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以絲網印刷法製備染料敏化太陽能電池應用於小型供電元件之研究 = = St...

王立甫

以絲網印刷法製備染料敏化太陽能電池應用於小型供電元件之研究 = = Study on preparation of dye-sensitized solar cells by screen printing method for application in small power supply components /

Record Type:	Language materials, printed : Monograph/item
Title/Author:	以絲網印刷法製備染料敏化太陽能電池應用於小型供電元件之研究 =/ 王立甫.
Reminder of title:	Study on preparation of dye-sensitized solar cells by screen printing method for application in small power supply components /
remainder title:	Study on preparation of dye-sensitized solar cells by screen printing method for application in small power supply components.
Author:	王立甫
Published:	雲林縣 :國立虎尾科技大學 , : 民113.07.,
Description:	66面 :圖, 表 ; : 30公分.;
Notes:	指導教授: 閔庭輝.
Subject:	screen printing method. -
Online resource:	電子資源

以絲網印刷法製備染料敏化太陽能電池應用於小型供電元件之研究 = = Study on preparation of dye-sensitized solar cells by screen printing method for application in small power supply components /
王立甫

以絲網印刷法製備染料敏化太陽能電池應用於小型供電元件之研究 =Study on preparation of dye-sensitized solar cells by screen printing method for application in small power supply components /Study on preparation of dye-sensitized solar cells by screen printing method for application in small power supply components.王立甫. - 初版. - 雲林縣 :國立虎尾科技大學 ,民113.07. - 66面 :圖, 表 ;30公分.

指導教授: 閔庭輝.

碩士論文--國立虎尾科技大學電子工程系碩士班.

含參考書目.

染料敏化太陽能電池與傳統矽半導體太陽能電池相比，具有製程簡單、成本低廉和性能穩定等優勢，其光陽極通常是使用二氧化鈦 (TiO2) 材料薄膜作為電子傳輸劑，以及染料分子吸收太陽光譜的能量，將其轉換為電能。作為光陽極複合材料，石墨烯被認為是最佳選擇之一。石墨烯具有高比表面積、優良的熱穩定性和導電性，同時還是目前已知具有最小電阻率的材料之一。本研究使用絲網印刷法製備染料敏化太陽能電池(DSSCs)，並在二氧化鈦(P25)光陽極(PA)中摻雜不同濃度的單層石墨烯(G)製程染敏電池並將最佳的單層石墨烯濃度工作電極面積加大使其最大電流得到提升，最後再與電容進行整合完成能源的充放電系統。經數據結果表明，摻雜了單層石墨烯的二氧化鈦複合薄膜染敏電池相較於純二氧化鈦所製成的薄膜染敏電池，其短路電流密度(Jsc)由12.95 mA/cm2上升至14.051 mA/cm2，轉換效率(η)由5.764 % 上升至6.314 % ，內部結構阻抗(Rk)從13.328 Ω 下降至11.032 Ω。將摻雜單層石墨烯最佳濃度的工作電極面積增大後從原先Imax(mA) : 3.095mA提升到10.092mA，並將元件整合進行串並聯完成驅動LED，在增大工作面積後電容所需充電時間得到縮短。.

(平裝)Subjects--Topical Terms:

1451620
screen printing method.

以絲網印刷法製備染料敏化太陽能電池應用於小型供電元件之研究 = = Study on preparation of dye-sensitized solar cells by screen printing method for application in small power supply components /
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245 1 0 $a 以絲網印刷法製備染料敏化太陽能電池應用於小型供電元件之研究 = $b Study on preparation of dye-sensitized solar cells by screen printing method for application in small power supply components / $c 王立甫.
246 1 1 $a Study on preparation of dye-sensitized solar cells by screen printing method for application in small power supply components.
250 $a 初版.
260 # $a 雲林縣 : $b 國立虎尾科技大學 , $c 民113.07.
300 $a 66面 : $b 圖, 表 ; $c 30公分.
500 $a 指導教授: 閔庭輝.
500 $a 學年度: 112.
502 $a 碩士論文--國立虎尾科技大學電子工程系碩士班.
504 $a 含參考書目.
520 3 $a 染料敏化太陽能電池與傳統矽半導體太陽能電池相比，具有製程簡單、成本低廉和性能穩定等優勢，其光陽極通常是使用二氧化鈦 (TiO2) 材料薄膜作為電子傳輸劑，以及染料分子吸收太陽光譜的能量，將其轉換為電能。作為光陽極複合材料，石墨烯被認為是最佳選擇之一。石墨烯具有高比表面積、優良的熱穩定性和導電性，同時還是目前已知具有最小電阻率的材料之一。本研究使用絲網印刷法製備染料敏化太陽能電池(DSSCs)，並在二氧化鈦(P25)光陽極(PA)中摻雜不同濃度的單層石墨烯(G)製程染敏電池並將最佳的單層石墨烯濃度工作電極面積加大使其最大電流得到提升，最後再與電容進行整合完成能源的充放電系統。經數據結果表明，摻雜了單層石墨烯的二氧化鈦複合薄膜染敏電池相較於純二氧化鈦所製成的薄膜染敏電池，其短路電流密度(Jsc)由12.95 mA/cm2上升至14.051 mA/cm2，轉換效率(η)由5.764 % 上升至6.314 % ，內部結構阻抗(Rk)從13.328 Ω 下降至11.032 Ω。將摻雜單層石墨烯最佳濃度的工作電極面積增大後從原先Imax(mA) : 3.095mA提升到10.092mA，並將元件整合進行串並聯完成驅動LED，在增大工作面積後電容所需充電時間得到縮短。.
520 3 $a Compared to traditional silicon semiconductor solar cells, dye-sensitized solar cells offer advantages such as simple processing, low cost, and stable performance. Typically, their photoanodes employ titanium dioxide (TiO2) thin films as electron conductors, while dye molecules absorb energy from the solar spectrum and convert it into electricity. Graphene is considered one of the optimal choices as a composite material for the photoanode. It possesses a high surface area, excellent thermal stability, conductivity, and is one of the materials known to have the smallest electrical resistivity. This study utilized screen printing to fabricate dye-sensitized solar cells (DSSCs), doping different concentrations of single-layer graphene (G) into titanium dioxide (P25) photoanodes (PAs) to process the dye-sensitized cells. The optimal concentration of single-layer graphene was then incorporated into the working electrode area to enhance maximum current, and finally integrated with a capacitor to complete the energy storage and discharge system. Data results indicate that compared to pure titanium dioxide films, dye-sensitized solar cells with graphene-doped titanium dioxide composite films exhibited an increase in short-circuit current density (Jsc) from 12.95mA/ cm2 to 14.051mA/ cm2, conversion efficiency (η) from 5.764% to 6.314%, and a decrease in internal structural impedance (Rk) from 13.328 Ω to 11.032 Ω. Increasing the working electrode area with the optimal concentration of graphene doping resulted in an increase in the maximum current Imax(mA) from 3.095 mA to 10.092 mA, and the components were integrated for series and parallel connections to drive LEDs, After increasing the working area, the time required for the capacitor to charge is shortened..
563 $a (平裝)
650 # 4 $a screen printing method. $3 1451620
650 # 4 $a titanium dioxide. $3 1127684
650 # 4 $a graphene. $3 1137666
650 # 4 $a Dye-sensitized solar cells. $3 839173
650 # 4 $a 絲網印刷法. $3 1419338
650 # 4 $a 二氧化鈦. $3 995094
650 # 4 $a 石墨烯. $3 996200
650 # 4 $a 染料敏化太陽能電池. $3 995160
856 7 # $u https://handle.ncl.edu.tw/11296/6264r4 $z 電子資源 $2 http