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Journal articles on the topic 'Synthesis gas'

Author: Grafiati
Published: 4 June 2021
Last updated: 6 September 2023

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1

JM, Bahig. "Synthesis of Bio-gas Using Squander Cooking Oil." Petroleum & Petrochemical Engineering Journal 5, no. 3 (2021): 1–7. http://dx.doi.org/10.23880/ppej-16000270.

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The point of this examination is to evaluate the performance of both catalytic and thermal cracking processes in the thermochemical conversion of squander cooking oil into biofuel and investigate the impact of ZSM-5 impetus and breaking reactor temperature to items yield, biofuel caloric substance and synthetic arrangement. Several parameters might affect process performance which resulted in different product’s yield and specification. Cracking temperature variation gave appreciable effect on yield and product’s caloric values.
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2

Encinar, J. M., J. F. González, N. Sánchez, and S. Nogales. "Glycerol Reuse for Obtaining Synthesis Gas through Steam Reforming." International Journal of Chemical Engineering and Applications 10, no. 5 (October 2019): 163–67. http://dx.doi.org/10.18178/ijcea.2019.10.5.762.

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3

Dac Dien, Nguyen, Luong Huu Phuoc, Do Duc Tho, Nguyen Anh Phuc Duc, Nguyen Duc Chien, and Dang Duc Vuong. "HYDROTHERMAL SYNTHESIS AND NH3 GAS SENSING PROPERTY OFWO3 NANO PARTICLES." Journal of Science, Natural Science 60, no. 7 (2015): 68–74. http://dx.doi.org/10.18173/2354-1059.2015-0034.

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4

Shalaev, R. V. "Gas-Phase Synthesis of Film Structures of Ni—N System." METALLOFIZIKA I NOVEISHIE TEKHNOLOGII 37, no. 4 (August 17, 2016): 509–19. http://dx.doi.org/10.15407/mfint.37.04.0509.

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5

Chiche, D., C. Diverchy, A. C. Lucquin, F. Porcheron, and F. Defoort. "Synthesis Gas Purification." Oil & Gas Science and Technology – Revue d’IFP Energies nouvelles 68, no. 4 (July 2013): 707–23. http://dx.doi.org/10.2516/ogst/2013175.

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6

Zhang, Qianwen, Xiaohong Li, Kenji Asami, Sachio Asaoka, and Kaoru Fujimoto. "Synthesis of LPG from synthesis gas." Fuel Processing Technology 85, no. 8-10 (July 2004): 1139–50. http://dx.doi.org/10.1016/j.fuproc.2003.10.016.

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7

Betts, Natalie S., Christoph Dockter, Oliver Berkowitz, Helen M. Collins, Michelle Hooi, Qiongxian Lu, Rachel A. Burton, et al. "Transcriptional and biochemical analyses of gibberellin expression and content in germinated barley grain." Journal of Experimental Botany 71, no. 6 (December 10, 2019): 1870–84. http://dx.doi.org/10.1093/jxb/erz546.

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Abstract Mobilization of reserves in germinated cereal grains is critical for early seedling vigour, global crop productivity, and hence food security. Gibberellins (GAs) are central to this process. We have developed a spatio-temporal model that describes the multifaceted mechanisms of GA regulation in germinated barley grain. The model was generated using RNA sequencing transcript data from tissues dissected from intact, germinated grain, which closely match measurements of GA hormones and their metabolites in those tissues. The data show that successful grain germination is underpinned by high concentrations of GA precursors in ungerminated grain, the use of independent metabolic pathways for the synthesis of several bioactive GAs during germination, and a capacity to abort bioactive GA biosynthesis. The most abundant bioactive form is GA1, which is synthesized in the scutellum as a glycosyl conjugate that diffuses to the aleurone, where it stimulates de novo synthesis of a GA3 conjugate and GA4. Synthesis of bioactive GAs in the aleurone provides a mechanism that ensures the hormonal signal is relayed from the scutellum to the distal tip of the grain. The transcript data set of 33 421 genes used to define GA metabolism is available as a resource to analyse other physiological processes in germinated grain.
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8

Wender, Irving. "Reactions of synthesis gas." Fuel Processing Technology 48, no. 3 (September 1996): 189–297. http://dx.doi.org/10.1016/s0378-3820(96)01048-x.

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9

Valenti, Michael. "Turbines for Synthesis Gas." Mechanical Engineering 120, no. 08 (August 1, 1998): 72–73. http://dx.doi.org/10.1115/1.1998-aug-6.

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This article reviews on one of the most demanding applications for steam turbines, which are providing the extraction steam for the production of ammonia and methanol synthesis gas, or syngas. Dresser-Rand Energy Systems, Wellsville, NY, designed their Syngas Steam Turbine specifically to meet these requirements. Demand is expected to grow for both ammonia and methanol. Ammonia is the source for most of the nitrogen fertilizer produced globally. The capacity in 1996 was 117 million metric tons, up from 113 million metric tons five years earlier. Dresser-Rand approached the syngas project with more than 30 years’ experience as a leading supplier of compression equipment for ammonia plants. The first Syngas Steam Turbine, and its complete compression train including Dresser-Rand DATUM compressors, was shipped to a methanol plant operated by Qatar Fuel Additives Ltd. in the Mesaieed Industrial Area, Qatar. It is scheduled to begin operation by the middle of next year, producing 610,000 metric tons of methanol annually. Dresser-Rand engineers have also adapted their Syngas Turbine technology for different applications.
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10

Debabov, V. G. "Bioethanol from synthesis gas." Applied Biochemistry and Microbiology 49, no. 7 (October 22, 2013): 619–28. http://dx.doi.org/10.1134/s000368381307003x.

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11

Rostrup-Nielsen, J. R. "Production of synthesis gas." Catalysis Today 18, no. 4 (December 1993): 305–24. http://dx.doi.org/10.1016/0920-5861(93)80059-a.

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12

Knifton, John F., J. J. Lin, David A. Storm, and S. F. Wong. "New synthesis gas chemistry." Catalysis Today 18, no. 4 (December 1993): 355–84. http://dx.doi.org/10.1016/0920-5861(93)80061-5.

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13

Keim, Wilhelm, and Wolfang Falter. "Isobutanol from synthesis gas." Catalysis Letters 3, no. 1 (1989): 59–63. http://dx.doi.org/10.1007/bf00765055.

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14

Fujimoto, Kaoru, Michiaki Adachi, and Hiro-o. Tominaga. "DIRECT SYNTHESIS OF ISOPARAFFINS FROM SYNTHESIS GAS." Chemistry Letters 14, no. 6 (June 5, 1985): 783–86. http://dx.doi.org/10.1246/cl.1985.783.

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15

Fujimoto, Kaoru, Hitoshi Saima, and Hiro-o. Tominaga. "Selective Synthesis of LPG from Synthesis Gas." Bulletin of the Chemical Society of Japan 58, no. 10 (October 1985): 3059–60. http://dx.doi.org/10.1246/bcsj.58.3059.

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16

Verkerk, Kai A. N., Bernd Jaeger, Caspar-Heinrich Finkeldei, and Wilhelm Keim. "Recent developments in isobutanol synthesis from synthesis gas." Applied Catalysis A: General 186, no. 1-2 (October 1999): 407–31. http://dx.doi.org/10.1016/s0926-860x(99)00158-1.

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17

Tustin, Gerald C., Richard D. Colberg, and Joseph R. Zoeller. "Synthesis of vinyl acetate monomer from synthesis gas." Catalysis Today 58, no. 4 (May 2000): 281–91. http://dx.doi.org/10.1016/s0920-5861(00)00262-5.

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18

Aasberg-Petersen, K., I. Dybkjær, C. V. Ovesen, N. C. Schjødt, J. Sehested, and S. G. Thomsen. "Natural gas to synthesis gas – Catalysts and catalytic processes." Journal of Natural Gas Science and Engineering 3, no. 2 (May 2011): 423–59. http://dx.doi.org/10.1016/j.jngse.2011.03.004.

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19

Olsen, Susanne, and Edward Gobina. "GTL synthesis gas generation membrane for monetizing stranded gas." Membrane Technology 2004, no. 6 (June 2004): 5–10. http://dx.doi.org/10.1016/s0958-2118(04)00161-2.

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20

Kiendl, Isabel, Marco Klemm, Andreas Clemens, and André Herrman. "Dilute gas methanation of synthesis gas from biomass gasification." Fuel 123 (May 2014): 211–17. http://dx.doi.org/10.1016/j.fuel.2014.01.036.

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21

Sundset, Trude, Jostein Sogge, and Terje Strøm. "Evaluation of natural gas based synthesis gas production technologies." Catalysis Today 21, no. 2-3 (December 1994): 269–78. http://dx.doi.org/10.1016/0920-5861(94)80148-7.

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22

Rafiee, A., and M. Hillestad. "Synthesis Gas Production Configurations for Gas-to-Liquid Applications." Chemical Engineering & Technology 35, no. 5 (April 23, 2012): 870–76. http://dx.doi.org/10.1002/ceat.201100674.

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23

Chríbik, Andrej, Marián Polóni, Ján Lach, Ľubomír Jančošek, Peter Kunc, and Josef Zbranek. "Synthesis Gas from Pyrolysed Plastics for Combustion Engine." Scientific Proceedings Faculty of Mechanical Engineering 23, no. 1 (December 1, 2015): 18–24. http://dx.doi.org/10.1515/stu-2015-0004.

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Abstract The article discusses the application of synthesis gas from pyrolysis of plastics in petrol engine. The appropriate experimental measurements were performed on a combustion engine LGW 702 designated for micro-cogeneration unit. The power parameters, economic and internal parameters of the engine were compared to the engine running on the reference fuel - natural gas and synthesis gas. Burning synthesis gas leads to decreased performance by about 5% and to increased mass hourly consumption by 120%. In terms of burning, synthesis gas has similar properties as natural gas. More significant changes are observed in even burning of fuel in consecutive cycles.
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24

Maksimov, Pavel, Arto Laari, Vesa Ruuskanen, Tuomas Koiranen, and Jero Ahola. "Gas phase methanol synthesis with Raman spectroscopy for gas composition monitoring." RSC Advances 10, no. 40 (2020): 23690–701. http://dx.doi.org/10.1039/d0ra04455e.

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25

Kamo, Mutsukazu. "Diamond synthesis from gas phase." Bulletin of the Japan Institute of Metals 28, no. 6 (1989): 483–92. http://dx.doi.org/10.2320/materia1962.28.483.

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26

Klasson, K. T., M. D. Ackerson, E. C. Clausen, and J. L. Gaddy. "Bioreactors for synthesis gas fermentations." Resources, Conservation and Recycling 5, no. 2-3 (April 1991): 145–65. http://dx.doi.org/10.1016/0921-3449(91)90022-g.

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27

Rebrov, A. K. "Gas-jet synthesis of diamond." Journal of Physics: Conference Series 1105 (November 2018): 012124. http://dx.doi.org/10.1088/1742-6596/1105/1/012124.

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28

Bengelsdorf, Frank R., Melanie Straub, and Peter Dürre. "Bacterial synthesis gas (syngas) fermentation." Environmental Technology 34, no. 13-14 (July 2013): 1639–51. http://dx.doi.org/10.1080/09593330.2013.827747.

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29

Dunbar, Robert C., Don Solooki, Claire A. Tessier, Wiley J. Youngs, and Bruce Asamoto. "Gas-phase synthesis of metallocyclotriynes." Organometallics 10, no. 1 (January 1991): 52–54. http://dx.doi.org/10.1021/om00047a027.

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30

Del Bianco, A., E. Girardi, and M. Anelli. "Liquefaction coprocessing with synthesis gas." Fuel Processing Technology 27, no. 3 (May 1991): 235–45. http://dx.doi.org/10.1016/0378-3820(91)90050-m.

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31

Blanks, R. F., T. S. Wittrig, and D. A. Peterson. "Bidirectional adiabatic synthesis gas generator." Chemical Engineering Science 45, no. 8 (1990): 2407–13. http://dx.doi.org/10.1016/0009-2509(90)80122-u.

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32

Maqbool, Wahab, Sang Jin Park, and Euy Soo Lee. "Steam Methane Reforming of Natural Gas with Substantial Carbon Dioxide Contents – Process Optimization for Gas-to-Liquid Applications." Applied Mechanics and Materials 548-549 (April 2014): 316–20. http://dx.doi.org/10.4028/www.scientific.net/amm.548-549.316.

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Steam methane reforming has been a conventional process to produce synthesis gas which is an important feedstock to many chemicals. However, for gas to liquid (GTL) applications this reforming process is not suitable as it produces synthesis gas with very high hydrogen to carbon monoxide ratio than required by the Fischer Tropsch synthesis in GTL line. In this work, a GTL process is designed in which synthesis gas is produced by steam reforming from a natural gas feedstock containing relatively substantial carbon dioxide contents in it. Synthesis gas composition is tailored by tail gas recycling from the Fischer Tropsch products. Process simulation and optimization is performed on Aspen HYSYS to produce synthesis gas with hydrogen to carbon monoxide ratio of 2 which is desired in GTL technology.
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33

Souza, Mariana M. V. M., Octávio R. Macedo Neto, and Martin Schmal. "Synthesis Gas Production from Natural Gas on Supported Pt Catalysts." Journal of Natural Gas Chemistry 15, no. 1 (March 2006): 21–27. http://dx.doi.org/10.1016/s1003-9953(06)60003-0.

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34

SANO, Tsuneji, and Haruo TAKAYA. "Synthesis of light olefins from synthesis gas utilizing zeolite." Journal of The Japan Petroleum Institute 29, no. 4 (1986): 267–79. http://dx.doi.org/10.1627/jpi1958.29.267.

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35

Osman, Mohamed E., Vladimir V. Maximov, Viktor S. Dorokhov, Viktor M. Mukhin, Tatiana F. Sheshko, Patricia J. Kooyman, and Viktor M. Kogan. "Carbon-Supported KCoMoS2 for Alcohol Synthesis from Synthesis Gas." Catalysts 11, no. 11 (October 30, 2021): 1321. http://dx.doi.org/10.3390/catal11111321.

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KCoMoS2 was supported on various carbon support materials to study the support effect on synthesis gas conversion. Next to two activated carbons with high micropore volume, a traditional alumina (γ-Al2O3) support and its carbon coated form (CCA) were studied for comparison. Coating alumina with carbon increases the selectivity to alcohols, but the AC-supported catalysts show even higher alcohol selectivities and yields, especially at higher temperatures where the conversions over the AC-supported catalysts increase more than those over the γ-Al2O3-based catalysts. Increasing acidity leads to decreased CO conversion yield of alcohols. The two activated-carbon-supported catalysts give the highest yield of ethanol at the highest conversion studied, which seems to be due to increased KCoMoS2 stacking and possibly to the presence of micropores and low amount of mesopores.
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36

Li, Xiaohong, Kenji Asami, Mengfei Luo, Keisuke Michiki, Noritatsu Tsubaki, and Kaoru Fujimoto. "Direct synthesis of middle iso-paraffins from synthesis gas." Catalysis Today 84, no. 1-2 (August 2003): 59–65. http://dx.doi.org/10.1016/s0920-5861(03)00301-8.

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37

Li, Congming, and Kaoru Fujimoto. "Selective Synthesis of Isobutane from CO2-Containing Synthesis Gas." Energy & Fuels 28, no. 2 (February 3, 2014): 1331–37. http://dx.doi.org/10.1021/ef402393j.

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38

Inayat, Abrar, Muhammad A. B. Ahmad, Mohsin Raza, Chaouki Ghenai, Salman Raza Naqvi, and Muhammad Ayoub. "Development of Reaction Kinetics Model for the Production of Synthesis Gas from Dry Methane Reforming." Bulletin of Chemical Reaction Engineering & Catalysis 16, no. 2 (May 5, 2021): 440–45. http://dx.doi.org/10.9767/bcrec.16.2.10510.440-445.

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The energy supply systems dependent on fossils and municipal solid waste (MSW) materials are primarily responsible for releasing greenhouse (GHG) gases and their related environmental hazards. The increasing amount of methane (CH4) and carbon dioxide (CO2) is the scientific community's main concern in this context. Reduction in the emission amount of both gases combined with the conversion technologies that would convert these total threat gases (CO2 and CH4) into valuable feedstocks will significantly lower their hazardous impact on climate change. The conversion technique known as dry methane reforming (DMR) utilizes CO2 and CH4 to produce a combustible gas mixture (CO+H2), popularly known as synthesis gas/or syngas. Therefore, this research study aims to explore and enlighten the characteristics of the DMR mechanism. The conversion behaviour of CO2 and CH4 was studied with modelling and simulation of the DMR process using MATLAB. The results showed that inlet gas flow has a significant impact on the reactions. In contrast, the inlet molar composition ratio of the reactions was found to have no substantial effect on the mechanism of DMR. Copyright © 2021 by Authors, Published by BCREC Group. This is an open access article under the CC BY-SA License (https://creativecommons.org/licenses/by-sa/4.0).
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39

Chríbik, Andrej, Marián Polóni, Ján Lach, Ľubomír Jančošek, Peter Kunc, and Josef Zbranek. "Internal Combustion Engine Powered by Synthesis Gas from Pyrolysed Plastics." Strojnícky casopis – Journal of Mechanical Engineering 66, no. 1 (July 1, 2016): 37–46. http://dx.doi.org/10.1515/scjme-2016-0009.

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AbstractThe article discusses the application of synthesis gas from pyrolysis of plastics in petrol engine. The appropriate experimental measurements were performed on a combustion engine LGW 702 designated for micro-cogeneration unit. The power parameters, economic parameters in term of brake specific fuel consumption, and internal parameters of the engine were compared to the engine running on the reference fuel - natural gas and synthesis gas. Burning synthesis gas leads to decreased performance by about 5% and to increased mass hourly consumption by 120 %. In terms of burning, synthesis gas has similar properties as natural gas. Compared with [5] a more detailed study has been prepared on the effects of angle of spark advance on the engine torque, giving more detailed assessment of engine cycle variability and considering specification of start and end of combustion in the logarithm p-V diagram.
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40

Dimov, S. V. "Synthesis of methanol in microchnnel." Journal of Physics: Conference Series 2119, no. 1 (December 1, 2021): 012113. http://dx.doi.org/10.1088/1742-6596/2119/1/012113.

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Abstract Systematic experimental data have been obtained on the results of catalytic chemical reactions in a microchannel reactor for the synthesis of methanol from synthesis gas. Synthesis gas contains hydrogen, carbon monoxide and dioxide, as well as nitrogen in the ratio 58/29/5/8. The experiments were carried out at different flow rates in the temperature range 190-260C. Experiments were also carried out for methanol synthesis in fixed bed reactor at different synthesis pressures.
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41

Cornelissen, R., E. Tober, J. Kok, and T. van de Meer. "Generation of synthesis gas by partial oxidation of natural gas in a gas turbine." Energy 31, no. 15 (December 2006): 3199–207. http://dx.doi.org/10.1016/j.energy.2006.03.028.

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42

Popok, Vladimir N., and Ondřej Kylián. "Gas-Phase Synthesis of Functional Nanomaterials." Applied Nano 1, no. 1 (October 2, 2020): 25–58. http://dx.doi.org/10.3390/applnano1010004.

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Nanoparticles (NPs) of different types, especially those of metals and metal oxides, are widely used in research and industry for a variety of applications utilising their unique physical and chemical properties. In this article, the focus is put on the fabrication of nanomaterials by means of gas-phase aggregation, also known as the cluster beam technique. A short overview of the history of cluster sources development emphasising the main milestones is presented followed by the description of different regimes of cluster-surface interaction, namely, soft-landing, pinning, sputtering and implantation. The key phenomena and effects for every regime are discussed. The review is continued by the sections describing applications of nanomaterials produced by gas aggregation. These parts critically analyse the pros and cons of the cluster beam approach for catalysis, formation of ferromagnetic and superparamagnetic NPs, applications in sensor and detection technologies as well as the synthesis of coatings and composite films containing NPs in research and industrial applications covering a number of different areas, such as electronics, tribology, biology and medicine. At the end, the current state of the knowledge on the synthesis of nanomaterials using gas aggregation is summarised and the strategies towards industrial applications are outlined.
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43

Grammatikopoulos, Panagiotis, Stephan Steinhauer, Jerome Vernieres, Vidyadhar Singh, and Mukhles Sowwan. "Nanoparticle design by gas-phase synthesis." Advances in Physics: X 1, no. 1 (January 2, 2016): 81–100. http://dx.doi.org/10.1080/23746149.2016.1142829.

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44

Kaup, Gerd, and Doris Matthies. "Gas-Solid Reactions in Organic Synthesis." Molecular Crystals and Liquid Crystals Incorporating Nonlinear Optics 161, no. 1 (August 1988): 119–43. http://dx.doi.org/10.1080/00268948808070244.

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45

Jessop, Philip, Dolores C. Wynne, Scott DeHaai, and Denise Nakawatase. "Carbon dioxide gas accelerates solventless synthesis." Chemical Communications, no. 8 (2000): 693–94. http://dx.doi.org/10.1039/a909703a.

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46

Li, Shaoping, Jeffrey A. Eastman, and Loren J. Thompson. "Gas-condensation synthesis of nanocrystalline BaTiO3." Applied Physics Letters 70, no. 17 (April 28, 1997): 2244–46. http://dx.doi.org/10.1063/1.118828.

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47

York, Andrew P. E., Tian‐cun Xiao, Malcolm L. H. Green, and John B. Claridge. "Methane Oxyforming for Synthesis Gas Production." Catalysis Reviews 49, no. 4 (October 2007): 511–60. http://dx.doi.org/10.1080/01614940701583315.

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48

Kazakov, A. V., S. A. Khaustov, R. B. Tabakaev, and Y. A. Belousova. "Numerical simulation of synthesis gas incineration." IOP Conference Series: Materials Science and Engineering 124 (April 2016): 012110. http://dx.doi.org/10.1088/1757-899x/124/1/012110.

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49

Irikura, Karl K., and J. L. Beauchamp. "Gas-phase synthesis of metalloporphyrin ions." Journal of the American Chemical Society 113, no. 7 (March 1991): 2767–68. http://dx.doi.org/10.1021/ja00007a069.

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50

Mattei, Jean-Gabriel, Panagiotis Grammatikopoulos, Junlei Zhao, Vidyadhar Singh, Jerome Vernieres, Stephan Steinhauer, Alexander Porkovich, et al. "Gas-Phase Synthesis of Trimetallic Nanoparticles." Chemistry of Materials 31, no. 6 (March 6, 2019): 2151–63. http://dx.doi.org/10.1021/acs.chemmater.9b00129.

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