Controllable Crystallization of Two-Dimensional Bi Nanocrystals with Morphology-Boosted CO 2 Electroreduction in Wide pH Environments.
Li-Wei ChenYu-Chen HaoJiani LiLinyu HuXintao ZuoChunlong DaiZi-Long YuHui-Zi HuangWenjing TianDi LiuXiaoxue ChangPengfei LiRuiwen ShaoBo WangAn-Xiang YinPublished in: Small (Weinheim an der Bergstrasse, Germany) (2023)
Two-dimensional low-melting-point (LMP) metal nanocrystals are attracting increasing attention with broad and irreplaceable applications due to their unique surface and topological structures. However, the chemical synthesis, especially the fine control over the nucleation (reduction) and growth (crystallization), of such LMP metal nanocrystals remains elusive as limited by the challenges of low standard redox potential, low melting point, poor crystalline symmetry, etc. Here, a controllable reduction-melting-crystallization (RMC) protocol to synthesize free-standing and surfactant-free bismuth nanocrystals with tunable dimensions, morphologies, and surface structures is presented. Especially, ultrathin bismuth nanosheets with flat or jagged surfaces/edges can be prepared with high selectivity. The jagged bismuth nanosheets, with abundant surface steps and defects, exhibit boosted electrocatalytic CO 2 reduction performances in acidic, neutral, and alkaline aqueous solutions, achieving the maximum selectivity of near unity at the current density of 210 mA cm -2 for formate evolution under ambient conditions. This work creates the RMC pathway for the synthesis of free-standing two-dimensional LMP metal nanomaterials and may find broader applicability in more interdisciplinary applications.
Keyphrases
- high resolution
- room temperature
- epstein barr virus
- energy transfer
- visible light
- air pollution
- metal organic framework
- reduced graphene oxide
- quantum dots
- randomized controlled trial
- particulate matter
- mass spectrometry
- cystic fibrosis
- escherichia coli
- highly efficient
- staphylococcus aureus
- structural basis
- pseudomonas aeruginosa
- anaerobic digestion