材料科学
光催化
超快激光光谱学
化学工程
X射线光电子能谱
纳米笼
光化学
异质结
吸附
电子转移
催化作用
飞秒
化学物理
纳米技术
脱氢
超短脉冲
吸收光谱法
量子点
再分配(选举)
氧化还原
解吸
光谱学
碳纤维
吸收(声学)
表面电荷
电催化剂
载流子
化学
量子效率
纳米结构
能量转换
作者
Guoyang Gao,Yameng Zhang,Yulong An,Luwen Xu,Houjuan Qi,Liquan Jing,Jinguang Hu,Zhanhua Huang
标识
DOI:10.1021/acscatal.6c01547
摘要
Achieving photocatalytic conversion of CO 2 coupled with 5-hydroxymethylfurfural (HMF) represents a highly forward-looking endeavor under the carbon neutrality context. This work innovatively constructs ligand-modified CdS quantum dots (QDs)-anchored on ZnCoNi-LDH nanocages (CdS/ZnCoNi-LDH) through a ligand-mediated interlayer anion exchange strategy. This strategy is demonstrated to exhibit universality for synthesizing composites comprising diverse ligand-functionalized CdS QDs and ZnCoNi-LDH with tunable interlayer anions. The efficient S-scheme charge separation and transfer mechanism is confirmed through in situ X-ray photoelectron spectroscopy, Kelvin probe and theoretical analysis. At molecular/atomic levels, femtosecond transient absorption spectroscopy elucidates the ultrafast charge transfer behavior through ligand-mediated interfacial channels in the CdS/ZnCoNi-LDH S-scheme heterojunction. In the CO 2 reduction coupled with HMF oxidation system, CdS/ZnCoNi-LDH exhibits up to 16-fold and 41-fold enhancements in CO and 2,5-diformylfuran (DFF) yields, respectively, with selectivities exceeding 96% for CO and 93% for DFF. In situ experimental and theoretical results demonstrate that the redistribution of surface charges in CdS/ZnCoNi-LDH facilitates the adsorption of CO 2 and HMF molecules, while simultaneously lowering the energy barrier for *CO desorption and hydroxymethyl dehydrogenation in HMF. This study provides an insight for synergistic utilization of CO 2 and biomass valorization through engineered design of advanced S-scheme heterojunctions.
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