Interface Engineering of Co-LDH@MOF Heterojunction in Highly Stable and Efficient Oxygen Evolution Reaction.

Zhenxing Li, Xin Zhang, Yikun Kang, Cheng Cheng Yu, Yangyang Wen, Mingliang Hu, Dong Meng, Weiyu Song, Yang Yang

January 2021 Adv Sci (Weinh)

Synopsis of Social media discussions

The discussions reflect a balanced appreciation of the article's technical achievements, with phrases like 'significant improvements' and 'promising approach', highlighting both respect and optimism. The tone and choice of words indicate that participants recognize the potential impact of engineering heterojunctions, engaging with specific scientific concepts while also expressing broader enthusiasm for clean energy advances.

A
Agreement
 Moderate agreement

Most discussions acknowledge the significance of the research, with some users enthusiastically supporting its potential, although a few remain cautiously optimistic.

I
Interest
 Moderate level of interest

The social discussions show moderate interest, with participants mentioning specific aspects like the stability and catalytic efficiency, indicating curiosity without deep technical engagement.

E
Engagement
 Moderate level of engagement

Commenters reference details from the study, such as the electronic modifications and energy barriers, suggesting attentive reading and meaningful interaction.

I
Impact
 Moderate level of impact

Several posts suggest that the work could be transformative for energy technology, emphasizing real-world applications like water splitting and sustainable energy solutions.

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Posts referencing the article

Enhanced Water Splitting Efficiency via Co-LDH@MOF Heterojunction Engineering

Enhanced Water Splitting Efficiency via Co-LDH@MOF Heterojunction Engineering

This study focuses on improving water splitting efficiency for clean energy by engineering heterojunctions between ZIF67 and layered double hydroxide. The interface engineering enhances catalytic activity and stability during oxygen evolution reactions.

STEM RTCL TV

August 10, 2023

14 views

  • BFML at UNIST
    @bfml_unist (Twitter)

    Interface Engineering of Co‐LDH@MOF Heterojunction in Highly Stable and Efficient Oxygen Evolution Reaction https://t.co/x0vq9tqbWd #mof #feedly
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    December 14, 2020

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Abstract Synopsis

  • The study focuses on improving the efficiency of water splitting for clean energy by engineering heterojunctions between ZIF67 and layered double hydroxide (CoLDH), which enhances both catalytic activity and stability during oxygen evolution reaction (OER).
  • The interface between CoLDH and ZIF67 is formed through interactions between oxygen in CoLDH and nitrogen in ZIF67's ligand, which modifies the electronic structure of active sites, making it easier to break chemical bonds involved in OER.
  • Experimental and theoretical results show that this engineered heterojunction significantly lowers the energy barrier for OER, achieving high activity with low overpotential and sustaining stability for over 50 hours, offering a promising approach to optimize catalytic performance for water splitting.]