核聚变与等离子体物理
覈聚變與等離子體物理
핵취변여등리자체물리
NUCLEAR FUSION AND PLASMA PHYSICS
2014年
3期
275-281
,共7页
宋莎莎%左潇%魏钰%陈龙威%舒兴胜
宋莎莎%左瀟%魏鈺%陳龍威%舒興勝
송사사%좌소%위옥%진룡위%서흥성
电感耦合等离子体%等离子体增强化学气相沉积%多晶硅薄膜%氢气比例
電感耦閤等離子體%等離子體增彊化學氣相沉積%多晶硅薄膜%氫氣比例
전감우합등리자체%등리자체증강화학기상침적%다정규박막%경기비례
Inductively coupled plasma%Plasma enhanced chemical vapor deposition%Polycrystalline silicon thin films%H2 dilution
利用电感耦合等离子体增强化学气相沉积法(ICP-PECVD)直接在普通玻璃衬底上低温沉积多晶硅薄膜,主要研究了不同氢气稀释比例对薄膜沉积特性和微观结构的影响。采用X射线衍射仪(XRD)、拉曼光谱仪和扫描电子显微镜(SEM)表征了在不同氢气比例条件下所制备多晶硅薄膜的微结构、形貌,并对不同条件下样品的沉积速率进行了分析。实验结果表明:随着混合气体中硅烷比例的增加,薄膜的沉积速率不断增加;晶化率先增加,后减小;当硅烷含量为4.8%时,晶化率达到最大值67.3%。XRD和SEM结果显示多晶硅薄膜在普通玻璃衬底上呈柱状生长,且晶粒排列整齐、致密,这种结构可提高载流子的纵向迁移率,有利于制备高效多晶硅薄膜太阳能电池。
利用電感耦閤等離子體增彊化學氣相沉積法(ICP-PECVD)直接在普通玻璃襯底上低溫沉積多晶硅薄膜,主要研究瞭不同氫氣稀釋比例對薄膜沉積特性和微觀結構的影響。採用X射線衍射儀(XRD)、拉曼光譜儀和掃描電子顯微鏡(SEM)錶徵瞭在不同氫氣比例條件下所製備多晶硅薄膜的微結構、形貌,併對不同條件下樣品的沉積速率進行瞭分析。實驗結果錶明:隨著混閤氣體中硅烷比例的增加,薄膜的沉積速率不斷增加;晶化率先增加,後減小;噹硅烷含量為4.8%時,晶化率達到最大值67.3%。XRD和SEM結果顯示多晶硅薄膜在普通玻璃襯底上呈柱狀生長,且晶粒排列整齊、緻密,這種結構可提高載流子的縱嚮遷移率,有利于製備高效多晶硅薄膜太暘能電池。
이용전감우합등리자체증강화학기상침적법(ICP-PECVD)직접재보통파리츤저상저온침적다정규박막,주요연구료불동경기희석비례대박막침적특성화미관결구적영향。채용X사선연사의(XRD)、랍만광보의화소묘전자현미경(SEM)표정료재불동경기비례조건하소제비다정규박막적미결구、형모,병대불동조건하양품적침적속솔진행료분석。실험결과표명:수착혼합기체중규완비례적증가,박막적침적속솔불단증가;정화솔선증가,후감소;당규완함량위4.8%시,정화솔체도최대치67.3%。XRD화SEM결과현시다정규박막재보통파리츤저상정주상생장,차정립배렬정제、치밀,저충결구가제고재류자적종향천이솔,유리우제비고효다정규박막태양능전지。
Polycrystalline silicon thin film formation from inductively coupled plasma enhanced chemical vapor deposition system was studied. The dilution effect of H2 on film deposition was discussed. The X-ray diffractometry, Raman spectra and scanning electron microscope measurement were carried out to analyze the influence of H2 on the microstructures and the topography of polycrystalline silicon thin films. The optimum conditions for polycrystalline silicon thin films deposition were also discussed. The results indicated that polycrystalline silicon thin films with columnar structure crystals were fabricated on glass substrate. The deposition rate exhibited monotonic increase with Silane ratio R, a maximum deposition rate of 0.65nm?s-1 was obtained. However, the crystal volume fraction of polycrystalline silicon thin films initially increased from 60.5%to 67.3%, and then slightly decreased with the increase of R. Therefore, the crystal has a maximum value of 67.3%at R=4.8%. The polycrystalline silicon thin films had a compact and well-arranged structure at this ratio. This structure can also increase carrier mobility and improve the efficiency of solar cells.
