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Journal articles on the topic 'Green sustainable chemistry'

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Author: Grafiati
Published: 11 July 2023

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1

KARAGÖLGE, Zafer, and Bahri GÜR. "Sustainable Chemistry: Green Chemistry." Journal of the Institute of Science and Technology 6, no. 2 (June 20, 2016): 89. http://dx.doi.org/10.21597/jist.2016218851.

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2

Payal Rathi, Saba Nausheen, and Nisha. "Green chemistry and technology for sustainable development." International Journal of Science and Research Archive 8, no. 2 (March 30, 2023): 161–65. http://dx.doi.org/10.30574/ijsra.2023.8.2.0225.

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Green chemistry is one of the most explored topics these days. Major research on green chemistry aims to reduce or eradicate the production of harmful bi-products and maximizing the desired product in an eco friendly way. The green chemistry is required to minimize the harm of the nature by anthropogenic materials and the processes applied to generate them. Green chemistry indicates research emerges from scientific discoveries about effluence responsiveness. Green chemistry involves 12 principals which minimize or eliminates the use or production of unsafe substances. Scientists and Chemists can significantly minimize the risk to environment and health of human by the help of all the valuable ideology of green chemistry. The principles of green chemistry can be achieved by the use environmental friendly, harmless, reproducible and solvents and catalysts during production of medicine, and in researches. Green chemistry could include anything from reducing waste to even disposing of waste in the correct manner. All chemical wastes should be disposed of in the best possible manner without causing any damage to the environment and living beings. This article presents selected examples of implementation of green chemistry principles in everyday life.
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3

Lattes, Armand, and Isabelle Rico-Lattes. "Green and sustainable chemistry." Comptes Rendus Chimie 14, no. 7-8 (July 2011): 619–20. http://dx.doi.org/10.1016/j.crci.2011.07.007.

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4

Abyzbekova, G. M., D. K. Ongar, A. S. Tapalova, S. O. Espenbetova, K. Sh Arynova, and G. T. Balykbaeva. "GREEN CHEMISTRY IS THE KEY TO SUSTAINABLE DEVELOPMENT." Bulletin of Korkyt Ata Kyzylorda University 57, no. 2 (2021): 100–105. http://dx.doi.org/10.52081/bkaku.2021.v57.i2.042.

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It speaks of the emergence of the Green Chemistry direction, which has become the philosophy of thinking of all chemists, the pace of development in the world, 12 principles and the metric of green chemistry, significance. Directions for the development of green chemistry, its development in the countries of the world and the work carried out in this direction in universities were outlined. New chemical reaction and process schemes developed in many laboratories around the world are designed to radically reduce the environmental impact of large-scale chemical production. Manufacturers of chemical hazards arising from the use of an aggressive environment traditionally try to reduce the connection of workers with these substances, limiting their connection.At the same time, green chemistry offers another strategy - a careful selection of starting materials and technological schemes that exclude the use of harmful substances. Thus, green chemistry is a kind of technology that allows not only to obtain the necessary substance, but also to obtain it at all stages of production by means that are not harmful to the environment. On the development of green chemical education in the countries of the world and the work carried out at the university in this direction. Keywords: sustainable development, green chemistry, E-factor, atomic efficiency, green chemical formation
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5

Misono, Makoto. "Sustainable Society and Green Chemistry." TRENDS IN THE SCIENCES 10, no. 6 (2005): 78–81. http://dx.doi.org/10.5363/tits.10.6_78.

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6

Popa, Valentin, and Irina Volf. "GREEN CHEMISTRY AND SUSTAINABLE DEVELOPMENT." Environmental Engineering and Management Journal 5, no. 4 (2006): 545–58. http://dx.doi.org/10.30638/eemj.2006.042.

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7

Tundo, Pietro, and Elena Griguol. "Green Chemistry for Sustainable Development." Chemistry International 40, no. 1 (January 1, 2018): 18–24. http://dx.doi.org/10.1515/ci-2018-0105.

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8

Centi, Gabriele, and Siglinda Perathoner. "Catalysis and sustainable (green) chemistry." Catalysis Today 77, no. 4 (January 2003): 287–97. http://dx.doi.org/10.1016/s0920-5861(02)00374-7.

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9

Cole-Hamilton, David J. "EuCheMS – Green and Sustainable Chemistry." Green Chemistry 17, no. 4 (2015): 2281–82. http://dx.doi.org/10.1039/c5gc90018b.

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10

Dutta, Pinak, and Mita Dutta. "MULTICOMPONENT REACTIONS: GREEN HOPE TOWARD SUSTAINABLE DEVELOPMENT." RASAYAN Journal of Chemistry 15, no. 03 (2022): 1728–34. http://dx.doi.org/10.31788/rjc.2022.1536854.

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Practicing sustainable chemistry is one of the best ways to address ‘man-made’ environmental perils. The decorum set by the laws of green chemistry can lead us towards mitigating such menace. Multi-component reactions are one such weapon in the armoury of a chemist towards developing and inventing commodities ranging from life-saving drugs to lifestyle products through sustainable synthetic methodologies. Though much advancement is accomplished in developing such reactions, a correlation between ‘environmentally benign operation’ and ‘mere synthesis’ is yet to be realized. Herein, we have tried to highlight the gradual advancement of this procedure and what still needs to be achieved to entice the philosopher within ourselves towards greener thoughts and ideas.
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11

Gärtner, Peter. "Green Chemistry for a Sustainable Europe." Nachrichten aus der Chemie 70, no. 5 (April 29, 2022): 99. http://dx.doi.org/10.1002/nadc.20224126423.

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12

Champagne, Pascale, and Avtar Matharu. "Brown to green and sustainable chemistry." Current Opinion in Green and Sustainable Chemistry 2 (October 2016): iii—iv. http://dx.doi.org/10.1016/j.cogsc.2016.11.001.

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13

Lenoir, Dieter. "Experiments in Green and Sustainable Chemistry." CLEAN - Soil, Air, Water 39, no. 1 (January 2011): 95. http://dx.doi.org/10.1002/clen.201190000.

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14

Eilks, Ingo, and Franz Rauch. "Sustainable development and green chemistry in chemistry education." Chem. Educ. Res. Pract. 13, no. 2 (2012): 57–58. http://dx.doi.org/10.1039/c2rp90003c.

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15

Welton, Tom. "Solvents and sustainable chemistry." Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences 471, no. 2183 (November 2015): 20150502. http://dx.doi.org/10.1098/rspa.2015.0502.

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Solvents are widely recognized to be of great environmental concern. The reduction of their use is one of the most important aims of green chemistry. In addition to this, the appropriate selection of solvent for a process can greatly improve the sustainability of a chemical production process. There has also been extensive research into the application of so-called green solvents, such as ionic liquids and supercritical fluids. However, most examples of solvent technologies that give improved sustainability come from the application of well-established solvents. It is also apparent that the successful implementation of environmentally sustainable processes must be accompanied by improvements in commercial performance.
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16

Cannon, Amy S., and John C. Warner. "The Science of Green Chemistry and its Role in Chemicals Policy and Educational Reform." NEW SOLUTIONS: A Journal of Environmental and Occupational Health Policy 21, no. 3 (October 14, 2011): 499–517. http://dx.doi.org/10.2190/ns.21.3.m.

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Over the past 10 years, the science of green chemistry has continued to evolve and has been adopted in research labs in industry and academia. At the same time, new innovations in chemicals policy have widened opportunities for legislative action to protect human health and the environment. This article addresses the mechanisms by which the science of green chemistry and chemicals policy can work together to help attain a more sustainable future. It also speaks to the pitfalls of inappropriately merging these two, and explores how such a merger could inhibit the creation of sustainable technologies. Green chemistry's role in educational reform is discussed as a means for training students who are prepared to create truly sustainable technologies.
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17

Hernández Fernández, Francisco J., and Antonia Pérez de los Ríos. "Special Issue: Green Sustainable Chemical Processes." Processes 9, no. 7 (June 24, 2021): 1097. http://dx.doi.org/10.3390/pr9071097.

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18

Маммино, Лилиана, and Liliana Mammino. "Interdisciplinarity as a key to green chemistry education and education for sustainable development." Safety in Technosphere 7, no. 1 (August 9, 2018): 49–56. http://dx.doi.org/10.12737/article_5b5f0a8eb0c255.92407680.

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Green chemistry is the chemists’ contribution to sustainable development — a contribution whose fundamental role derives from the fundamental role of chemistry for development, embracing nearly all forms of industry and nearly all products used in everyday life. The ‘development’ concept entails a myriad of components related to various disciplines; pursuing sustainable development requires careful attention to all the aspects of each component. Green chemistry interfaces with all the areas of chemistry: organic chemistry, because most substances used in the chemical industry are organic; chemical engineering, because of the need to design new production processes; computational chemistry, because its role in the design of new substances with desired properties is apt for the design of new environmentally benign substances; and many others. Their inherently interdisciplinary nature needs to be reflected in the education for sustainable development and in green chemistry education at all levels of instruction, for learners to mature a comprehensive and realistic vision. The paper highlights the importance of such interdisciplinary outlooks and considers a number of illustrative examples.
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19

BHANDARI, SUNEETA. "APPLICATIONS OF GREEN CHEMISTRY PRINCIPLES IN AGRICULTURE." Green Chemistry & Technology Letters 4, no. 2 (September 29, 2018): 10–12. http://dx.doi.org/10.18510/gctl.2018.422.

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Green chemistry involves the design and development of products and processes that minimize or eliminate the use and generation of chemicals hazardous to the environment and human health. The principles of green chemistry involve the development of green catalysts and use of non-toxic reagents. Green chemistry emphasizes the use of reactions improved atom efficiency, use of solvent-free or environmentally benign recyclable solvent system and the use of renewable resources. Nowadays, green chemistry plays a new paradigm in the field of agriculture. Sustainable agriculture and green chemistry are both revolutionary fields and intertwined. In the last few years, for sustainable production in agriculture use of renewable biomass resources increases to generate bio-based food products with low inputs, zero waste, substantial social values and minimizing environmental impact. This article provides a good insight into green chemistry principles in sustainable agriculture.
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20

Rubab, Laila, Ayesha Anum, Sami A. Al-Hussain, Ali Irfan, Sajjad Ahmad, Sami Ullah, Aamal A. Al-Mutairi, and Magdi E. A. Zaki. "Green Chemistry in Organic Synthesis: Recent Update on Green Catalytic Approaches in Synthesis of 1,2,4-Thiadiazoles." Catalysts 12, no. 11 (October 29, 2022): 1329. http://dx.doi.org/10.3390/catal12111329.

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Green (sustainable) chemistry provides a framework for chemists, pharmacists, medicinal chemists and chemical engineers to design processes, protocols and synthetic methodologies to make their contribution to the broad spectrum of global sustainability. Green synthetic conditions, especially catalysis, are the pillar of green chemistry. Green chemistry principles help synthetic chemists overcome the problems of conventional synthesis, such as slow reaction rates, unhealthy solvents and catalysts and the long duration of reaction completion time, and envision solutions by developing environmentally benign catalysts, green solvents, use of microwave and ultrasonic radiations, solvent-free, grinding and chemo-mechanical approaches. 1,2,4-thiadiazole is a privileged structural motif that belongs to the class of nitrogen–sulfur-containing heterocycles with diverse medicinal and pharmaceutical applications. This comprehensive review systemizes types of green solvents, green catalysts, ideal green organic synthesis characteristics and the green synthetic approaches, such as microwave irradiation, ultrasound, ionic liquids, solvent-free, metal-free conditions, green solvents and heterogeneous catalysis to construct different 1,2,4-thiadiazoles scaffolds.
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21

Turner, Charlotta. "Sustainable analytical chemistry—more than just being green." Pure and Applied Chemistry 85, no. 12 (December 1, 2013): 2217–29. http://dx.doi.org/10.1351/pac-con-13-02-05.

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This review article describes analytical chemistry beyond green chemistry and all efforts that contribute to a more sustainable development. A background is given on sustainable development and green chemistry. Examples of “greening” strategies for sample preparation, chromatography, and detection are given. Thereafter, the review discusses how and why a method or a solvent could be claimed as being “green”. Green metrics for analytical chemistry is discussed, including the environment, health, and safety (EHS) index and life cycle assessment (LCA). The choice of solvent and the criteria for a solvent being “green” is also discussed. Finally, sustainable analytical chemistry is described by considering the three important “legs” so as to obtain sustainable development—economic feasibility, societal relevance, and environmental soundness. Hopefully, the review article will stimulate some new perspectives on the difference between greenness and sustainability in analytical chemistry.
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22

Pavez, Paulina, Jessica Honores, Daniela Millán, and Mauricio Isaacs. "UN sustainable development goals: How can sustainable/green chemistry contribute?" Current Opinion in Green and Sustainable Chemistry 13 (October 2018): 154–57. http://dx.doi.org/10.1016/j.cogsc.2018.06.013.

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23

Dhage, Suresh D., and Komalsing K. Shisodiya. "APPLICATIONS OF GREEN CHEMISTRY IN SUSTAINABLE DEVELOPMENT." INTERNATIONAL RESEARCH JOURNAL OF PHARMACY 4, no. 7 (August 10, 2013): 1–4. http://dx.doi.org/10.7897/2230-8407.04701.

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24

Aldred, Joanna M. "Conference Report: Green and Sustainable Chemistry Conference." Sustainable Chemistry and Pharmacy 4 (December 2016): 81–83. http://dx.doi.org/10.1016/j.scp.2016.07.005.

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25

Aldred, Joanna M. "Conference report: Green and Sustainable Chemistry Conference." Current Opinion in Green and Sustainable Chemistry 1 (August 2016): I—III. http://dx.doi.org/10.1016/j.cogsc.2016.07.007.

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26

Aldred, Joanna M. "Conference report: Green and Sustainable Chemistry Conference." Current Opinion in Green and Sustainable Chemistry 9 (February 2018): 45–48. http://dx.doi.org/10.1016/j.cogsc.2017.12.002.

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27

Burgman, Mark, Mike Tennant, Nikolaos Voulvoulis, Karen Makuch, and Kaveh Madani. "Facilitating the transition to sustainable green chemistry." Current Opinion in Green and Sustainable Chemistry 13 (October 2018): 130–36. http://dx.doi.org/10.1016/j.cogsc.2018.04.006.

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28

Srivastava, Pankaj, Rajeev Rajput, Mukesh Ruhela, Munendra Varshney, and Dheeraj Kumar. "Wastes encountered by green chemistry." Environment Conservation Journal 9, no. 1&2 (June 16, 2008): 105–8. http://dx.doi.org/10.36953/ecj.2008.091221.

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Green chemistry involves an economically sustainable view of chemical research, development and manufacture and is dedicated to chemistry to benefit society. Now a days green chemistry is universally accepted term to reveal the movement towards more environmentally accepted chemical processes and products.
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29

West, Julian G. "A blueprint for green chemists: lessons from nature for sustainable synthesis." Pure and Applied Chemistry 93, no. 5 (March 25, 2021): 537–49. http://dx.doi.org/10.1515/pac-2021-0107.

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Abstract The design of new chemical reactions that are convenient, sustainable, and innovative is a preeminent concern for modern synthetic chemistry. While the use of earth abundant element catalysts remains underdeveloped by chemists, nature has developed a cornucopia of powerful transformation using only base metals, demonstrating their viability for sustainable method development. Here we show how study of nature’s approach to disparate chemical problems, from alkene desaturation to photodetection in bacteria, can inspire and enable new approaches to difficult synthetic chemistry problems past, present, and future.
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30

Hitce, Julien, Jinzhu Xu, Maude Brossat, Marie-Céline Frantz, Anne-Claude Dublanchet, Michel Philippe, and Maria Dalko-Csiba. "UN sustainable development goals: How can sustainable/green chemistry contribute? Green chemistry as a source of sustainable innovations in the cosmetic industry." Current Opinion in Green and Sustainable Chemistry 13 (October 2018): 164–69. http://dx.doi.org/10.1016/j.cogsc.2018.06.019.

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31

Paristiowati, Maria, Zulmanelis Zulmanelis, and Muhamad Fazar Nurhadi. "GREEN CHEMISTRY-BASED EXPERIMENTS AS THE IMPLEMENTATION OF SUSTAINABLE DEVELOPMENT VALUES." JTK (Jurnal Tadris Kimiya) 4, no. 1 (June 30, 2019): 11–20. http://dx.doi.org/10.15575/jtk.v4i1.3566.

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The development of a chemistry experiment based on green chemistry aims to train and familiarize students to save on the use of chemicals, replace them with safer materials and minimize waste generated from experimental activities. Research and development methods are used to develop experimental modules based on green chemistry. The stages of research and development consist of needs analysis, product development, and product testing. The developed experiment module, implements three principles of green chemistry, i.e. preventing waste, safer chemical planning and safe use of solvents. The feasibility test by expert judgement on the material and media obtained scores 91.9% and 94.7% respectively. The results of the trials in small groups and large groups showed that the developed module was feasible to use. Student perceptions after using the module show positive results. The conclusions from the results of the feasibility test and the trial conducted indicate that the green chemistry-based kinetics' module has good criteria and in accordance with the wishes and needs of students. In addition, the implementation of this module in the kinetics experiment succeeded in making students understand and apply the principles of green chemistry. As many as 90% of students realize that there is a relationship between the application of the principles of green chemistry and the educational paradigm for sustainable development. The use of kinetics' module based on green chemistry also saved the cost of experiment material requirements by 75% per year.
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32

Das, Ananya, Abir Sadhukhan, Soumallya Chakraborty, Somenath Bhattacharya, Dr Amitava Roy, and Dr Arin Bhattacharjee. "Role of Green Chemistry in Organic Synthesis and Protection of Environment." International Journal for Research in Applied Science and Engineering Technology 10, no. 12 (December 31, 2022): 1850–53. http://dx.doi.org/10.22214/ijraset.2022.48373.

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Abstract: Nowadays green chemistry plays a vital role in organic chemistry. It minimizes the effect and use of hazardous substances on the environment and human health. The main goal of green chemistry is to use of green solvents (PEG, water, acetone, alcohol) eliminate the toxicity, uses of small quantity of catalyst and minimize the potential for chemical accident during work. Green chemistry is one type of chemistry where main focus is to eliminate or minimize the hazards by applying suitable process and raw materials. So it is more effective to pharmacists or chemists for avoiding this bad impact on human health, environment. Green chemistry also known as sustainable chemistry. Green chemistry is always interesting matter to pharmacists as well as chemists for synthesis pharmaceutical products. Green chemistry brings a new path for synthesizing safer chemical products. For manufacturing pharmaceutical products by using green chemistry, there have many criteria or methods that should be followed for synthesis chemical products during manufacturing condition. Some of these are prevention waste, Atom economy, less hazardous chemical syntheses, designing safer chemicals, safer solvents, design for more energy efficient chemical, use of renewable feed stocks, reduce derivatives in any compounds, catalysis, design for degradation, real time analysis for pollution prevention, inherently safer for accident prevention, etc. These methods should be considerable before synthesized chemical products by applying green chemistry for eliminating or minimizing hazardous in chemical products during synthesis.
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33

Kidwai, M. "Green chemistry trends toward sustainability." Pure and Applied Chemistry 78, no. 11 (January 1, 2006): 1983–92. http://dx.doi.org/10.1351/pac200678111983.

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Green chemistry is not an emerging trend, but is already a reality owing to its applications. A large number of case studies are presented here in addition to literature work. The case studies cover new approaches and new experiments, which will articulate the requirement for industrial application of sustainable chemistry.
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34

Mulvihill, Martin J., Evan S. Beach, Julie B. Zimmerman, and Paul T. Anastas. "Green Chemistry and Green Engineering: A Framework for Sustainable Technology Development." Annual Review of Environment and Resources 36, no. 1 (November 21, 2011): 271–93. http://dx.doi.org/10.1146/annurev-environ-032009-095500.

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35

Postnikov, Pavel S., Marina Trusova, Ksenia Kutonova, and Viktor Filimonov. "Arenediazonium salts transformations in water media: Coming round to origins." Resource-Efficient Technologies, no. 1 (June 30, 2016): 36–42. http://dx.doi.org/10.18799/24056529/2016/1/37.

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Aromatic diazonium salts belong to an important class of organic compounds. The chemistry of these compounds has been originally developedin aqueous media, but then chemists focused on new synthetic methods that utilize reactions of diazonium salts in organic solvents. However, according to the principles of green chemistry and resource-efficient technologies, the use of organic solvents should be avoided. This review summarizes new trends of diazonium chemistry in aqueous media that satisfy requirements of green chemistry and sustainable technology.
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36

Claux, Ombéline, Cyrille Santerre, Maryline Abert-Vian, David Touboul, Nadine Vallet, and Farid Chemat. "Alternative and sustainable solvents for green analytical chemistry." Current Opinion in Green and Sustainable Chemistry 31 (October 2021): 100510. http://dx.doi.org/10.1016/j.cogsc.2021.100510.

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37

Maertens, Alexandra, Emily Golden, and Thomas Hartung. "Avoiding Regrettable Substitutions: Green Toxicology for Sustainable Chemistry." ACS Sustainable Chemistry & Engineering 9, no. 23 (June 1, 2021): 7749–58. http://dx.doi.org/10.1021/acssuschemeng.0c09435.

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38

Ganesh, Krishna N., Deqing Zhang, Scott J. Miller, Kai Rossen, Paul J. Chirik, Marisa C. Kozlowski, Julie B. Zimmerman, et al. "Green Chemistry: A Framework for a Sustainable Future." Organometallics 40, no. 12 (June 15, 2021): 1801–5. http://dx.doi.org/10.1021/acs.organomet.1c00343.

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39

Ganesh, Krishna N., Deqing Zhang, Scott J. Miller, Kai Rossen, Paul J. Chirik, Marisa C. Kozlowski, Julie B. Zimmerman, et al. "Green Chemistry: A Framework for a Sustainable Future." Organic Letters 23, no. 13 (June 15, 2021): 4935–39. http://dx.doi.org/10.1021/acs.orglett.1c01906.

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40

Ganesh, Krishna N., Deqing Zhang, Scott J. Miller, Kai Rossen, Paul J. Chirik, Marisa C. Kozlowski, Julie B. Zimmerman, et al. "Green Chemistry: A Framework for a Sustainable Future." Environmental Science & Technology 55, no. 13 (June 15, 2021): 8459–63. http://dx.doi.org/10.1021/acs.est.1c03762.

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41

Ganesh, Krishna N., Deqing Zhang, Scott J. Miller, Kai Rossen, Paul J. Chirik, Marisa C. Kozlowski, Julie B. Zimmerman, et al. "Green Chemistry: A Framework for a Sustainable Future." Organic Process Research & Development 25, no. 7 (June 15, 2021): 1455–59. http://dx.doi.org/10.1021/acs.oprd.1c00216.

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42

Ganesh, Krishna N., Deqing Zhang, Scott J. Miller, Kai Rossen, Paul J. Chirik, Marisa C. Kozlowski, Julie B. Zimmerman, et al. "Green Chemistry: A Framework for a Sustainable Future." ACS Sustainable Chemistry & Engineering 9, no. 25 (June 15, 2021): 8336–40. http://dx.doi.org/10.1021/acssuschemeng.1c03891.

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43

Ganesh, Krishna N., Deqing Zhang, Scott J. Miller, Kai Rossen, Paul J. Chirik, Marisa C. Kozlowski, Julie B. Zimmerman, et al. "Green Chemistry: A Framework for a Sustainable Future." Industrial & Engineering Chemistry Research 60, no. 25 (June 15, 2021): 8964–68. http://dx.doi.org/10.1021/acs.iecr.1c02213.

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Ganesh, Krishna N., Deqing Zhang, Scott J. Miller, Kai Rossen, Paul J. Chirik, Marisa C. Kozlowski, Julie B. Zimmerman, et al. "Green Chemistry: A Framework for a Sustainable Future." Environmental Science & Technology Letters 8, no. 7 (June 15, 2021): 487–91. http://dx.doi.org/10.1021/acs.estlett.1c00434.

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45

Ganesh, Krishna N., Deqing Zhang, Scott J. Miller, Kai Rossen, Paul J. Chirik, Marisa C. Kozlowski, Julie B. Zimmerman, et al. "Green Chemistry: A Framework for a Sustainable Future." ACS Omega 6, no. 25 (June 15, 2021): 16254–58. http://dx.doi.org/10.1021/acsomega.1c03011.

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Ganesh, Krishna N., Deqing Zhang, Scott J. Miller, Kai Rossen, Paul J. Chirik, Marisa C. Kozlowski, Julie B. Zimmerman, et al. "Green Chemistry: A Framework for a Sustainable Future." Journal of Organic Chemistry 86, no. 13 (June 15, 2021): 8551–55. http://dx.doi.org/10.1021/acs.joc.1c01355.

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47

Rita, Földényi. "First EuCheMS Congress on Green and Sustainable Chemistry." Green Processing and Synthesis 3, no. 2 (April 1, 2014): 101. http://dx.doi.org/10.1515/gps-2014-0019.

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48

Gu, Yanlong, and François Jérôme. "Glycerol as a sustainable solvent for green chemistry." Green Chemistry 12, no. 7 (2010): 1127. http://dx.doi.org/10.1039/c001628d.

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49

Phair, John W. "Green chemistry for sustainable cement production and use." Green Chemistry 8, no. 9 (2006): 763. http://dx.doi.org/10.1039/b603997a.

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50

Liu, Zhimin, and Klaus Kümmerer. "Editorial overview: Green and sustainable chemistry conference 2017." Current Opinion in Green and Sustainable Chemistry 9 (February 2018): A1—A2. http://dx.doi.org/10.1016/j.cogsc.2018.04.014.

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