入射單色光-電子轉(zhuǎn)化效率(Incident Monochromatic Photon-Electron Conversion Efficiency,IPCE)定義為流經(jīng)閉合電路中的電子數(shù)與入射單色光的光電子數(shù)的比值,用來(lái)評(píng)價(jià)不同波長(zhǎng)下的光電轉(zhuǎn)化效率,是評(píng)價(jià)光電極光電化學(xué)性能的重要指標(biāo)之一。
由于半導(dǎo)體材料對(duì)不同波長(zhǎng)的入射光具有不同的響應(yīng),因此,測(cè)量光電極的IPCE對(duì)評(píng)估光電極對(duì)單色光光子的利用率會(huì)更加精確,進(jìn)而在改進(jìn)光電極提升其光電化學(xué)性能上更具針對(duì)性[1]。
IPCE計(jì)算公式如下[2]:
jph:光電流密度(mA·cm-2),通過(guò)計(jì)時(shí)電流法(恒電位)測(cè)得
h:普朗克常量(6.62×10-34 J·s)
c:光速(3.0×108 m·s-1)
e:?jiǎn)蝹€(gè)電子所攜帶的電量(1.6×10-19 C)
Pmono:?jiǎn)紊獾墓夤β拭芏龋╩W·cm-2)
λ:?jiǎn)紊獠ㄩL(zhǎng)
簡(jiǎn)化后可表示為公示(2)[1]:
jp:光電流密度(mA·cm-2)
jd:暗電流密度(mA·cm-2)
λ:入射單色光波長(zhǎng)(nm)
pin:光電極受到的光功率密度(mW·cm-2)
光電極的光電流密度越大,IPCE值越高,可以通過(guò)改善光電極材料的電荷分離和收集效率,進(jìn)一步提升光電極的光電流密度,從而提高IPCE數(shù)值。
泊菲萊科技PL-PES光譜光電系統(tǒng)可實(shí)現(xiàn)以入射光的波長(zhǎng)為函數(shù),在紫外、可見(jiàn)、近紅外波長(zhǎng)范圍,自動(dòng)表征測(cè)量半導(dǎo)體材料的光電流、光伏等光電性能參數(shù),可與開(kāi)爾文探針、電導(dǎo)探針等測(cè)試設(shè)備聯(lián)用,可以控制輸出光波長(zhǎng)、光照射時(shí)間、與電化學(xué)工作站同步工作。PL-PES光譜光電系統(tǒng)主要應(yīng)用于不同外加電壓條件、不同光照波長(zhǎng)、不同光強(qiáng)和不同電壓及光照強(qiáng)度掃描下的光電流測(cè)試和特定光照波長(zhǎng)下的開(kāi)路電位測(cè)試等。
Fig.1 a)PL-PES光譜光電系統(tǒng); b) IPCE曲線及光電流/電壓行為譜
Fig. 2. a) IPCE at 0 V vs. Ag/AgCl[3]; b) IPCE at 1.2 V vs. Ag/AgCl[4]; c)IPCE [5]; d) IPCE at 1.2 VRHE; e) band gaps from photocurrent measurements[6];f) IPCEs at 0.6 and 1.2 VRHE, respectively[7]
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