电子元件与材料
電子元件與材料
전자원건여재료
ELECTRONIC COMPONENTS & MATERIALS
2015年
6期
23-27
,共5页
聂慧军%刘淑平%吕雁文%杨大洋
聶慧軍%劉淑平%呂雁文%楊大洋
섭혜군%류숙평%려안문%양대양
β-FeSi2%环保型材料%HIT型太阳能电池%本征层%界面态密度%afors-het
β-FeSi2%環保型材料%HIT型太暘能電池%本徵層%界麵態密度%afors-het
β-FeSi2%배보형재료%HIT형태양능전지%본정층%계면태밀도%afors-het
β-FeSi2%environment-friendly materials%HIT type solar cell%intrinsic layer%interface states density%afors-het
运用afors-het软件对β-FeSi2(n)/a-Si (i)/c-Si(p)结构的太阳能电池进行模拟,依次讨论了本征层、发射层、界面态对电池性能的影响。结果表明:添加本征层电池性能提高,但随着本征层厚度的增加载流子收集率下降、串联电阻增大,造成电池光电转化效率下降;发射层厚度的增加使得载流子的收集率下降造成光电转化效率下降,同时发射层掺杂浓度增大虽然使得内建电场强度增大,但载流子的复合也会加大,最终使得电池性能保持稳定;界面态使得电池性能下降,为使电池获得较好性能,界面态密度应尽可能小于1011 cm–2·eV–1。通过优化,最终使得该结构的太阳能电池光电转化效率达到17.00%。
運用afors-het軟件對β-FeSi2(n)/a-Si (i)/c-Si(p)結構的太暘能電池進行模擬,依次討論瞭本徵層、髮射層、界麵態對電池性能的影響。結果錶明:添加本徵層電池性能提高,但隨著本徵層厚度的增加載流子收集率下降、串聯電阻增大,造成電池光電轉化效率下降;髮射層厚度的增加使得載流子的收集率下降造成光電轉化效率下降,同時髮射層摻雜濃度增大雖然使得內建電場彊度增大,但載流子的複閤也會加大,最終使得電池性能保持穩定;界麵態使得電池性能下降,為使電池穫得較好性能,界麵態密度應儘可能小于1011 cm–2·eV–1。通過優化,最終使得該結構的太暘能電池光電轉化效率達到17.00%。
운용afors-het연건대β-FeSi2(n)/a-Si (i)/c-Si(p)결구적태양능전지진행모의,의차토론료본정층、발사층、계면태대전지성능적영향。결과표명:첨가본정층전지성능제고,단수착본정층후도적증가재류자수집솔하강、천련전조증대,조성전지광전전화효솔하강;발사층후도적증가사득재류자적수집솔하강조성광전전화효솔하강,동시발사층참잡농도증대수연사득내건전장강도증대,단재류자적복합야회가대,최종사득전지성능보지은정;계면태사득전지성능하강,위사전지획득교호성능,계면태밀도응진가능소우1011 cm–2·eV–1。통과우화,최종사득해결구적태양능전지광전전화효솔체도17.00%。
The performance of β-FeSi2(n)/c-Si(p) HIT solar cell was simulated by using the afors-het. At the same time, the influences of the intrinsic layer, an emission layer, and the interface states on the battery performance were discussed. The results show that, the performance of battery is improved after adding the intrinsic layer. However, with the increasing of the intrinsic layer thickness, carrier collection rate decreases and the series resistance increases so that the photoelectric conversion efficiency of cell decreases. Increasing the thickness of the emission layer makes the collection rate of carrier decrease, causing that the photoelectric conversion efficiency reduces. Although the increasing of emission layer doping concentration leads to increasing of built-in electric field intensity, the carrier compound increases simultaneously. So the battery performance remains stable. Interface states degrade battery performance, so the density of interface states should be less than 1011cm–2·eV–1 in order to obtain the better performance for the cell. By optimizing the various parameters of the cell, the photoelectricconversion efficiency of β-FeSi2(n)/a-Si(i)/c-Si(p) solar cell can reach 17.00%.