Photothermal Effect- and Interfacial Chemical Bond-Modulated NiOx/Ta3N5 Heterojunction for Efficient CO2 Photoreduction

Pei, Lang; Wang, Xusheng; Zhu, Heng; Yu, He; Bandaru, Sateesh; Yan, Shicheng; Zou, Zhigang

doi:10.1021/acsami.3c13538

ACS Appl. Mater. Interfaces

2023

DOI: 10.1021/acsami.3c13538

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Photothermal Effect- and Interfacial Chemical Bond-Modulated NiO_x/Ta₃N₅ Heterojunction for Efficient CO₂ Photoreduction

Lang Pei,

Xusheng Wang,

Heng Zhu

et al.

Abstract: Photothermal catalysis, which combines light promotion and thermal activation, is a promising approach for converting CO 2 into fuels. However, the development of photothermal catalysts with effective light-to-heat conversion, strong charge transfer ability, and suitable active sites remains a challenge. Herein, the photothermal effect-and interfacial N−Ni/ Ta−O bond-modulated heterostructure composed of oxygen vacancy-rich NiO x and Ta 3 N 5 was rationally fabricated for efficient photothermal catalytic CO 2 … Show more

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Cited by 7 publications

References 40 publications

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Constructing Robust Interfacial Chemical Bond Enhanced Charge Transfer in S‐Scheme 3D/2D Heterojunction for CO₂ Photoreduction

Feng,

Gong,

Fan

et al. 2024

Adv Funct Materials

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A stable ZnTe@Cs3Sb2I9 catalyst with 3D/2D‐hollow‐composite structure is constructed for CO2 photocatalytic reduction via the in situ growth of Cs3Sb2I9 nanosheets on hollow ZnTe microspheres using lattice matching. The formed Tellurium‐Antimony (Te─Sb) bonds improved the poor contact at the heterojunction interface, effectively promoted charge separation, and successfully suppressed photocorrosion. The unique core‐shell structure not only strengthens light absorption but also improves CO2 adsorption capacity. Consequently, the S‐scheme heterojunction with the synergistic effect of chemical bonds and 3D/2D‐hollow‐composite structure significantly enhances photocatalytic performance. The ZnTe@Cs3Sb2I9 photocatalyst offers a CO selectivity of 90.5%, which is higher than that of pure ZnTe (22.9%) and Cs3Sb2I9 (56.9%). This structure holds great promise for practical applications in CO2 photocatalytic reduction.

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Constructing Robust Interfacial Chemical Bond Enhanced Charge Transfer in S‐Scheme 3D/2D Heterojunction for CO₂ Photoreduction

Feng,

Gong,

Fan

et al. 2024

Adv Funct Materials

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Enhancing Atmospheric Water Harvesting of MIL‐101 (Cr) MOF Sorbent with Rapid Desorption Enabled by Ni─Ni₃S₂ Photothermal Bridge

Chen,

Liu,

et al. 2024

Adv Funct Materials

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Metal–organic frameworks (MOFs) have emerged as leading candidates for atmospheric water harvesting (AWH). Despite their high water uptake capacity, challenges persist in effective solar‐driven desorption for water collection. Addressing this, a photothermal bridge is introduced by in situ growth of Ni₃S₂ coating on a thermally conductive nickel mesh, enhancing heat transfer to the MOF and accelerating desorption kinetics. MIL‐101 (Cr) MOF in bulk form (BMOF) is bonded to the lightweight Ni─Ni3S2 mesh using adhesive, forming a dual‐layer Ni─Ni₃S₂ mesh/BMOF assembly. This hybrid retains a high water uptake of ≈0.63 g g⁻¹ at 60% relative humidity (RH) with superior sorption kinetics. Photothermally driven heat transfer from Ni─Ni₃S₂ to BMOF achieves complete water desorption within 40 min under 1 kW m−2. Compared to other configurations like foil, granules, and foam, the mesh‐based hybrid has the highest single‐cycle adsorption–desorption kinetic of 3.18 × 10⁻3 g g⁻¹ min⁻¹. Additionally, the hybrid demonstrates exceptional hydrothermal stability over 50 cycles and maintains morphological stability with airflow, ensuring consistent performance. Heat transfer simulations confirm the thermal distribution across the Ni─Ni₃S₂ mesh/BMOF, corroborating the rapid and uniform desorption. This approach paves the way for efficient AWH in high‐RH, water‐scarce regions by enhancing desorption kinetics through solar energy.

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Photothermal-boosted S-scheme heterojunction of α-Fe2O3@NiOx for high-selective reduction of CO2 to CO

Liu,

Kaihui,

Nie

et al. 2024

Applied Surface Science

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Photothermal Effect- and Interfacial Chemical Bond-Modulated NiO_x/Ta₃N₅ Heterojunction for Efficient CO₂ Photoreduction

Cited by 7 publications

References 40 publications

Constructing Robust Interfacial Chemical Bond Enhanced Charge Transfer in S‐Scheme 3D/2D Heterojunction for CO₂ Photoreduction

Constructing Robust Interfacial Chemical Bond Enhanced Charge Transfer in S‐Scheme 3D/2D Heterojunction for CO₂ Photoreduction

Enhancing Atmospheric Water Harvesting of MIL‐101 (Cr) MOF Sorbent with Rapid Desorption Enabled by Ni─Ni₃S₂ Photothermal Bridge

Photothermal-boosted S-scheme heterojunction of α-Fe2O3@NiOx for high-selective reduction of CO2 to CO

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Photothermal Effect- and Interfacial Chemical Bond-Modulated NiOx/Ta3N5 Heterojunction for Efficient CO2 Photoreduction

Cited by 7 publications

References 40 publications

Constructing Robust Interfacial Chemical Bond Enhanced Charge Transfer in S‐Scheme 3D/2D Heterojunction for CO2 Photoreduction

Constructing Robust Interfacial Chemical Bond Enhanced Charge Transfer in S‐Scheme 3D/2D Heterojunction for CO2 Photoreduction

Enhancing Atmospheric Water Harvesting of MIL‐101 (Cr) MOF Sorbent with Rapid Desorption Enabled by Ni─Ni3S2 Photothermal Bridge

Photothermal-boosted S-scheme heterojunction of α-Fe2O3@NiOx for high-selective reduction of CO2 to CO

Contact Info

Product

Resources

About

Photothermal Effect- and Interfacial Chemical Bond-Modulated NiO_x/Ta₃N₅ Heterojunction for Efficient CO₂ Photoreduction

Constructing Robust Interfacial Chemical Bond Enhanced Charge Transfer in S‐Scheme 3D/2D Heterojunction for CO₂ Photoreduction

Constructing Robust Interfacial Chemical Bond Enhanced Charge Transfer in S‐Scheme 3D/2D Heterojunction for CO₂ Photoreduction

Enhancing Atmospheric Water Harvesting of MIL‐101 (Cr) MOF Sorbent with Rapid Desorption Enabled by Ni─Ni₃S₂ Photothermal Bridge