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Introduction
“Plastics” stand atop a pile of petrochemical based products in terms of global significance (Degli Espositi et al., 2021). Important properties like durability and cost effectiveness make plastics almost indispensable (Lear et al., 2021). They are useful both locally and industrially to man’s daily life. They show numerous applications in industrial packaging, food packaging, bottling, technology developments, platforms, medicine, and also automobiles (Yildizhan, 2021). The flipside to these numerous global benefits is the environmental concerns they bring along; plastics are not readily biodegradable and as such pose threats to global health, the immediate environment and ocean life (Narancic and O’Connor, 2019).
However, plastics from biodegradable materials are being researched and tested (Shen et al., 2020). These new type of plastics are produced from different natural biomass and they are degradable (Rao et al., 2021). Adjustments need to be made as the goal is to ensure production of plastics that are biodegradable, low in cost and can replace the synthetic plastics in the capacity of its daily usage (Shafqat et al., 2020).
Plastics are synthetic polymers that show similarities to natural polymers attained from plants and other biological elements (Kubowicz and Booth, 2017). The present yearly global production capacity of synthetic plastics sits at about forty million tonnes (Yildizhan, 2021). In developed countries, billions of plastic bottles are usually processed and synthesized annually (Stapleton, 2019). These developments translates into almost a quarter of global landfills occupied by plastic wastes, hence a significant contribution to global environmental pollution (Canopoli et al., 2018).
The geometric progressions at which oil-based plastics are being made use of globally is a serious global issue (Turner, 2021). This is as a result of slowly developing infrastructural frameworks proposed for the management of plastic wastes. (Danso et al., 2019). Developments in the implementations of these infrastructural frameworks are presently taking place at a slow rate compared to the exponential increase in plastic wastes globally (Zhu et al., 2019). Various proper “STEM” research with respect to the development of novel technologies and materials in the “plastics” area are presently championed, and carried out (Iram et al., 2019). With the current level of global exposure to the adverse effects of oil-based plastics, there is a need to explore the possibilities and potentials of bio-plastics (Bano et al., 2017). Bio-plastics could be seen as the future of the “plastic” world (Bhagwat et al., 2020).
Oil-based plastics are usually the most globally utilized plastics in the world of “plastics” (Yimyai et al., 2020). They are usually synthesized via the addition or condensation polymerization reaction. These techniques are among the most globally used techniques in synthesizing diverse polymers (Lambert and Wagner, 2017).
Biodegradable plastic stands atop many effective and efficient answers to the “plastic problem” (Fotopoulou and Karapanagioti, 2017). A major component that differentiates bioplastics from the common synthetic plastic is the presence of PolyHydroxylAlkanoate (PHA); this contributes to the biodegradability of bioplastics (Zimmermann et al., 2020). Bioplastics are similar to synthetic plastics in properties and other aspects, which makes them perfect substitutes for synthetic plastics (Pira, 2019). Bioplastics could exist as a full composition of the bioplastic itself or as a blend of bioplastics with other petro-chemical based products (White et al., 2020). This provides an optimal way of replacing fully synthetic plastics while also maintaining their significantly beneficial properties (Bishop et al., 2021).
The research of production of biodegradable plastics did not just begin today, it had started a long time ago, but as the need for these form of plastics has become very essential and a major goal (Sidek et al., 2019). In 1980, bioplastics were introduced, the purpose was to have plastics that are commonly decomposed, decompose on landfills so they would not take space (Lothfy et al., 2018). The use of starch as a natural, raw material for degradable thermoplastic is an important goal (.Filiciotto and Rothenberg, 2021). However, starch alone cannot form plastics with satisfactory chemical and mechanical properties, thus using a modifier are important to improve these properties (Hwang et al., 2020).
Problem Statement
Plastics are synthetic polymers that show similarities to natural polymers attained from plants and other biological elements (Osswald et al., 2019). The present yearly global production capacity of synthetic plastics sits at about forty million tonnes. In developed countries, billions of plastic bottles are usually processed and synthesized annually. These developments translates into almost a quarter of global landfills occupied by plastic wastes, hence a significant contribution to global environmental pollution (Yildhizan, 2021; Stapleton, 2019; Canopoli et al., 2018) .
Plastic is the best amongst all the others due to its lifelong properties. But, plastics cannot be degraded by natural processes in short periods and are left in the environment as solid waste, causing a lot of environmental pollution (Thakur et al., 2018). Burning or burying is not suitable for them as they emit materials that are detrimental, both to the environment and humans (Rahman and Bhoi, 2021). As many countries are banning the use of these oil based plastics, there needs to be a replacement and this replacement needs to be able to carry out the job the traditional plastics does (Arikan and Bilgen, 2019). This led to the research into the production of biodegradable plastics, which has therefore been the response to the problems associated with the plastic waste (Gadhave et al., 2018).
Aim and Objectives
The aim of this research project is to optimally synthesize biodegradable plastic films from agricultural wastes; using banana peels as the primary feedstock, with the following objectives:
Research Questions
The identified research questions for this project are provided below:
Deliverables
The deliverables of these project are a project report, samples of the synthesized products and gotten results. The synthesized products would be tested according to industry standards and literature to see how they compare with required standards. Also, the report should contain a complete documentation of how the laboratory experiment was carried out, how various process variables were gotten, how the desired products were synthesized and how the results were arrived at.
Relevance
Biodegradable plastics is a form of “prevention is better than cure” treatment, this is a preventive method of taking care of the problem of plastic pollution rather than treatment method.
Methodology
This project focuses on secondary research, laboratory experiments and process analysis, and they are discussed below:
Secondary research
The secondary research in this project will utilize a systematic approach (Johnson et al., 2016) to review the works of literature. The steps involved in the systematic review of the literature are provided below:
Laboratory experiments
The laboratory experiments would cover a large chunk of this project. They would be carried out in stages, and as such described below;
Process Analysis
The totality of the process reaction would be analyzed and this would also occur in stages;
Evaluation
The risk assessment conducted for this project is provided in the table below:
Table 1: Risk assessment
Risk
Impact
Mitigation Plan
Inability to meet the deadline
Low
Get an extension from the supervisor in due time
Inability to get required process inputs
High
Refer to municipalities, research institutes and laboratory technicians for help
Inability to develop the process set up
Refer to laboratory technicians for help
Insufficient data
Refer to journals and textbooks for help
Schedule
Table 2: Project Plan
Task Name
Start Date
End Date
Duration (Days)
Initial Research
23/09/2021
07/10/2021
14
Proposal
28/10/2021
21
Secondary Research
07/12/2021
40
Introduction Chapter
12/12/2021
5
Literature Review Chapter
05/01/2022
24
Methodology Chapter
17/01/2022
12
Sourcing of Required Feedstock
15/03/2022
60
Presentation 1
23/03/2022
8
Laboratory Experiments
06/04/2022
Evaluation of Gotten Results
13/04/2022
7
Discussion Chapter
23/04/2022
10
Evaluation Chapter
28/04/2022
Conclusion Chapter
30/04/2022
2
Project Management Chapter
01/05/2022
Abstract and Report compilation
03/05/2022
Report Proofreading
13/05/2022
Presentation 2
23/05/2022
Reference
Arikan, E.B. and Bilgen, H.D., 2019. Production of bioplastic from potato peel waste and investigation of its biodegradability. International Advanced Researches and Engineering Journal, 3(2), pp.93-97.
Bano, K., Kuddus, M., R Zaheer, M., Zia, Q., F Khan, M., Gupta, A. and Aliev, G., 2017. Microbial enzymatic degradation of biodegradable plastics. Current pharmaceutical biotechnology, 18(5), pp.429-440.
Bhagwat, G., Gray, K., Wilson, S.P., Muniyasamy, S., Vincent, S.G.T., Bush, R. and Palanisami, T., 2020. Benchmarking bioplastics: A natural step towards a sustainable future. Journal of Polymers and the Environment, pp.1-21.
Bishop, G., Styles, D. and Lens, P.N., 2021. Environmental performance comparison of bioplastics and petrochemical plastics: A review of life cycle assessment (LCA) methodological decisions. Resources, Conservation and Recycling, 168, p.105451.
Canopoli, L., Fidalgo, B., Coulon, F. and Wagland, S.T., 2018. Physico-chemical properties of excavated plastic from landfill mining and current recycling routes. Waste Management, 76, pp.55-67.
Danso, D., Chow, J. and Streit, W.R., 2019. Plastics: environmental and biotechnological perspectives on microbial degradation. Applied and environmental microbiology, 85(19).
Degli Esposti, M., Morselli, D., Fava, F., Bertin, L., Cavani, F., Viaggi, D. and Fabbri, P., 2021. The role of biotechnology in the transition from plastics to bioplastics: an opportunity to reconnect global growth with sustainability. FEBS Open bio, 11(4), pp.967-983.
Filiciotto, L. and Rothenberg, G., 2021. Biodegradable Plastics: Standards, Policies, and Impacts. ChemSusChem, 14(1), p.56.
Fotopoulou, K.N. and Karapanagioti, H.K., 2017. Degradation of various plastics in the environment. In Hazardous Chemicals Associated with Plastics in the Marine Environment (pp. 71-92). Springer, Cham.
Gadhave, R.V., Das, A., Mahanwar, P.A. and Gadekar, P.T., 2018. Starch based bio-plastics: the future of sustainable packaging.
Hwang, K.R., Jeon, W., Lee, S.Y., Kim, M.S. and Park, Y.K., 2020. Sustainable bioplastics: Recent progress in the production of bio-building blocks for the bio-based next-generation polymer PEF. Chemical Engineering Journal, 390, p.124636.
Iram, D., Riaz, R. and Iqbal, R.K., 2019. Usage of potential micro-organisms for degradation of plastics. Open Journal of Environmental Biology, 4(1), pp.007-015.
Johnson, D., Deterding, S., Kuhn, K.A., Staneva, A., Stoyanov, S. and Hides, L., 2016. Gamification for health and wellbeing: A systematic review of the literature. Internet interventions, 6, pp.89-106.
Kubowicz, S. and Booth, A.M., 2017. Biodegradability of plastics: challenges and misconceptions.
Lambert, S. and Wagner, M., 2017. Environmental performance of bio-based and biodegradable plastics: the road ahead. Chemical Society Reviews, 46(22), pp.6855-6871.
Lear, G., Kingsbury, J.M., Franchini, S., Gambarini, V., Maday, S.D.M., Wallbank, J.A., Weaver, L. and Pantos, O., 2021. Plastics and the microbiome: impacts and solutions. Environmental Microbiome, 16(1), pp.1-19.
Lothfy, F.A., Nor, A.M., Senawi, S.A., Zainuddin, N.S.A., Mohmad, E., Norzeri, N.A.S., Bahri, N.Y.S.S., Azmi, P.E.N.M. and Kamaruzaman, A.N., 2018. MECHANICAL PROPERTIES OF BIOPLASTIC FROM JACKFRUIT SEED FLOUR AND POLYPROPYLENE. Malaysian Journal of Analytical Sciences, 22(3), pp.429-434.
Mitra, R., Xu, T., Xiang, H. and Han, J., 2020. Current developments on polyhydroxyalkanoates synthesis by using halophiles as a promising cell factory. Microbial cell factories, 19, pp.1-30.
Narancic, T. and O'Connor, K.E., 2019. Plastic waste as a global challenge: are biodegradable plastics the answer to the plastic waste problem?. Microbiology, 165(2), pp.129-137.
Osswald, T.A., Baur, E. and Rudolph, N., 2019. Plastics handbook: the resource for plastics engineers. Carl Hanser Verlag GmbH Co KG.
Pira, S., 2019. The Future of Bioplastics for Packaging to 2024.
Rahman, M.H. and Bhoi, P.R., 2021. An overview of non-biodegradable bioplastics. Journal of Cleaner Production, p.126218.
Rao, L.S., Naidu, C.D. and Tiwari, S., 2021. Investigation on synthesis, structure and degradability of starch based bioplastics. Materials Today: Proceedings.
Shafqat, A., Tahir, A., Mahmood, A. and Pugazhendhi, A., 2020. A review on environmental significance carbon foot prints of starch based bio-plastic: A substitute of conventional plastics. Biocatalysis and Agricultural Biotechnology, p.101540.
Shen, M., Song, B., Zeng, G., Zhang, Y., Huang, W., Wen, X. and Tang, W., 2020. Are biodegradable plastics a promising solution to solve the global plastic pollution?. Environmental Pollution, 263, p.114469.
Sidek, I.S., Draman, S.F.S., Abdullah, S.R.S. and Anuar, N., 2019. Current Development on Bioplastics and Its Future Prospects: An Introductory Review. INWASCON Technology Magazine, 1, pp.03-08.
Stapleton, P.A., 2019. Toxicological considerations of nano-sized plastics. AIMS environmental science, 6(5), p.367.
Thakur, S., Chaudhary, J., Sharma, B., Verma, A., Tamulevicius, S. and Thakur, V.K., 2018. Sustainability of bioplastics: Opportunities and challenges. Current opinion in Green and Sustainable chemistry, 13, pp.68-75.
Turner, M.M., 2021. Degradation of Plastics in in Environment: A Review on Ecotoxicological Effects.
White, E., Bassilakis, R. and Nogués, S., 2020. From the Plastics Present to a Sustainable Future: The Bioplastics Innovation Landscape, Players and Market Opportunities.
Yildizhan, F.S., 2021. A Technical and Industrial Analysis of Global Plastics Market, Trade, Financing, and Operations. ScienceOpen Preprints.
Yimyai, T., Phakkeeree, T. and Crespy, D., 2020. Tattooing Plastics with Reversible and Irreversible Encryption. Advanced Science, 7(13), p.1903785.
Zhu, Y., Zhu, D., Xu, T. and Ma, J., 2019. Impacts of (micro) plastics on soil ecosystem: progress and perspective. Journal of Agro-Environment Science, 38(1), pp.1-6.
Zimmermann, L., Dombrowski, A., Völker, C. and Wagner, M., 2020. Are bioplastics and plant-based materials safer than conventional plastics? In vitro toxicity and chemical composition. Environment International, 145, p.106066.
Last updated: Sep 29, 2021 07:56 PM
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