碳納米管@碳化硅同軸異質(zhì)結(jié)納米管非金屬光催化劑產(chǎn)氫性能(英文)
發(fā)布時間:2021-11-13 23:20
近年來,光催化裂解水產(chǎn)氫(H2)引起了廣泛的關(guān)注.儲量豐富,環(huán)境友好的非金屬無機半導(dǎo)體β-SiC(立方相碳化硅)具有適當(dāng)?shù)膸?Eg=2.4 eV, ECB=-0.9 V),是一種潛在的光催化劑.受限于SiC光催化劑內(nèi)部光生電子-空穴對的快速復(fù)合, SiC光催化劑的效率較低.已有的關(guān)于SiC光催化劑改性的報道主要包括構(gòu)建納米SiC,構(gòu)建SiC異質(zhì)結(jié),構(gòu)建碳/SiC材料雜化材料.進一步的研究表明, SiC與碳材料之間通過緊密的界面接觸形成了肖特基結(jié),能將SiC表面的光生電子快速轉(zhuǎn)移,抑制光生電子-空穴對的快速復(fù)合,從而提高光催化分解水產(chǎn)氫的活性.另一方面,碳納米管(CNTs)具有良好的電子導(dǎo)電性,一維有序的管腔所形成的電子快速傳導(dǎo)路徑.因此,將半導(dǎo)體光催化劑與CNTs復(fù)合,是一種制備先進的光催化劑的有效策略.本文利用Si蒸氣與CNTs之間的氣-固反應(yīng),在CNTs表面原位生長SiC納米包覆層,成功地制備了一維同軸核-殼CNTs@SiC納米管.高分辨率透射電子顯微鏡圖像表明, SiC與CNTs之間是通過Si-C共價鍵原子接觸,并得到X射線光電子能譜...
【文章來源】:Chinese Journal of Catalysis. 2020,41(01)北大核心EISCICSCD
【文章頁數(shù)】:10 頁
【文章目錄】:
1. Introduction
2. Experimental
2.1. Material synthesis
2.2. Characterization
2.3. Photoelectrochemical measurements
2.4. PC water splitting
3. Results and discussion
3.1. Structure and composition of the photocatalysts
3.2. Optical properties and photoelectricities of the photocatalysts
3.3. PC activities of the photocatalysts
3.4. Discussion of the mechanism
4. Conclusions
本文編號:3493911
【文章來源】:Chinese Journal of Catalysis. 2020,41(01)北大核心EISCICSCD
【文章頁數(shù)】:10 頁
【文章目錄】:
1. Introduction
2. Experimental
2.1. Material synthesis
2.2. Characterization
2.3. Photoelectrochemical measurements
2.4. PC water splitting
3. Results and discussion
3.1. Structure and composition of the photocatalysts
3.2. Optical properties and photoelectricities of the photocatalysts
3.3. PC activities of the photocatalysts
3.4. Discussion of the mechanism
4. Conclusions
本文編號:3493911
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