted attention. Among them, the organic solar cell process has received a lot of research due to its low cost, lightweight and reusable characteristics. As well as development, the future will move towards high photoelectric conversion efficiency of components.
In the modularization process of organic solar cells, sub-components are connected in series. The series connection of sub-components will create a partial area where it is difficult to generate electricity. This partial area is called a dead zone, which is a decisive factor affecting the efficiency of solar cells. The purpose of this thesis is to explore how to optimize the module that reduces the dead zone process, including new evaporation style masks, various factors on the improved process module, and make comparisons to improve the energy conversion efficiency and fill factor of the device. I hope it can Increase its effective power generation area under a fixed measurement area.

Keywords:Organic Solar Cell, Blade coating, Fill factor, increase effective power generation area, binary system.

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