Thermoelectric materials and their devices can realize the solid-state energy conversion between thermal and electrical energy, therefore serving as a promising alternative to conventional fossil fuels for energy supply. As...

Advances in Ag2Se-based thermoelectrics from materials to applications

Abstract Photocatalytic conversion of CO 2 to high-value products plays a crucial role in the global pursuit of carbon–neutral economy. Junction photocatalysts, such as the isotype heterojunctions, offer an ideal paradigm to navigate the photocatalytic CO 2 reduction reaction (CRR). Herein, we elucidate the behaviors of isotype heterojunctions toward photocatalytic CRR over a representative photocatalyst, g-C 3 N 4 . Impressively, the isotype heterojunctions possess a significantly higher efficiency for the spatial separation and transfer of photogenerated carriers than the single components. Along with the intrinsically outstanding stability, the isotype heterojunctions exhibit an exceptional and stable activity toward the CO 2 photoreduction to CO. More importantly, by combining quantitative in situ technique with the first-principles modeling, we elucidate that the enhanced photoinduced charge dynamics promotes the production of key intermediates and thus the whole reaction kinetics. 

/pdf/isotype-heterojunction-boosted-co2-photoreduction-to-co-2o4yo7lt.pdf

Isotype Heterojunction-Boosted CO2 Photoreduction to CO

With rising CO2 emissions caused by the massive consumption of fossil fuels, it is highly desirable to develop strategies that adopt renewable energy to convert CO2 into value‐added chemical feedstocks. Over the past decades, photocatalytic reduction of CO2 using light energy has attracted considerable attention. However, the advanced photocatalysis techniques cannot exert their action where light is unavailable. Here, a method for CO2 reduction on basis of vibration‐driven piezoelectricity to yield a piezo‐electrocatalysis effect which requires mechanical vibration rather than light, is proposed. Under mild vibration and sacrificial agent‐free conditions, the piezoelectric BaTiO3 catalyst provides a suitable piezo‐potential to overcome the redox potential of CO2 and convert it into CO with a maximum yield of 63.3 µmol g−1, achieving a reactivity comparable to those of photocatalysts. The piezo‐electrocatalytic CO2 reduction reaction adds a new avenue in addition to the existing photocatalytic techniques by expanding the scope of energy utilization to promote carbon neutrality.

Piezo‐Electrocatalysis for CO2 Reduction Driven by Vibration

Effect of oxygen vacancies on the photocatalytic activity of flower-like BiOBr microspheres towards NO oxidation and CO2 reduction

Photothermal functional material and structure for photothermal catalytic CO2 reduction: Recent advance, application and prospect

Facet junction of BiOBr nanosheets boosting spatial charge separation for CO2 photoreduction

Constructing n-type Ag2Se/CNTs composites toward synergistically enhanced thermoelectric and mechanical performance

Constructing n-Type Ag2Se/CNTs Composites Toward Synergistically Enhanced Thermoelectric and Mechanical Performance

Achieving high average power factor in tetrahedrite Cu12Sb4S13 via regulating electron-phonon coupling strength

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Papers

Facet junction of BiOBr nanosheets boosting spatial charge separation for CO2 photoreduction

Constructing n-type Ag2Se/CNTs composites toward synergistically enhanced thermoelectric and mechanical performance

Facet junction of BiOBr nanosheets boosting spatial charge separation for CO2 photoreduction

Constructing n-Type Ag2Se/CNTs Composites Toward Synergistically Enhanced Thermoelectric and Mechanical Performance

Achieving high average power factor in tetrahedrite Cu12Sb4S13 via regulating electron-phonon coupling strength