최소 단어 이상 선택하여야 합니다.
최대 10 단어까지만 선택 가능합니다.
다음과 같은 기능을 한번의 로그인으로 사용 할 수 있습니다.
NTIS 바로가기전기화학회지 = Journal of the Korean Electrochemical Society, v.25 no.4, 2022년, pp.162 - 173
이혁진 (공주대학교 화학교육과) , 봉성율 (공주대학교 화학교육과)
The development of new materials is an essential key for unraveling the environmental and energy problems all over the world. Among the various application materials in this area, crystalline and two-dimensional carbon materials have been studied from points of view such as electrical conductivity, ...
X. Tang, S. Lv, K. Jiang, G. Zhou, and X. Liu, Recent development of ionic liquid-based electrolytes in lithiumion batteries, J. Power Sources, 542, 231792 (2022).
X. Jiang, Y. Chen, X. Meng, W. Cao, C. Liu, Q. Huang, N. Naik, V. Murugadoss, M. Huang, and Z. Guo, The impact of electrode with carbon materials on safety performance of lithium-ion batteries: A review, Carbon, 191, 448-470 (2022).
C. Huang, Y. Li, N. Wang, Y. Xue, Z. Zuo, H. Liu, and Y. Li, Progress in research into 2D graphdiyne-based materials, Chem. Rev., 118, 7744-7803 (2018).
M. Inagaki and F. Kang, Graphene derivatives: graphane, fluorographene, graphene oxide, graphyne and graphdiyne, J. Mater. Chem. A, 2, 13193-13206 (2014).
A. Razaq, F. Bibi, X. Zheng, R. Papadakis, S. H. M. Jafri, and H. Li, Review on graphene-, graphene oxide-, reduced graphene oxide-based flexible composites: From fabrication to applications, Materials, 15, 1012 (2022).
M. S. A. Bhuyan, M. N. Uddin, M. M. Islam, F. A. Bipasha, and S. S. Hossain, Synthesis of graphene, Int. Nano Lett., 6, 65-83 (2016).
X. Lu, M. Yu, H. Huang, and R. S. Ruoff, Tailoring graphite with the goal of achieving single sheets, Nanotechnology, 10, 269 (1999).
Y. Zhang, J. P. Small, W. V. Pontius, and P. Kim, Fabrication and electric-field-dependent transport measurements of mesoscopic graphite devices, Appl. Phys. Lett., 86, 073104 (2005).
A.M. Affoune, B.L.V. Prasad, H. Sato, T. Enoki, Y. Kaburagi, and Y. Hishiyama, Experimental evidence of a single nano-graphene, Chem. Phys. Lett., 348, 17-20 (2001).
S. Bong, Y.-R. Kim, I. Kim, S. Woo, S. Uhm, J. Lee, and H. Kim, Graphene supported electrocatalysts for methanol oxidation, Electrochem. Commun., 12, 129-131 (2010).
L. Sun, G. Yuan, L. Gao, J. Yang, M. Chhowalla, M. H. Gharahcheshmeh, K. K. Gleason, Y. S. Choi, B. H. Hong, and Z. Liu, Chemical vapour deposition, Nat. Rev. Methods Primer, 1, 5 (2021).
M. M. Haley, S. C. Brand, and J. J. Pak, Carbon networks based on dehydrobenzoannulenes: Synthesis of graphdiyne substructures, Angew. Chem. Int. Ed., 36(8), 836-838 (1997).
J. M. Kehoe, J. H. Kiley, J. J. English, C. A. Johnson, R. C. Petersen, and M. M. Haley, Carbon networks based on dehydrobenzoannulenes. 3. Synthesis of graphyne substructures1, Org. Lett., 2(7), 969-972 (2000).
W. B. Wan and M. M. Haley, Carbon networks based on dehydrobenzoannulenes. 4. Synthesis of "Star" and "Trefoil" graphdiyne substructures via sixfold crosscoupling of hexaiodobenzene, J. Org. Chem., 66(11), 3893-3901 (2001).
X. Li, B. Li, Y. He, and F. Kang, A review of graphynes: Properties, applications and synthesis, New Carbon Mater., 35, 619-629 (2020).
X. Gao, H. Liu, D. Wang, and J. Zhang, Graphdiyne: synthesis, properties, and applications, Chem. Soc. Rev., 48, 908-936 (2019).
J. Zhou, J. Li, Z. Liu, and J. Zhang, Exploring approaches for the synthesis of few-layered graphdiyne, Adv. Mater., 31, 1803758 (2019).
D. Malko, C. Neiss, F. Vines, and A. Gorling, Competition for graphene: Graphynes with directiondependent dirac cones, Phys. Rev. Lett., 108, 086804 (2012).
H. Wang, T. Maiyalagan, and X. Wang, Review on recent progress in nitrogen-doped graphene: Synthesis, characterization, and its potential applications, ACS Catal., 2, 781-794 (2012).
X. Li, D. Geng, Y. Zhang, X. Meng, R. Li, and X. Sun, Superior cycle stability of nitrogen-doped graphene nanosheets as anodes for lithium ion batteries, Electrochem. Commun., 13, 822-825 (2011).
S. H. Yang, S.-K. Park, and Y. C. Kang, Metal-organic frameworks derived FeSe 2 @C nanorods interconnected by N-doped graphene nanosheets as advanced anode materials for Na-ion batteries, Int. J. Energy Res., 45, 20909-20920 (2021).
S. Yu, B. Guo, T. Zeng, H. Qu, J. Yang, and J. Bai, Graphene-based lithium-ion battery anode materials manufactured by mechanochemical ball milling process: A review and perspective, Compos. Part B Eng., 246, 110232 (2022).
Z. Luo, S. Lim, Z. Tian, J. Shang, L. Lai, B. MacDonald, C. Fu, Z. Shen, T. Yu, and J. Lin, Pyridinic N doped graphene: synthesis, electronic structure, and electrocatalytic property, J. Mater. Chem., 21, 8038-8044 (2011).
D. Wei, Y. Liu, Y. Wang, H. Zhang, L. Huang, and G. Yu, Synthesis of N-doped graphene by chemical vapor deposition and its electrical properties, Nano Lett., 9, 1752-1758 (2009).
A. L. M. Reddy, A. Srivastava, S. R. Gowda, H. Gullapalli, M. Dubey, and P. M. Ajayan, Synthesis of nitrogen-doped graphene films for lithium battery application, ACS Nano, 4, 6337-6342 (2010).
S. M. Shinde, E. Kano, G. Kalita, M. Takeguchi, A. Hashimoto, and M. Tanemura, Grain structures of nitrogen-doped graphene synthesized by solid source-based chemical vapor deposition, Carbon, 96, 448-453 (2016).
M. Son, S.-S. Chee, S.-Y. Kim, W. Lee, Y. H. Kim, B.-Y. Oh, J. Y. Hwang, B. H. Lee, and M.- H. Ham, High-quality nitrogen-doped graphene films synthesized from pyridine via two-step chemical vapor deposition, Carbon, 159, 579-585 (2020).
J. Xu, G. Dong, C. Jin, M. Huang, and L. Guan, Sulfur and nitrogen Co-doped, few-layered graphene oxide as a highly efficient electrocatalyst for the oxygen-reduction reaction, ChemSusChem, 6, 493-499 (2013).
F. Hassani, H. Tavakol, F. Keshavarzipour, and A. Javaheri, A simple synthesis of sulfur-doped graphene using sulfur powder by chemical vapor deposition, RSC Adv., 6, 27158-27163 (2016).
J. Zhou, Z. Wang, Y. Chen, J. Liu, B. Zheng, W. Zhang, and Y. Li, Growth and properties of largearea sulfur-doped graphene films, J. Mater. Chem. C, 5, 7944-7949 (2017).
L. Ci, L. Song, C. Jin, D. Jariwala, D. Wu, Y. Li, A. Srivastava, Z. F. Wang, K. Sorr, L. Balicas, F. Liu, and P. M. Ajayan, Atomic layers of hybridized boron nitride and graphene domains, Nat. Mater., 9, 430-435 (2010).
T. Wu, H. Shen, L. Sun, B. Cheng, B. Liu, and J. Shen, Nitrogen and boron doped monolayer graphene by chemical vapor deposition using polystyrene, urea and boric acid, New J. Chem., 36, 1385-1391 (2012).
Z. Zhai, H. Shen, J. Chen, X. Li, and Y. Li, Metal-free synthesis of boron-doped graphene glass by hot-filament chemical vapor deposition for wave energy harvesting, ACS Appl. Mater. Interfaces, 12(2), 2805-2815 (2020).
H. Kim, O. Renault, A. Tyurnina, J.-P. Simonato, D. Rouchon, and D. Mariolle, Doping efficiency of single and randomly stacked bilayer graphene by iodine adsorption, Appl. Phys. Lett., 105, 011605 (2014).
Z.-S. Wu, W. Ren, L. Xu, F. Li, and H.-M. Cheng, Doped graphene sheets as anode materials with superhigh rate and large capacity for lithium ion batteries, ACS Nano, 5, 5463-5471 (2011).
G. H. Jun, S. H. Jin, B. Lee, B. H. Kim, W.-S. Chae, S. H. Hong, and S. Jeon, Enhanced conduction and charge-selectivity by N-doped graphene flakes in the active layer of bulkheterojunction organic solar cells, Energy Environ. Sci., 6, 3000-3006 (2013).
Z.-H. Sheng, L. Shao, J.-J. Cen, W.-J. Bao, F.-B. Wang, and X.-H. Xia, Catalyst-free synthesis of nitrogen-doped graphene via thermal annealing graphite oxide with melamine and its excellent electrocatalysis, ACS Nano, 5, 4350-4358 (2011).
X. Wang, X. Li, L. Zhang, Y. Yoon, P. K. Weber, H. Wang, J. Guo, and H. Dai, N-doping of graphene through electrothermal reactions with ammonia, Science, 324, 768-771 (2009).
S. Yang, L. Zhi, K. Tang, X. Feng, J. Maier, and K. Mullen, Efficient synthesis of heteroatom (N or S)-doped graphene based on ultrathin graphene oxide-porous silica sheets for oxygen reduction reactions, Adv. Funct. Mater., 22, 3634-3640 (2012).
H. M. Jeong, J. W. Lee, W. H. Shin, Y. J. Choi, H. J. Shin, J. K. Kang, and J. W. Choi, Nitrogendoped graphene for high-performance ultracapacitors and the importance of nitrogen-doped sites at basal planes, Nano Lett., 11, 2472-2477 (2011).
Y. Shao, S. Zhang, M. H. Engelhard, G. Li, G. Shao, Y. Wang, J. Liu, I. A. Aksay, and Y. Lin, Nitrogen-doped graphene and its electrochemical applications, J. Mater. Chem., 20, 7491-7496 (2010).
Y. Wang, F. Yu, M. Zhu, C. Ma, D. Zhao, C. Wang, A. Zhou, B. Dai, J. Ji, and X. Guo, Ndoping of plasma exfoliated graphene oxide via dielectric barrier discharge plasma treatment for the oxygen reduction reaction, J. Mater. Chem. A, 6, 2011-2017 (2018).
S. Li, Z. Wang, H. Jiang, L. Zhang, J. Ren, M. Zheng, L. Dong, and L. Sun, Plasma-induced highly efficient synthesis of boron doped reduced graphene oxide for supercapacitors, Chem. Commun., 52, 10988-10991 (2016).
V. K. Abdelkader-Fernandez, M. Domingo-Garcia, F. J. Lopez-Garzon, D. M. Fernandes, C. Freire, M. D. L. Torre, M. Melguizo, M. L. Godino-Salido, and M. Perez-Mendoza, Expanding graphene properties by a simple S-doping methodology based on cold CS 2 plasma, Carbon, 144, 269-279 (2019).
J. Guo, W. Wang, Y. Li, J. Liang, Q. Zhu, J. Li, and X. Wang, Room-temperature synthesis of waterdispersible sulfur-doped reduced graphene oxide without stabilizers, RSC Adv., 10, 26460-26466 (2020).
D. W. Chang, H.-J. Choi, and J.-B. Baek, Wetchemical nitrogen-doping of graphene nanoplatelets as electrocatalysts for the oxygen reduction reaction, J. Mater. Chem. A, 3, 7659-7665 (2015).
P. Wu, Z. Cai, Y. Gao, H. Zhang, and C. Cai, Enhancing the electrochemical reduction of hydrogen peroxide based on nitrogen-doped graphene for measurement of its releasing process from living cells, Chem. Commun., 47, 11327-11329 (2011).
L. Sun, L. Wang, C. Tian, T. Tan, Y. Xie, K. Shi, M. Li, and H. Fu, Nitrogen-doped graphene with high nitrogen level via a one-step hydrothermal reaction of graphene oxide with urea for superior capacitive energy storage, RSC Adv., 2, 4498-4506 (2012).
Y. Su, Y. Zhang, X. Zhuang, S. Li, D. Wu, F. Zhang, and X. Feng, Low-temperature synthesis of nitrogen/sulfur co-doped three-dimensional graphene frameworks as efficient metal-free electrocatalyst for oxygen reduction reaction, Carbon, 62, 296-301 (2013).
N. Li, Z. Wang, K. Zhao, Z. Shi, Z. Gu, and S. Xu, Large scale synthesis of N-doped multi-layered graphene sheets by simple arc-discharge method, Carbon, 48(1), 255-259 (2010).
Y. Zhou, N. Wang, J. Muhammad, D. Wang, Y. Duan, X. Zhang, X. Dong, and Z. Zhang, Graphene nanoflakes with optimized nitrogen doping fabricated by arc discharge as highly efficient absorbers toward microwave absorption, Carbon, 148, 204-213 (2019).
L. S. Panchakarla, K. S. Subrahmanyam, S. K. Saha, A. Govindaraj, H. R. Krishnamurthy, U. V. Waghmare, and C. N. R. Rao, Synthesis, structure, and properties of boron- and nitrogen-doped graphene, Adv. Mater., 21(46), 4726-4730 (2009).
T. V. Pham, J.-G. Kim, J. Y. Jung, J. H. Kim, H. Cho, T. H. Seo, H. Lee, N. D. Kim, and M. J. Kim, High areal capacitance of N-doped graphene synthesized by arc discharge, Adv. Funct. Mater., 29(48), 1905511 (2019).
C. Liu, X. Liu, J. Tan, Q. Wang, H. Wen, and C. Zhang, Nitrogen-doped graphene by all-solid-state ball-milling graphite with urea as a high-power lithium ion battery anode, J. Power Sources, 342, 157-164 (2017).
I.-Y. Jeon, S. Zhang, L. Zhang, H.-J. Choi, J.-M. Seo, Z. Xia, L. Dai, and J.-B. Baek, Edgeselectively sulfurized graphene nanoplatelets as efficient metal-free electrocatalysts for oxygen reduction reaction: The electron spin effect, Adv. Mater., 25(42), 6138-6145 (2013).
H. N. Tien and S. H. Hur, Synthesis of highly durable sulfur doped graphite nanoplatelet electrocatalyst by a fast and simple wet ball milling process, Mater. Lett., 161, 399-403 (2015).
J. Xu, J. Shui, J. Wang, M. Wang, H.-K. Liu, S. X. Dou, I.-Y. Jeon, J.-M. Seo, J.-B. Baek, and L. Dai, Sulfur-graphene nanostructured cathodes via ball-milling for high-performance lithium-sulfur batteries, ACS Nano, 8, 10920-10930 (2014).
J. Xu, I.-Y. Jeon, J.-M. Seo, S. Dou, L. Dai, and J.-B. Baek, Edge-selectively halogenated graphene nanoplatelets (XGnPs, X Cl, Br, or I) prepared by ball-milling and used as anode materials for lithium-ion batteries, Adv. Mater., 26(43), 7317-7323 (2014).
X. Meng, C. Yu, X. Song, J. Iocozzia, J. Hong, M. Rager, H. Jin, S. Wang, L. Huang, J. Qiu, and Z. Lin, Scrutinizing defects and defect density of selenium-doped graphene for high-efficiency triiodide reduction in dye-sensitized solar cells, Angew. Chem., 130, 4772-4776 (2018).
J. Ma, Y. Yuan, S. Wu, J. Y. Lee, and B. Kang, γ-Graphyne nanotubes as promising lithium-ion battery anodes, Appl. Surf. Sci., 531, 147343 (2020).
Q. Zhang, C. Tang, W. Zhu, and C. Cheng, Strainenhanced Li storage and diffusion on the graphyne as the anode material in the Li-ion battery, J. Phys. Chem. C, 122(40), 22838-22848 (2018).
B. Wu, X. Jia, Y. Wang, J. Hu,E. Gao, Z. Liu, Superflexible C68-graphyne as a promising anode material for lithium-ion batteries, J. Mater. Chem A, 7, 17357-17365 (2019).
X. Liu, S. M. Cho, S. Lin, Z. Chen, W. Choi, Y.-M. Kim, E. Yun, E. H. Baek, D. H. Ryu, and H. Lee, Constructing two-dimensional holey graphyne with unusual annulative π-extension, Matter, 5(7), 2306-2318 (2022)
*원문 PDF 파일 및 링크정보가 존재하지 않을 경우 KISTI DDS 시스템에서 제공하는 원문복사서비스를 사용할 수 있습니다.
출판사/학술단체 등이 한시적으로 특별한 프로모션 또는 일정기간 경과 후 접근을 허용하여, 출판사/학술단체 등의 사이트에서 이용 가능한 논문
※ AI-Helper는 부적절한 답변을 할 수 있습니다.