Journal of Inorganic Materials, Volume. 39, Issue 2, 115(2023)
Figures & Tables(16)
![Preparation of graphene nanoribbons by photolithographic plasma etching technique[13]](/Images/icon/loading.gif){kind=icon}
1. Preparation of graphene nanoribbons by photolithographic plasma etching technique[13]
4. Schematic illustration of scanning probe microscopy (SPM) technique for cutting graphene nanosheets[11]
6. Pd single-atom modification by selectively trimming the Pd atoms on the PCN surface using chemical scissors[23]
7. N atomic vacancy modification of g-C3N4 realized by cutting of H2 chemical scissor[24]
8. Mg/Zn/CO2 scissors rationally tailoring the carbon nanomaterials[25]
10. Schematic representation of structural conversion using dppm as chemical scissor[60]
11. Two-dimensional MOF materials synthesized by proton concentration modulation with chemical scissor effect[30]
12. Schematic illustrations of different etching methods for preparation of MXene
13. Chemical-scissors assisted structural editing strategy for layered transition metal carbides/nitrides[10]
14. Lewis-acidic-melt method for the preparation of MAX phases and MXenes
15. Chemical scissor-assisted atomic intercalation of transition metal dichalcogenides[38]
Table 1. Chemical mechanism of typical "chemical scissors" and applications in structural editing
View tableView in ArticleTable 1. Chemical mechanism of typical "chemical scissors" and applications in structural editing
Regulation mechanism Chemical scissor Chemical mechanism Target Potential applications Ref. Chemical cutting Plasma Collision and reaction of plasma on graphene surface Graphene Electronic engineering [ 13 ,16 ]O2/NH3 Oxidation of edge carbon atoms Graphene Electronic engineering [ 17 ]Metal nanoparticles Catalytic hydrogenation of carbon atoms Graphene Electronic engineering [ 18 -19 ]TiO2 photocatalysis Photoinduced oxidation of carbon atoms by highly active OH radicals Graphene Electronic engineering [ 12 ]HNO3/H2SO4/KClO3 Thermal expansion caused by oxidation and decomposition of surface functional groups of graphite Graphite Energy storage [ 20 ]NH3/H2O2 Oxidation of carbon atoms g-C3N4 Catalysis, Sensor [ 21 ]HNO3/H2SO4 Oxidation of carbon atoms g-C3N4 Catalysis, Sensor [ 22 ]Chemical modification FeCl3 Oxidation of Pd atoms Pd clusters Catalysis, Sensor [ 23 ]H2 Hydrogenation of N atoms g-C3N4 Catalysis, Sensor [ 24 ]CO2 Oxidation of carbon atoms Carbon materials Energy storage [ 25 ]Chemical synthesis C2H5OH The breaking of organic bonds results in the dissolution of organic substances 3-aminophenol formaldehyde resin Catalysis [ 14 ]Acetone The breaking of organic bonds results in the dissolution of organic substances 3-aminophenol formaldehyde resin Catalysis, energy storage [ 26 -27 ]Lone pair cations and halogen ions Control of coordination environments Sb2ZnO3Cl2 Sb16Cd8O25Cl14 Te6O11Cl2 Sb4O5Cl2 Catalysis, energy storage [ 15 ,28 -29 ]H+ Control of reaction dynamics Metal-benzene hexethiol (BHT) coordination polymer Catalysis [ 30 ]Chemical etching and intercalation Lewis acidic melts (CuCl2, ZnCl2) Oxidation of A-site atoms in MAX phases MAX phases Catalysis, energy storage, electronic engineering [ 10 ,31 -35 ]HF, HCl/LiF Acidic dissolution of A-site atoms in MAX phases MAX phases Catalysis, energy storage [ 36 -37 ]Metal atoms (Mn, Fe, Co, Ni,Cu, Ag) Regulating electronic structure by injecting electrons into host materials Transition metal chalcogenides Catalysis, energy storage [ 38 ]
Tools
Get Citation
Copy Citation Text
Haoming DING, Ke CHEN, Mian LI, Youbing LI, Zhifang CHAI, Qing HUANG.
Paper Information
Category:
Received: Nov. 10, 2023
Accepted: --
Published Online: Jul. 8, 2024
The Author Email: Qing HUANG (huangqing@nimte.ac.cn)
© Copyright 2018-2021 | Chinese Laser Press.
All Rights Reserved 沪ICP备15018463号-20