Hydrophilic Amino Groups Acted in the Hydrophobic Reaction Environment for Efficient Hydrogen Isotopes Enrichment

Xu, Yongsheng; Feng, Xin; Yin, Xiaohong

doi:10.1021/acsami.2c20446

ACS Appl. Mater. Interfaces

2023

DOI: 10.1021/acsami.2c20446

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Hydrophilic Amino Groups Acted in the Hydrophobic Reaction Environment for Efficient Hydrogen Isotopes Enrichment

Yongsheng Xu

Xin Feng

Xiaohong Yin

Abstract: Hydrogen isotope enrichment through liquid-phase catalytic exchange (LPCE) technology is achieved in a hydrophobic reaction environment to avoid liquid water poisoning, but the usage of hydrophobic support severely inhibits the internal diffusion of water molecules to decrease the catalytic efficiency. Herein, we encapsulate platinum active sites into a metal organic framework (Pt@NH 2 −UiO-66) as the efficient catalyst for LPCE via introducing hydrophilic amino groups. Experiments and density functional theor… Show more

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Cited by 2 publications

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Lithium Fluoride Enhanced Platinum Catalytic Exchange of Hydrogen Isotopes by High Hydrogen Adsorption at Low Temperature

Liu,

Xu,

Ren

et al. 2024

ChemNanoMat

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The catalytic exchange of hydrogen isotopes is a promising technology for purifying recycled water in nuclear power stations. However, it remains a challenge for achieving high catalytic efficiency and stability at low temperatures. In this work, we propose a facile strategy to enhance the catalyst efficiency by introducing LiF in the Pt/Ti3AlC2 (Pt‐5‐LiF/Ti3AlC2). The incorporation of LiF significantly achieves high catalytic exchange efficiency of 92% and a turnover frequency of 28.1 h‐1, which are more than twice that of Pt/Ti3AlC2. The structure‐activity relationship analysis reveals that the introduction of LiF substantially enhanced the hydrogen adsorption capacity of the catalyst and further improved the performance of the catalysts. Moreover, this LiF‐added strategy is also applicable to other Pt‐based catalysts such as Pt/Al2O3 and Pt/activated carbon. This work provides a novel catalyst design strategy for high‐efficiency catalytic exchange of hydrogen isotopes.

show abstract

Lithium Fluoride Enhanced Platinum Catalytic Exchange of Hydrogen Isotopes by High Hydrogen Adsorption at Low Temperature

Liu,

Xu,

Ren

et al. 2024

ChemNanoMat

View full text Add to dashboard Cite

show abstract

Triggering Ion Diffusion and Electron Transport Dual Pathways for High Efficiency Electrochemical Li⁺ Extraction

Zhan,

Qian,

Qiao

et al. 2024

ACS Nano

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Efficient electrochemical Li + adsorption holds significant promise for lithium extraction, while the mismatched rate between Li + diffusion and electron transport within the electrode material impedes the electrochemical activity and restricts the adsorption efficiency. To address this challenge, herein, we rationally design and integrate the ion and electron dual-conducting poly(vinyl alcohol)−polyaniline (PVA-PANI) copolymer (CP) within the H 1.6 Mn 1.6 O 4 (HMO) electrode matrix to facilitate Li + diffusion and electron transport. The Li + diffusion coefficient (D Li+ ) increased from 3.03 × 10 −10 to 5.92 × 10 −10 cm 2 /s, while the charge transfer resistance (R ct ) decreased from 53.73 to 29.57 ohm. Consequently, the HMO@CP electrode exhibits superior adsorption kinetics and a state-of-the-art high adsorption capacity of up to 49.48 mg/g. Comprehensive mechanistic studies reveal that the negatively charged hydroxyl groups (−OH) in PVA accelerate Li + diffusion and that the conjugated structure and redox-active quinoid sites in PANI offer denser electron distribution and promote electron transport. This synergistic effect in CP significantly enhanced Li + diffusion and electron transport, leading to electrochemical activity and adsorption efficiency. Our work highlights the critical role of simultaneously regulating the ion diffusion and electron transport dual pathways for optimizing Li + adsorption performance and inspires development of the next generation electrochemical adsorption electrodes.

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Hydrophilic Amino Groups Acted in the Hydrophobic Reaction Environment for Efficient Hydrogen Isotopes Enrichment

Cited by 2 publications

References 19 publications

Lithium Fluoride Enhanced Platinum Catalytic Exchange of Hydrogen Isotopes by High Hydrogen Adsorption at Low Temperature

Lithium Fluoride Enhanced Platinum Catalytic Exchange of Hydrogen Isotopes by High Hydrogen Adsorption at Low Temperature

Triggering Ion Diffusion and Electron Transport Dual Pathways for High Efficiency Electrochemical Li⁺ Extraction

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Hydrophilic Amino Groups Acted in the Hydrophobic Reaction Environment for Efficient Hydrogen Isotopes Enrichment

Cited by 2 publications

References 19 publications

Lithium Fluoride Enhanced Platinum Catalytic Exchange of Hydrogen Isotopes by High Hydrogen Adsorption at Low Temperature

Lithium Fluoride Enhanced Platinum Catalytic Exchange of Hydrogen Isotopes by High Hydrogen Adsorption at Low Temperature

Triggering Ion Diffusion and Electron Transport Dual Pathways for High Efficiency Electrochemical Li+ Extraction

Contact Info

Product

Resources

About

Triggering Ion Diffusion and Electron Transport Dual Pathways for High Efficiency Electrochemical Li⁺ Extraction