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Journal articles on the topic 'Porous graphitic carbon'

Author: Grafiati
Published: 4 June 2021
Last updated: 15 February 2022

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1

Gadipelli, Srinivas, Zhuangnan Li, Tingting Zhao, Yuchen Yang, Taner Yildirim, and Zhengxiao Guo. "Graphitic nanostructures in a porous carbon framework significantly enhance electrocatalytic oxygen evolution." Journal of Materials Chemistry A 5, no. 47 (2017): 24686–94. http://dx.doi.org/10.1039/c7ta03027d.

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Hybrid carbons, nickel embedded nanographites in a nitrogen-doped porous carbon structure, developed by a simplified CVD fashion, utilizing a solid state precursor, zeolitic-imidazolate-framework, lead to highly enhanced water oxidation activity over simple graphitic or porous carbon based structures alone.
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2

Huo, Xiuqin, Huan Yi, Yukui Fu, et al. "Porous graphitic carbon nitride nanomaterials for water treatment." Environmental Science: Nano 8, no. 7 (2021): 1835–62. http://dx.doi.org/10.1039/d1en00171j.

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This review summarizes the application of porous g-C<sub>3</sub>N<sub>4</sub> in water treatment and modification to enhance its catalytic performance, showing the potential of porous g-C<sub>3</sub>N<sub>4</sub> for the actual treatment of water bodies.
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3

Lei, Wanwan, Sheng Liu, and Wen-Hua Zhang. "Porous hollow carbon nanofibers derived from multi-walled carbon nanotubes and sucrose as anode materials for lithium-ion batteries." RSC Advances 7, no. 1 (2017): 224–30. http://dx.doi.org/10.1039/c6ra24927b.

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Porous hollow carbon nanofibers exhibit tunable shell thicknesses from 2.5 to 13.5 nm. Overcoating of a thin, porous, and non-graphitic carbon layer on the pristine MWCNTs holds a great potential for enhancing their anode performance for LIBs.
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4

Fu, Xiaorui, Xiaofei Hu, Zhenhua Yan, et al. "Template-free synthesis of porous graphitic carbon nitride/carbon composite spheres for electrocatalytic oxygen reduction reaction." Chemical Communications 52, no. 8 (2016): 1725–28. http://dx.doi.org/10.1039/c5cc08897f.

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Porous graphitic carbon nitride/carbon composite spheres synthesized from glucose, melamine and cyanuric acid precursors via a template-free route efficiently catalyze the electrochemical oxygen reduction.
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5

Jung, Hyeyoung, Jihyeon Kang, Inho Nam, and Sunyoung Bae. "Graphitic Porous Carbon Derived from Waste Coffee Sludge for Energy Storage." Materials 13, no. 18 (2020): 3972. http://dx.doi.org/10.3390/ma13183972.

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Coffee is one of the largest agricultural products; however, the majority of the produced coffee is discarded as waste sludge by beverage manufacturers. Herein, we report the use of graphitic porous carbon materials that have been derived from waste coffee sludge for developing an energy storage electrode based on a hydrothermal recycling procedure. Waste coffee sludge is used as a carbonaceous precursor for energy storage due to its greater abundance, lower cost, and easier availability as compared to other carbon resources. The intrinsic fibrous structure of coffee sludge is based on cellulose and demonstrates enhanced ionic and electronic conductivities. The material is primarily composed of cellulose-based materials along with several heteroatoms; therefore, the waste sludge can be easily converted to functionalized carbon. The production of unique graphitic porous carbon by hydrothermal carbonization of coffee sludge is particularly attractive since it addresses waste handling issues, offers a cheaper recycling method, and reduces the requirement for landfills. Our investigations revealed that the graphitic porous carbon electrodes derived from coffee sludge provide a specific capacitance of 140 F g−1, with 97% retention of the charge storage capacity after 1500 cycles at current density of 0.3 A g−1.
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6

Chen, Qiang, Xiaofei Tan, Yunguo Liu, et al. "Biomass-derived porous graphitic carbon materials for energy and environmental applications." Journal of Materials Chemistry A 8, no. 12 (2020): 5773–811. http://dx.doi.org/10.1039/c9ta11618d.

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7

Li, Yang, Xin Li, Huaiwu Zhang, and Quanjun Xiang. "Porous graphitic carbon nitride for solar photocatalytic applications." Nanoscale Horizons 5, no. 5 (2020): 765–86. http://dx.doi.org/10.1039/d0nh00046a.

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This review summarizes the development of PCN, i.e., synthesis, morphology, modification, and application in recent years. This review can provide a comprehensive view of PCN and lay a foundation for the design of ideal photocatalysts in the future.
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8

Törnkvist, Anna, Karin E. Markides, and Leif Nyholm. "Chromatographic behaviour of oxidised porous graphitic carbon columns." Analyst 128, no. 7 (2003): 844–48. http://dx.doi.org/10.1039/b303076h.

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9

Liu, Qinglei, Jiajun Gu, Wang Zhang, Yoshinari Miyamoto, Zhixin Chen, and Di Zhang. "Biomorphic porous graphitic carbon for electromagnetic interference shielding." Journal of Materials Chemistry 22, no. 39 (2012): 21183. http://dx.doi.org/10.1039/c2jm34590k.

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10

Ganegoda, Hasitha, David S. Jensen, Daniel Olive, et al. "Photoemission studies of fluorine functionalized porous graphitic carbon." Journal of Applied Physics 111, no. 5 (2012): 053705. http://dx.doi.org/10.1063/1.3691888.

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11

Hoinkis, E. "Thermodesorption of deuterium from a porous graphitic carbon." Journal of Nuclear Materials 183, no. 1-2 (1991): 9–18. http://dx.doi.org/10.1016/0022-3115(91)90465-j.

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12

Gong, Youning, Delong Li, Chengzhi Luo, Qiang Fu, and Chunxu Pan. "Highly porous graphitic biomass carbon as advanced electrode materials for supercapacitors." Green Chemistry 19, no. 17 (2017): 4132–40. http://dx.doi.org/10.1039/c7gc01681f.

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13

Al-Haddad, Ameera. "Determination of Polychlorinated Biphenyls with Non-o-Chlorine Substituent in Aroclor Mixtures and in Soil Using Porous Graphitic Carbon Columns." Journal of AOAC INTERNATIONAL 77, no. 2 (1994): 437–41. http://dx.doi.org/10.1093/jaoac/77.2.437.

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Abstract Polychlorinated biphenyls (PCBs) with non-o-chlo-rine substituent were determined in several Aroclor mixtures and in PCB-contaminated soil samples. Non-o-CI substituted PCBs were isolated using porous graphitic carbon/liquid chromatographic columns. Columns of this type provide a simple, rapid, and efficient method for the isolation of these compounds from different types of sample matrixes. The average percent recovery of non-o-CI substituted PCBs from porous graphitic carbon columns was found to be 87%, with an average coefficient of variation of 3.1%.
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14

Balakumar, Vellaichamy, Ramalingam Manivannan, Chitiphon Chuaicham, Sekar Karthikeyan, and Keiko Sasaki. "A simple tactic synthesis of hollow porous graphitic carbon nitride with significantly enhanced photocatalytic performance." Chemical Communications 57, no. 55 (2021): 6772–75. http://dx.doi.org/10.1039/d1cc02355a.

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A simple tactic synthesis of hollow porous graphitic carbon nitride was demonstrated. The porous material exhibits increased light absorption, interfacial charge transfer and separation, in addition to a decrease in recombination tendency.
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15

Zhang, Xiaohua, Hengxiang Li, Bing Qin, et al. "Direct synthesis of porous graphitic carbon sheets grafted on carbon fibers for high-performance supercapacitors." Journal of Materials Chemistry A 7, no. 7 (2019): 3298–306. http://dx.doi.org/10.1039/c8ta11844b.

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16

Wang, Hui, Tingting Yan, Junjie Shen, Jianping Zhang, Liyi Shi, and Dengsong Zhang. "Efficient removal of metal ions by capacitive deionization with straw waste derived graphitic porous carbon nanosheets." Environmental Science: Nano 7, no. 1 (2020): 317–26. http://dx.doi.org/10.1039/c9en01233h.

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17

Kiciński, Wojciech, Małgorzata Norek, and Michał Bystrzejewski. "Monolithic porous graphitic carbons obtained through catalytic graphitization of carbon xerogels." Journal of Physics and Chemistry of Solids 74, no. 1 (2013): 101–9. http://dx.doi.org/10.1016/j.jpcs.2012.08.007.

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18

Xie, Rui-Lun, Zhi-Min Zong, Fang-Jing Liu, et al. "Nitrogen-doped porous carbon foams prepared from mesophase pitch through graphitic carbon nitride nanosheet templates." RSC Advances 5, no. 57 (2015): 45718–24. http://dx.doi.org/10.1039/c4ra14513e.

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A scalable and facile method was developed to synthesize nitrogen-doped porous carbon foams (NPCFs) using graphitic carbon nitride (g-C<sub>3</sub>N<sub>4</sub>) nanosheets as hard templates through the calcination of mesophase pitch.
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19

Duffy, E., X. He, E. P. Nesterenko, et al. "Thermally controlled growth of carbon onions within porous graphitic carbon-detonation nanodiamond monolithic composites." RSC Advances 5, no. 29 (2015): 22906–15. http://dx.doi.org/10.1039/c5ra00258c.

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20

Wang, Haoran, Shukai Yu, and Bin Xu. "Hierarchical porous carbon materials prepared using nano-ZnO as a template and activation agent for ultrahigh power supercapacitors." Chemical Communications 52, no. 77 (2016): 11512–15. http://dx.doi.org/10.1039/c6cc05911b.

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21

Chen, Bisang, Dejian Chen, Feiming Li, Xiaofeng Lin, and Qitong Huang. "Graphitic porous carbon: efficient synthesis by a combustion method and application as a highly selective biosensor." Journal of Materials Chemistry B 6, no. 46 (2018): 7684–91. http://dx.doi.org/10.1039/c8tb02139b.

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22

Qiu, Kaipei, and Zheng Xiao Guo. "Hierarchically porous graphene sheets and graphitic carbon nitride intercalated composites for enhanced oxygen reduction reaction." J. Mater. Chem. A 2, no. 9 (2014): 3209–15. http://dx.doi.org/10.1039/c3ta14158f.

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23

Liu, Bin, Bo Xu, Shenchang Li, Jinli Du, Zhiguo Liu, and Wenying Zhong. "Heptazine-based porous graphitic carbon nitride: a visible-light driven photocatalyst for water splitting." Journal of Materials Chemistry A 7, no. 36 (2019): 20799–805. http://dx.doi.org/10.1039/c9ta03646f.

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24

Jung, Chul-Ho, Jonghyun Choi, Won-Sik Kim, and Seong-Hyeon Hong. "A nanopore-embedded graphitic carbon shell on silicon anode for high performance lithium ion batteries." Journal of Materials Chemistry A 6, no. 17 (2018): 8013–20. http://dx.doi.org/10.1039/c8ta01471j.

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25

Yang, Inchan, Meenkyoung Jung, Myung-Soo Kim, Dalsu Choi, and Ji Chul Jung. "Physical and chemical activation mechanisms of carbon materials based on the microdomain model." Journal of Materials Chemistry A 9, no. 15 (2021): 9815–25. http://dx.doi.org/10.1039/d1ta00765c.

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Activation mechanisms of carbon materials are proposed. Physical activation proceeds via removal of the carbon surface. Chemical activation produces highly porous carbon and enhances the crystallinity due to the removal of the non-graphitic parts.
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26

Qi, Fulai, Zhangxun Xia, Ruili Sun, et al. "Graphitization induced by KOH etching for the fabrication of hierarchical porous graphitic carbon sheets for high performance supercapacitors." Journal of Materials Chemistry A 6, no. 29 (2018): 14170–77. http://dx.doi.org/10.1039/c8ta01186a.

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27

Merly, C., B. Lynch, P. Ross, and J. D. Glennon. "Selective ion chromatography of metals on porous graphitic carbon." Journal of Chromatography A 804, no. 1-2 (1998): 187–92. http://dx.doi.org/10.1016/s0021-9673(98)00095-8.

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28

Sevilla, Marta, and Antonio B. Fuertes. "Fabrication of porous carbon monoliths with a graphitic framework." Carbon 56 (May 2013): 155–66. http://dx.doi.org/10.1016/j.carbon.2012.12.090.

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29

Clarot, I., D. Cledat, L. Boulkanz, E. Assidjo, T. Chianea, and P. J. P. Cardot. "Elution Characteristics of Natural Cyclodextrins on Porous Graphitic Carbon." Journal of Chromatographic Science 38, no. 1 (2000): 38–45. http://dx.doi.org/10.1093/chromsci/38.1.38.

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30

Pang, Xin, Tong Zhou, Qinting Jiang, et al. "Porous Graphitic Carbon Fibers for Fast‐Charging Supercapacitor Applications." Energy Technology 8, no. 5 (2020): 2000050. http://dx.doi.org/10.1002/ente.202000050.

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31

Zhang, Le-Sheng, Wei Li, Zhi-Min Cui, and Wei-Guo Song. "Synthesis of Porous and Graphitic Carbon for Electrochemical Detection." Journal of Physical Chemistry C 113, no. 48 (2009): 20594–98. http://dx.doi.org/10.1021/jp907989j.

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32

Liu, Yifan, Siyan Liu, Ziyi Liu, et al. "Porous quasi-graphitic carbon sheets for unprecedented sodium storage." Inorganic Chemistry Frontiers 7, no. 13 (2020): 2443–50. http://dx.doi.org/10.1039/d0qi00325e.

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Water-soluble KCl as the catalyst and template to produce PGC sheets in CCVD. Abundant channels on the surface of PGCs helps the transportation and diffusion of Na<sup>+</sup>. PGC sheets deliver a high reversible specific capacity of 237 mA h g<sup>−1</sup> at 0.1 A g<sup>−1</sup>.
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33

Paisley, Steven D. "Separation of Tocopheryl Acetate Isomers on Porous Graphitic Carbon." Chromatographia 72, no. 3-4 (2010): 317–19. http://dx.doi.org/10.1365/s10337-010-1650-6.

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34

Wan, Qian H., P. Nicholas Shaw, Martyn C. Davies, and David A. Barrett. "Chromatographic behaviour of positional isomers on porous graphitic carbon." Journal of Chromatography A 697, no. 1-2 (1995): 219–27. http://dx.doi.org/10.1016/0021-9673(94)00813-o.

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35

Michel, Monika, and Bogusław Buszewski. "Porous graphitic carbon sorbents in biomedical and environmental applications." Adsorption 15, no. 2 (2009): 193–202. http://dx.doi.org/10.1007/s10450-009-9170-0.

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36

Kim, Pil, Ji Bong Joo, Jongsik Kim, Wooyoung Kim, In Kyu Song, and Jongheop Yi. "Sucrose-derived graphitic porous carbon replicated by mesoporous silica." Korean Journal of Chemical Engineering 23, no. 6 (2006): 1063–66. http://dx.doi.org/10.1007/s11814-006-0030-2.

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37

Chubenko, E. B., A. V. Baglov, E. S. Lisimova, and V. E. Borisenko. "Synthesis of Graphitic Carbon Nitride in Porous Silica Glass." International Journal of Nanoscience 18, no. 03n04 (2019): 1940042. http://dx.doi.org/10.1142/s0219581x19400428.

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We developed and studied facile synthesis of graphitic carbon nitride in macroporous silica glass matrix. Melamine was used as a precursor. The synthesis was performed in a closed air ambience at 400–600∘C. It was found that the synthesized material was characterized with a broadband room-temperature photoluminescence in the range of 350–750[Formula: see text]nm with the peak shifting from to 445[Formula: see text]nm to 702[Formula: see text]nm when the temperature of the synthesis was increased from [Formula: see text]C to [Formula: see text]C while the intensity of the luminescence was decreased. The nature of the luminescent centers and possible applications of the synthesized material are discussed.
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38

Chang, Binbin, Baocheng Yang, Yanzhen Guo, Yiliang Wang, and Xiaoping Dong. "Preparation and enhanced supercapacitance performance of porous carbon spheres with a high degree of graphitization." RSC Advances 5, no. 3 (2015): 2088–95. http://dx.doi.org/10.1039/c4ra09204j.

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39

Han, Li-Na, Xiao Wei, Bing Zhang, et al. "Trapping oxygen in hierarchically porous carbon nano-nets: graphitic nitrogen dopants boost the electrocatalytic activity." RSC Advances 6, no. 62 (2016): 56765–71. http://dx.doi.org/10.1039/c6ra08815e.

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40

Wang, Zhonghao, Long Chen, Xiaorui Du, Guojun Zou, and Xiaolai Wang. "A “pillared” process to construct graphitic carbon nitride based functionalized mesoporous materials." RSC Advances 6, no. 19 (2016): 15605–9. http://dx.doi.org/10.1039/c5ra26192a.

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41

Zhang, Longshuai, Ning Ding, Jionghua Wu, et al. "New two-dimensional porous graphitic carbon nitride nanosheets for highly efficient photocatalytic hydrogen evolution under visible-light irradiation." Catalysis Science & Technology 8, no. 15 (2018): 3846–52. http://dx.doi.org/10.1039/c8cy00970h.

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42

Liu, Mingxian, Lihua Gan, Wei Xiong, Zijie Xu, Dazhang Zhu, and Longwu Chen. "Development of MnO2/porous carbon microspheres with a partially graphitic structure for high performance supercapacitor electrodes." J. Mater. Chem. A 2, no. 8 (2014): 2555–62. http://dx.doi.org/10.1039/c3ta14445c.

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43

Shin, Dongyoon, Myounghoon Choun, Hyung Chul Ham, Jae Kwang Lee, and Jaeyoung Lee. "A graphitic edge plane rich meso-porous carbon anode for alkaline water electrolysis." Physical Chemistry Chemical Physics 19, no. 33 (2017): 21987–95. http://dx.doi.org/10.1039/c7cp03208k.

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Highly graphitic edge plane rich porous carbon structure might be the origin of electrocatalytic activity for oxygen evolution reaction in carbon based catalysts and the embedded metal particles play a role in forming the specific carbon structure along with improving degree of graphitization.
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44

Kong, Xiangzhong, Anqiang Pan, Yaping Wang, et al. "In situ formation of porous graphitic carbon wrapped MnO/Ni microsphere networks as binder-free anodes for high-performance lithium-ion batteries." Journal of Materials Chemistry A 6, no. 26 (2018): 12316–22. http://dx.doi.org/10.1039/c8ta02546k.

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45

Janekarn, Intuorn, Andrew J. Hunt, Yuvarat Ngernyen, Sujittra Youngme, and Nontipa Supanchaiyamat. "Graphitic mesoporous carbon-silica composites from low-value sugarcane by-products for the removal of toxic dyes from wastewaters." Royal Society Open Science 7, no. 9 (2020): 200438. http://dx.doi.org/10.1098/rsos.200438.

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Highly porous carbon-silica composites (CSC) were prepared for the first time through a simple wet impregnation process and subsequent pyrolysis of low-value sugarcane by-products, namely molasses. These CSC materials demonstrate a distinct range of functionalities, which significantly differ from similar materials published in the literature. Importantly, the carbon-silica composites prepared at 800°C exhibited exceptional adsorption capacities for the azo-dye congo red (445 mg g −1 ), due to the graphitic carbon coating and unique functionality including C-O-C within the porous structure. Congo red adsorption capacity of the highly mesoporous graphitic carbon-silica composites significantly exceeds that of commercial activated carbon and silica, these carbon-silica composites therefore represent an effective step towards the development of porous bio-derived adsorbent for remediation of dye wastewaters. Both the porous properties (surface area and pore size distribution) and the functionality of the carbon coating were dependent on the temperature of preparation. The sustainable synthetic methods employed led to a versatile material that inherited the mesoporosity characteristics from the parent silica, demonstrating mesoporous volumes greater than 90% (as calculated from the total pore volume). Adsorption on the 800°C prepared carbon-silica composites demonstrated an excellent fit with the Langmuir isotherm and the pseudo-first-order kinetic model.
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46

Kim, Hyehee, Sen Gao, Myung Gwan Hahm, Chi Won Ahn, Hyun Young Jung, and Yung Joon Jung. "Graphitic Nanocup Architectures for Advanced Nanotechnology Applications." Nanomaterials 10, no. 9 (2020): 1862. http://dx.doi.org/10.3390/nano10091862.

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The synthesis of controllable hollow graphitic architectures can engender revolutionary changes in nanotechnology. Here, we present the synthesis, processing, and possible applications of low aspect ratio hollow graphitic nanoscale architectures that can be precisely engineered into morphologies of (1) continuous carbon nanocups, (2) branched carbon nanocups, and (3) carbon nanotubes–carbon nanocups hybrid films. These complex graphitic nanocup-architectures could be fabricated by using a highly designed short anodized alumina oxide nanochannels, followed by a thermal chemical vapor deposition of carbon. The highly porous film of nanocups is mechanically flexible, highly conductive, and optically transparent, making the film attractive for various applications such as multifunctional and high-performance electrodes for energy storage devices, nanoscale containers for nanogram quantities of materials, and nanometrology.
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47

Sun, Yue, Junpeng Ma, Xinyue Yang, Liping Wen, Weidong Zhou, and Jianxin Geng. "Sulfur covalently bonded to porous graphitic carbon as an anode material for lithium-ion capacitors with high energy storage performance." Journal of Materials Chemistry A 8, no. 1 (2020): 62–68. http://dx.doi.org/10.1039/c9ta09347h.

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48

Zhang, Cheng, Qing Shan Gao, Lu Yun Jiao, Laura Bogen, Nicole Forte, and Elizabeth Nestler. "Hollow Graphitic Carbon Nanospheres Synthesized by Rapid Pyrolytic Carbonization." Journal of Nano Research 68 (June 29, 2021): 1–16. http://dx.doi.org/10.4028/www.scientific.net/jnanor.68.1.

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Hollow graphitic porous carbon nanosphere (CNS) materials are synthesized from polymerization of resorcinol (R) and formaldehyde (F) in the presence of templating iron polymeric complex (IPC), followed by carbonization treatment. The effect of rapid heating in the carbonization process is investigated for the formation of hollow graphitic carbon nanospheres. The resulting CNS from rapid heating was characterized for its structure and properties by transmission electron microscope (TEM), x-ray diffraction (XRD), Raman spectroscopy, bulk conductivity measurement and Brunauer-Emmett-Teller (BET) surface area. Hollow graphitic CNS with reduced degree of agglomeration is observed under rapid heating during the carbonization process when compared to the CNS synthesized using the standard slow heating approach. Key words: carbon nanosphere (CNS), rapid pyrolytic carbonization, agglomeration
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49

Zhang, Linjie, Zixue Su, Feilong Jiang, et al. "Highly graphitized nitrogen-doped porous carbon nanopolyhedra derived from ZIF-8 nanocrystals as efficient electrocatalysts for oxygen reduction reactions." Nanoscale 6, no. 12 (2014): 6590–602. http://dx.doi.org/10.1039/c4nr00348a.

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50

Ndiripo, Anthony, Andreas Albrecht, and Harald Pasch. "Improving chromatographic separation of polyolefins on porous graphitic carbon stationary phases: effects of adsorption promoting solvent and column length." RSC Advances 10, no. 31 (2020): 17942–50. http://dx.doi.org/10.1039/d0ra00509f.

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