材料科学
不对称
密度泛函理论
光热治疗
化学物理
光电开关
工作(物理)
太阳能
热的
催化作用
光电子学
电荷(物理)
极化(电化学)
纳米技术
光化学
可再生能源
吸收(声学)
光热效应
光伏系统
还原(数学)
能量转换效率
化学能
电荷密度
分子物理学
碳纤维
太阳能燃料
电子结构
热能
太阳能电池
偶极子
原子物理学
光伏
储能
吸附
产量(工程)
作者
Wangquan Kang,Chengcheng Yuan,Chuanbiao Bie,Jiaguo Yu,L. Q. Wang,Liuyang Zhang
摘要
ABSTRACT The efficient utilization of solar energy to convert carbon dioxide into renewable fuels is a compelling strategy for mitigating carbon emissions and realizing sustainable chemical cycles. Herein, we report a Ni–modified oxygen–deficient TiO 2 (Ni/TiO 2‐x ) catalyst that achieves exceptionally high photothermal CO 2 reduction performance under simulated solar irradiation without external heating, reaching a remarkable total production yield of 278.3 mmol·g −1 ·h −1 . Structural and spectroscopic analyses reveal that the asymmetric Ni–V O –Ti interfacial configuration serves as a unique charge polarization center that redistributes charge density and stabilizes reaction intermediates under light–induced thermal excitation. This asymmetric coordination disrupts the electronic degeneracy of the Ti─O framework, thereby lowering the free energy barrier for the rate–determining step. Density functional theory (DFT) calculations further demonstrate that the asymmetric site acts as a dual–function photothermal antenna, where light absorption and heat localization cooperate to accelerate H 2 activation and C─O bond cleavage. This work unveils a paradigm in which geometric asymmetry governs both charge transfer and localized heat management, providing a molecular–level blueprint for next–generation photothermal catalysts for solar–driven CO 2 conversion.
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