PATH OF GREEN CHEMISTRY AND SUSTAINABLE DEVELOPMENT
AKBARE AZAM *
Department of Chemistry, Government Women P. G. College, Ghazipur, Uttar Pradesh, India.
*Author to whom correspondence should be addressed.
Abstract
Science achieved medicinal unrest till about the center of twentieth century wherein medications and anti-infection agents were found. The world's sustenance supply likewise expanded massively because of the disclosure of half and half assortments, improved techniques for cultivating, better seeds and utilization of bug sprays, herbicides and manures. The personal satisfaction on earth turned out to be vastly improved because of the disclosure of colors, plastics, beauty care products and different materials. Before long, the evil impacts of science likewise wound up articulated, fundamental among them being the contamination of land, water and environment. This is caused basically because of the impacts of results of compound businesses, which are being released into the air, streams/seas and the land. The utilization of harmful reactants and reagents additionally exacerbate things. The contamination achieved such levels that various governments made laws to limit it. This denoted the start of Green Chemistry by the center of 29th century. Practical Chemistry is an idea which adds to accomplishing various objectives of the 2030 Agenda for Sustainable Development (SDGs). It is based among others on the standards of "green science" and has interfaces with significant points for example asset protection, squander the board, word related security, worker and purchaser wellbeing and nourishment. Supportable science joins environmentally suitable arrangements with financial accomplishment under thought of societal and social requests.
Keywords: Sustainable chemistry, green chemistry, hybrid varieties, compound businesses.
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Cespi D, Beach ES, Swarr TE, Passarini F, Vassura I, Dunn PJ, Anastas PT. Life cycle inventory improvement in the pharmaceutical sector: Assessment of the sustainability combining PMI and LCA tools, Green Chem. 2015;17:3390-3400.
Raynie D, Driver J. Green assessment of chemical methods, in: 13th Annual Green Chemistry and Engineering Conference, Maryland; 2009.
de la Guardia M. An integrated approach of analytical chemistry, J. Braz. Chem. Soc. 1999; 10:429-437.
Garrigues S, Armenta S, de la Guardia M. Green strategies for decontamination of analytical wastes, Trends Anal. Chem. 2010; 29:592-601.
Csiba M, Cleophax J, Loupy A, Malthete J, Gero SD. Tetrahederon Letters. 1993;34:1787-1790.
Draths KM, Frost JW. Green Chemistry: Frontier in benign chemical synthesis and processes, Chapter 9; 1999.
Chong M, Lokpovsky EB, Coates GW. J. Am. Chem. Soc. 1998;120:11018-11019.
Kradtap Hartwell S. Exploring the potential for using inexpensive natural reagents extracted from plants to teach chemical analysis, Chem. Educ. Res. Pract. 2012;13:135-146.
de la Guardia M, Ruzicka J. Towards environmentally conscientious analytical chemistry through miniaturization, containment and reagent replacement, Analyst. 1995;120: 17N.
Green DW, Smith LL, JS Crain, Boparai AS, Kiely JT, Yaeger JS, Schilling JB. Waste minimization in analytical methods, DOE Pollution Prevention Conference XI Knoxville; 1995.
Płotka-Wasylka J. A new tool for the evaluation of the analytical procedure: Green Analytical Procedure Index, Talanta. 2018;181: 204-209.
Ahluwalia VK, Kidwai M. Green chemistry: An innovative technology. Foundations of Chemistry. 2005;7(3):269-289.
Constable DJC, Curzons AD, Cunningham VL. Metrics to ‘Green’ chemistry, which are the best? Green Chem. 2002;4:521-527.
Namiesnik J. Green analytical chemistry e some remarks, J. Separ. Sci. 2001;24:151-153.
Płotka-Wasylka JM, Kurowska-Susdorf A, Sajid M, de la Guardia M, Namiesnik J, Tobiszewski M. Green chemistry in higher education: State of the art, challenges and future trends, ChemSusChem. 2018;11:2845-2858.
de la Guardia M, Garrigues S. An ethical commitment and an economic opportunity, in: M. de la Guardia, S. Garrigues (Editors), Challenges in Green Analytical Chemistry, Royal Society of Chemistry. 2011;1-12.
de la Guardia M, Armenta S. Origins of green analytical chemistry, in: M. de la Guardia, S. Armenta (Editors), Green Analytical Chemistry, Comprehensive Analytical Chemistry. 2011;57:1-23.
Ho NWY, Chen Z, Brainard AP, Sedlak M. Green chemical synthesis and processes ACS. Chapter 12. 2000;248.
Wilkinson SL. Green’ is practical, Even Profitable, No Longer a Luxury, Green Chemistry Becomes a Central Strategy for Sustainable Firms. Chem. Eng. News. 1997;7 (5):35-43.
Yadav JS, Reddy KB, Raj KS, Prasad AR. Perkin transaction. Journal of Chemical Society. 2000;1: 1939-1941.
Zujang M, Henz T, Curtis R, Schertenleib, Beal LL. Water Science and Technology: A Journal of International Association on water Pollution Research. 2004;49(8):1-10.
Singh A, Sharma R, Anand KM, Khan SP, Sachan NK. Food-drug interaction. International Journal of Pharmaceutical & Chemical Science. 2012;1(1):264-279.
Synthetic pathways and processes in green chemistry: Introductory overview. Pure Applied Chemistry. 2009;72(7):1207–1228.
Phan TVT, Gallardo C, Mane J. Green motion: A new and easy to use green chemistry metric from laboratories to industry. Green Chem. 2015;17:2846-2852.