Green Approach for In-Situ Growth of CdS Nanorods in Low Band Gap Polymer Network for Hybrid Solar Cell Applications

纳米粒子(英文) Pub Date : 2014-08-11 DOI:10.4236/ANP.2014.33015

R. Bhardwaj, V. Bharti, Abhishek Sharma, D. Mohanty, V. Agrawal, N. Vats, G. Sharma, N. Chaudhary, Shilpa Jain, Jitender Gaur, Kamalika Banerjee, S. Chand

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Abstract

In-situ growth of CdS nanorods (NRs) has been demonstrated via solvothermal, in a low band gap polymer, poly [[4,8-bis[(2-ethylhexyl)oxy] benzo [1,2-b:4,5-b’] dithiophene-2,6-diyl] [3-fluoro-2-[(2-ethylhexyl) carbonyl] thieno [3,4-b] thiophenediyl]] (PTB7). It is a high yielding, green approach as it removes use of volatile and hazardous chemicals such as pyridine as ligand which are conventionally used to synthesize precursors of CdS (NRs). Moreover the solvothermal process is a zero emission process being a close vessel synthesis and hence no material leaching into the atmosphere during the synthesis. The PTB7:CdS nanocomposite has been characterized by SEM, XRD, FTIR, UV-visible spectroscopy techniques. The photoluminescence (PL) spectroscopy study of PTB7 with CdS NRs has shown significant PL quenching by the incorporation of CdS NRs in PTB7; this shows that CdS NRs are efficient electron acceptors with the PTB7. The PTB7:CdS is used as active layer in the fabrication of hybrid solar cells (HSC) as donor-acceptor combination in the bulk heterojunction (BHJ) geometry. The HSCs fabricated using this active layer without any additional supporting fullerene based electron acceptor has given power conversion efficiency of above 1%.

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混合太阳能电池用低带隙聚合物网络原位生长CdS纳米棒的绿色方法

采用溶剂热法在低带隙聚合物聚[[4,8-二[(2-乙基己基)氧]苯并[1,2-b:4,5-b ']二噻吩-2,6-二基][3-氟-2-[(2-乙基己基)羰基]噻吩[3,4-b]噻吩二基](PTB7)中原位生长了CdS纳米棒(nr)。这是一种高产、绿色的方法，因为它不使用挥发性和危险的化学物质，如吡啶作为配体，而这些化学物质通常用于合成CdS (nr)的前体。此外，溶剂热过程是一个零排放过程，是一个紧密的容器合成，因此在合成过程中没有物质浸出到大气中。采用SEM、XRD、FTIR、紫外可见光谱等技术对PTB7:CdS纳米复合材料进行了表征。PTB7与CdS NRs的光致发光(PL)光谱研究表明，CdS NRs掺入PTB7后，PTB7发生了明显的PL猝灭;这表明CdS NRs与PTB7是有效的电子受体。PTB7:CdS被用作混合太阳能电池(HSC)制造中的有源层，作为体异质结(BHJ)几何结构中的供体-受体组合。利用该活性层制备的hsc没有任何额外的支持富勒烯基电子受体，其功率转换效率超过1%。

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