Relevant bibliographies by topics / Flash graphene

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  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers
  6. Reports

Academic literature on the topic 'Flash graphene'

Author: Grafiati
Published: 5 June 2025
Last updated: 24 June 2025

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Journal articles on the topic "Flash graphene"

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Hong, Augustin J., Emil B. Song, Hyung Suk Yu, et al. "Graphene Flash Memory." ACS Nano 5, no. 10 (2011): 7812–17. http://dx.doi.org/10.1021/nn201809k.

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Stanford, Michael G., Ksenia V. Bets, Duy X. Luong, et al. "Flash Graphene Morphologies." ACS Nano 14, no. 10 (2020): 13691–99. http://dx.doi.org/10.1021/acsnano.0c05900.

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Bardarov, Ivo, Desislava Yordanova Apostolova, Maris Minna Mathew, Miha Nosan, Pedro Farinazzo Bergamo Dias Martins, and Bostjan Genorio. "Flash Graphene: a Sustainable Prospect for Electrocatalysis." Acta Chimica Slovenica 71, no. 4 (2024): 541–57. https://doi.org/10.17344/acsi.2024.8794.

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The increasing demand for sustainable and efficient energy conversion technologies requires ongoing exploration of new materials and methods. Flash Joule Heating (FJH) emerges as a promising technique for large-scale graphene production, boasting advantages over conventional methods. FJH rapidly heats carbon-based precursors to extreme temperatures using high electric currents, forming flash graphene upon rapid cooling. This approach offers rapid processing, high throughput, and can utilize diverse carbon sources, including biomass and waste, making it sustainable and cost-effective. Moreover, it generates minimal waste and yields flash graphene with enhanced conductivity, crucial for energy applications. FJH’s scalability, versatility, and efficiency position it as a key method for commercializing graphene across industries, particularly in energy conversion. This review comprehensively discusses FJH synthesis principles, emphasizing efficiency, scalability, and sustainability. Additionally, it analyzes recent advancements in flash graphene-based electrocatalysts, exploring their impact on renewable energy and sustainable electrocatalysis. Challenges and opportunities are addressed, outlining future research directions. Continued advancements hold immense potential to revolutionize graphene production and integrate it into next-generation energy systems, driving the transition towards cleaner energy solutions.
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Edward, Kaamil, Kabir Mamun, Sumesh Narayan, Mansour Assaf, David Rohindra, and Upaka Rathnayake. "State-of-the-Art Graphene Synthesis Methods and Environmental Concerns." Applied and Environmental Soil Science 2023 (February 2, 2023): 1–23. http://dx.doi.org/10.1155/2023/8475504.

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Graphene, a 2D sp2 hybridized carbon sheet consisting of a honeycomb network, is the building block of graphite. Since its discovery in 2004, graphene’s exceptional electronic and mechanical properties have peaked interest in various applications. However, the inability to mass produce high-quality graphene affordably currently limits the practical application of the material. Researchers are continuously working on advancing graphene synthesis methods to alleviate these limitations. Therefore, this review looks at the overview of established graphene synthesis methods and characterization techniques, and then highlights an in-depth review of graphene production through flash joule heating. The environmental concerns related to graphene synthesis are also presented in this review paper.
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Advincula, Paul A., Duy Xuan Luong, Weiyin Chen, Shivaranjan Raghuraman, Rouzbeh Shahsavari, and James M. Tour. "Flash graphene from rubber waste." Carbon 178 (June 2021): 649–56. http://dx.doi.org/10.1016/j.carbon.2021.03.020.

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Algozeeb, Wala A., Paul E. Savas, Duy Xuan Luong, et al. "Flash Graphene from Plastic Waste." ACS Nano 14, no. 11 (2020): 15595–604. http://dx.doi.org/10.1021/acsnano.0c06328.

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Novikov, Yu N., V. A. Gritsenko, G. Ya Krasnikov, and O. M. Orlov. "Multilayer graphene-based flash memory." Russian Microelectronics 45, no. 1 (2016): 63–67. http://dx.doi.org/10.1134/s1063739715060050.

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Subkhankulov, Vadim R., Ilshat Kh Saitov, Oleg L. Ryzhikov, and Mikhail Yu Dolomatov. "MODERN TECHNOLOGIES FOR GRAPHENE AND GRAPHENE-BASED COMPOUNDS PRODUCTION." Oil and Gas Business, no. 3 (June 7, 2024): 141–62. http://dx.doi.org/10.17122/ogbus-2024-3-141-162.

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Here are presented different ways for synthesis of graphene, graphene oxide and turbostratic graphene, including chemical vapor deposition, mechanical and chemical exfoliation methods and their modifications, epitaxial growth and laser synthesis. Their main advantages and disadvantages are presented. Special attention is given to a novel way for turbostratic graphene production by flash pyrolysis in electrical impulse discharge. Finally compared main physical properties of graphene and its compounds produced using different production methods.
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Novikov, Yu N., and V. A. Gritsenko. "New multilayer graphene-based flash memory." Materials Research Express 6, no. 10 (2019): 106306. http://dx.doi.org/10.1088/2053-1591/ab3992.

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Zhan, Ning, Mario Olmedo, Guoping Wang, and Jianlin Liu. "Graphene based nickel nanocrystal flash memory." Applied Physics Letters 99, no. 11 (2011): 113112. http://dx.doi.org/10.1063/1.3640210.

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Dissertations / Theses on the topic "Flash graphene"

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Miyata, Yasumitsu, Keiichi Kamon, Kazunori Ohashi, Ryo Kitaura, Masamichi Yoshimura, and Hisanori Shinohara. "A simple alcohol-chemical vapor deposition synthesis of single-layer graphenes using flash cooling." American Institute of Physics, 2010. http://hdl.handle.net/2237/14182.

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Hafsi, Bilel. "Réalisation, caractérisation et simulation de composants organiques : transistors à effet de champ et mémoires." Thesis, Lille 1, 2016. http://www.theses.fr/2016LIL10055/document.

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Cette thèse aborde une approche originale de réalisation de composants organiques (transistors, mémoires volatiles et non volatiles) à base d’un semiconducteur de type N “PolyeraTM N2200”. Tout d’abord, des transistors à effet de champ ont été fabriqués et optimisés en améliorant notamment certains paramètres technologiques. Par la suite, ces transistors ont été simulés à l’aide du logiciel ISE TCAD®, un logiciel basé sur un modèle 2D à effet de champ et de dérive-diffusion. Les propriétés électriques de ces dispositifs organiques ont été étudiées en fonction de l’influence de la mobilité des porteurs, des densités des pièges, et de leur énergie… . Les effets des pièges d'interface ont également été pris en considération. Par ailleurs, on y incorporant une couche de nanoparticules d’or (NP’s Au), on a réussi à développer des composants appelés « NOMFET » qui miment le comportement d’une synapse biologique tout en reproduisant les effets dépressifs et facilitateurs avec une amplitude relative de 50% et une réponse dynamique de l’ordre de 4s. En étudiant la dynamique de chargement et de déchargement des NP’s d’or, on a mis en évidence une fonction d’apprentissage anti-Hebbienne, un des mécanismes fondamentaux de l’apprentissage non-supervisé d’une synapse inhibitrice dans un réseau de neurones biologiques. Finalement, des mémoires FLASH, ont été réalisées en combinant des NP’s d’or avec des monofeuillets d’oxyde de graphène réduit (rGO). Ces mémoires « FLASH » appelées aussi mémoires à double grille flottante montrent une large fenêtre de mémorisation (~68V), un temps de rétention élevé (&gt;108s) et d’excellentes propriétés d’endurance (1000 cycles d’écriture/effacement)<br>The subject of this thesis adopt an original approach to realize new components (transistor, volatile and non-volatiles memory) based on N type organic semiconductor “PolyeraTM N2200”. First, we have fabricated and optimized organic field effect transistors by modifying some technological parameters related to fabrication. Then, we have analyzed their electrical properties with the help of two-dimensional drift-diffusion simulator using ISE-TCAD®. We studied the fixed surface charges and the effect of the organic semiconductor/oxide interface traps. The dependence of the threshold voltage on the density and energy level of the trap states has been also considered. , by incorporating gold nanoparticles in these devices, we have developed a new device called “NOMFETs” (nanoparticles organic memory field effect transistors), which mimic the behavior of biological synapse by reproducing a facilitating and a depressing drain current with a relative amplitude of about 50% and a dynamic response of about 4s. Studying the charging/discharging dynamics, we demonstrated a typical anti-Hebbien learning function, one of the fundamental mechanisms of the unsupervised learning in biological neural networks. Finally, we developed nonvolatile “FLASH” memory devices, by combining metallic gold nanoparticles and reduced graphene oxide (rGO) monolayer flakes. This double floating gate architecture provided us a good charge trapping ability which include a wide memory window (~68V), a long extrapolated retention time (&gt; 108 s) and strong endurance properties (1000 write/erase cycles)
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Hsueh, Jen-Hao, and 薛任皓. "Electrochemical Exfoliation of Graphene Sheets from Natural Graphite Flask." Thesis, 2016. http://ndltd.ncl.edu.tw/handle/60896231630466234055.

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碩士<br>元智大學<br>化學工程與材料科學學系<br>104<br>An electrochemical route to functionalize graphene nanosheets (GNs) directly from a natural graphite electrode is described herein in the presence of sulfate ions under constant-voltage (CV) and constant-current (CC) models at temperature range of 303‒333 K. This electrochemical exfoliation process is more effective than chemical exfoliation processes and also provides a means of producing low-defect and high-yield GN products. The influence of exfoliation temperature on the quality of as-prepared GN products is systematically investigated. To clarify this effect, one mechanism, consisted of (i) ionic intercalation, (ii) anion insertion and polarization, (iii) water electrolysis and SO2 evolution, and (iv) bubble expansion, is proposed. The interlayer distance, defect concentration, and growth rate of GNs as an increasing function of exfoliation temperature can be obtained. By using only 250 ml reactor, more than 1.8 g of GNs is obtained in less than 1 h through the CC operation. The growth rate of GNs under CC model is approximately five times higher than that under CV one at the fixed temperature. Based on the analysis of Arrhenius plots, the apparent activation energies through the CV and CC models are 20.6 and 23.1 kJ/mol, respectively. As a result, this exfoliation method using the CC model displays a potentially scalable approach for generating high-quality GN products.
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Books on the topic "Flash graphene"

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It Is Not Flesh and Blood, but Heart Which Makes Us Fathers and Sons: Family Graph Paper, Graph Paper Pad, Graphing Paper, Computation Pads, Drafting Paper, Blueprint Paper, Quad Rised 5x5, Grid Paper for Math and Science Student. Independently Published, 2020.

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Book chapters on the topic "Flash graphene"

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Prakash, C., P. Senthil, N. Manikandan, and D. Palanisamy. "Machinability Investigations of Aluminum Metal Matrix Composites (LM26 + Graphite + Flyash) by Using Wire Electrical Discharge Machining Process." In Lecture Notes in Mechanical Engineering. Springer Nature Singapore, 2022. http://dx.doi.org/10.1007/978-981-19-0244-4_91.

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Hayat, Mamoona, Junaid Ali, Saira Arif, Khaled Pervez, Ghayas Uddin Siddiqui, and Cinzia Casiraghi. "Graphene and Waste Management A Roadmap for Cost-Effective Graphene Production." In 2D Materials: Chemistry and Applications (Part 2). BENTHAM SCIENCE PUBLISHERS, 2024. http://dx.doi.org/10.2174/9789815305241124010006.

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The sustainable development goals have provided a boost and economic appeal to recycling and reusing waste. Waste materials like plastic, industrial, and biomass can be exploited as a foundation to produce valuable products, including wonder materials like graphene. It is utilized in almost every field of life, from environmental sustainability to smart clothing. Waste material contains a variety of organic polymers which can be converted into graphene and its derivatives. It uses various methods like metal catalysis, laser ablation techniques, flash Joule heating, and pyrolysis. These methods may produce 3D, 2D, 1D, and 0D graphene. The obtained products have exclusive properties like thermal, optoelectronic, and electrical properties. The potential for removing and converting waste into the revolutionary material of the century opens possibilities for a sustainable and progressive yet less hazardous world for our future generations. Some approaches promise the fabrication of graphene and its spin-offs from biowaste like sugarcane bagasse, dog feces, and grass. Similarly, liquid phase exfoliation of graphene provides less hazardous and sustainable graphene production from materials without using toxic materials or burdening the earth with waste products. The carbon-negative approach proves an environmentally friendly alternative to prevalent waste-burning practices to dispose of such waste. The obtained graphene and related products have distinctive properties and tremendous applications at a fraction of the cost. The potential for removing and converting waste into the revolutionary material of the century opens possibilities for a sustainable and progressive yet less hazardous world for our future generations. This chapter reviews the efficient methods for synthesizing graphene from waste products and its various applications.
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Conference papers on the topic "Flash graphene"

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Eisner, Steve, and John J. Reilly. "Effect of Corrosion on the EMI Shielding of Composite Electronic Enclosures." In CORROSION 1989. NACE International, 1989. https://doi.org/10.5006/c1989-89043.

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Abstract Two conductive composite materials were injection molded into an electronic enclosure configuration. The two materials used were 30% nickel plated graphite (NiGr) fibers and 20% nickel flakes (NiFlk) in polyphenylene sulfide (PPS) and 30% NiGr fibers and 10% stainless steel (SS) fibers in PPS. These enclosures were electroplated with a nickel strike followed by a 2 mil (51μm) layer of copper and then by an electroless nickel flash. Peel strength tests were performed to evaluate the adhesion of the nickel/copper/electroless nickel plating system to each of the two composites. The average peel strength of the plating system on the PPS/30%NiGr/20%NiFlk and the PPS/30%NiGr/10%SS composites was 4.5 and 2.7 lbs./inch (80 and 48 kg/m), respectively. Radiated emission measurements were performed at frequencies ranging from 14 kHz to 1 GHz on the plated PPS/30%NiGr/20%NiFlk composite enclosure before and after 144 hours of SO2/salt spray exposure.
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Hossain, Nahid M., and Masud H. Chowdhury. "Multilayer graphene nanoribbon floating gate transistor for flash memory." In 2014 IEEE International Symposium on Circuits and Systems (ISCAS). IEEE, 2014. http://dx.doi.org/10.1109/iscas.2014.6865258.

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Chang, Kai-Ping, Han-Hsiang Tai, Jer-Chyi Wang, and Chao-Sung Lai. "Graphene nanodots with high-k dielectrics for flash memory applications." In 2017 IEEE 12th International Conference on ASIC (ASICON). IEEE, 2017. http://dx.doi.org/10.1109/asicon.2017.8252506.

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Misra, Abhishek, Hemen Kalita, Mayur Waikar, et al. "Multilayer Graphene as Charge Storage Layer in Floating Gate Flash Memory." In 2012 4th IEEE International Memory Workshop (IMW). IEEE, 2012. http://dx.doi.org/10.1109/imw.2012.6213626.

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Zhou, Congli. "Graphene prepared by flash joule heating from biowaste for microwave absorption." In 2022 International Conference on Optoelectronic Materials and Devices, edited by Qiang Huang. SPIE, 2023. http://dx.doi.org/10.1117/12.2674021.

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Hossain, Nahid M., Md Belayat Hossain, and Masud H. Chowdhury. "Multilayer layer graphene nanoribbon flash memory: Analysis of programming and erasing operation." In 2014 27th IEEE International System-on-Chip Conference (SOCC). IEEE, 2014. http://dx.doi.org/10.1109/socc.2014.6948894.

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Wong, Shao Ing, Han Lin, Jaka Sunarso, Basil T. Wong, and Baohua Jia. "Tuning the properties of flash-reduced graphene oxide electrodes for supercapacitor applications." In Micro + Nano Materials, Devices, and Applications 2019, edited by M. Cather Simpson and Saulius Juodkazis. SPIE, 2019. http://dx.doi.org/10.1117/12.2543097.

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Akbari, Mitra, Lauri Sydanheimo, Jari Juuti, and Leena Ukkonen. "Flash reduction of inkjet printed graphene oxide on flexible substrates for electronic applications." In 2015 IEEE 15th International Conference on Nanotechnology (IEEE-NANO). IEEE, 2015. http://dx.doi.org/10.1109/nano.2015.7388775.

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Ramírez, Juan, Esteban Yépez, Fernando Pantoja-Suárez, Eliana Acurio, Fabian Pérez, and Leonardo Basile. "Design and Construction of a High-Current Capacitor Bank for Flash Graphene Synthesis." In Conference on Electrical and Electronic Engineering. MDPI, 2023. http://dx.doi.org/10.3390/engproc2023047018.

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Hossain, Nahid M., and Masud H. Chowdhury. "Graphene and CNT based flash memory: Impacts of scaling control and tunnel oxide thickness." In 2014 IEEE 57th International Midwest Symposium on Circuits and Systems (MWSCAS). IEEE, 2014. http://dx.doi.org/10.1109/mwscas.2014.6908582.

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Reports on the topic "Flash graphene"

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Johra, Hicham. Coating Translucent and Semitransparent Material Samples for Laser Flash Analysis. Department of the Built Environment, Aalborg University, 2020. http://dx.doi.org/10.54337/aau351121322.

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The aim of this technical report is to present and discuss the influence of graphite coating on the measurement of thermal diffusivity for translucent or semitransparent material samples with the Laser Flash Analysis (LFA) method. This experimental study has been conducted at the Building Material Characterization Laboratory of Aalborg University - Department of the Built Environment, with the Laser Flash Apparatus LFA 447 (Netzsch Gerätebau GmbH).
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