Textiles from orange peel waste

Science & Technology Development Journal, 23(2):508-516 Open Access Full Text Article Review DST-INSPIRE Fellow & Assistant Professor; Department of Textiles and Clothing, Avinashilingam Institute for Home Science and Higher Education for Women, Coimbatore, India Correspondence SachidhanandhamAishwariya, DST-INSPIRE Fellow & Assistant Professor; Department of Textiles and Clothing, Avinashilingam Institute for Home Science and Higher Education for Women, Coimbatore, India Email: aishu55@gmail.com History  Received: 2019-11-25  Accepted: 2020-04-20  Published: 2020-06-01 DOI : 10.32508/stdj.v23i2.1730 Copyright © VNU-HCM Press. This is an open- access article distributed under the terms of the Creative Commons Attribution 4.0 International license. Textiles from orange peel waste SachidhanandhamAishwariya* Use your smartphone to scan this QR code and download this article ABSTRACT The global textile business is now gearing towards greener alternatives to combat pollution and avoid synthetics in production. Ironically, there is an increased awareness among consumers on the quality of the product and choices they make in their shopping. The natural and synthetic fi- bres have set limitations, which has made manufacturers look out for other alternative fibres. Bam- boo, banana, milk, and corn are experimented for its commercial capabilities to perform as a textile material. To add on to the list, orange, the popular, and the most preferred fruit are known for its refreshing flavour. The peels after consumption/ processing of the fruit are discarded in the landfill, which is an organic waste with immense potential. This paper details the successful brand `Orange fibre', its journey from scratch, and the properties of textiles made from processing orange peel waste. The current areas of research have also been covered in a brief way, to invite more scholars to create solutions for the hitherto pollution orange peel waste. Key words: orange peel waste, organic waste, sustainable textiles, eco-friendly fibres, renewable fibres, regenerated cellulose, orange fiber INTRODUCTION Natural fibres like cotton, silk, and wool were utilized for the maximum by humans to a maximum possible timeline. Nineteenth-century proposed the replace- ment of natural fibres with synthetics with excellent performance properties that ruled for another hun- dred years now1. The petrochemical-derived fibres like polyester are a source of micro-plastic pollution, non-bio-degradable, toxic, and a threat to humans. Today, agriculture wastes and other organic wastes are seen as a potential renewable, biodegradable material to be made into textiles 2. POPULARITY OF ORANGES Orange production is approximately 51.8 million metric tonnes in 2014 3. The commonly consumed fruits worldwide are banana, apple, grapes, straw- berry, and orange. In many countries, orange juice is an essential entity in breakfast to cater to the ev- eryday recommended dose of vitamin C. Oranges are the richest source of vitamins, minerals, and energy, which has the ability to give an instant refreshment4. The regular consumption of orange helps in the effec- tive functioning of the heart, kidney, and aids infer- tility. There are other health benefits for skin, teeth, and bone, along with maintaining the normal blood pressure and cholesterol levels in the body5. Orange is one of the varieties in citrus fruit family, and other popular ones include lemon, mosambi, sweet lime, mandarins, and grapefruit. Nearly seventy percent of the orange fruits are used in the food processing in- dustry for making juice, jam, syrups, sweets, pectin, flavonoid, and fibres. It is also used inmaking refresh- ing drinks to induce smell, flavor, energy, and color. The list of uses for the fruit goes endless, whereas the peel that is a by-product of processing has fewer re- cycling options. For instance, the lemon peel is used to extract pectin and some varieties of citrus fruit for making cosmetics6. The top producers of orange are Brazil, USA, India, China, Mexico, Spain, Egypt, and Italy. Brazil pro- duces 1.8 million tonnes of orange per year. Approxi- mately 15 – 25 million tonnes of peel waste are found on landfill without recycling or composting. The transportedwaste is thrown in landfills or incinerated. These peels dumped on a site can be a threat to the en- vironment and human health. They may decompose, give away foul odour, microbial infestation, attract flies, and risk of spreading diseases during the rainy season. The baseline is the huge tonnes of orange peel waste is a menace. Two ecologists Daniel Janzen and Winnie Hallwachs in 1997, dumped 12,000 tonnes of orange peel over degrading lifeless soil in Amazon (Figure 1 ). The selected area was a victim of burn- ing trees in the forest for installing oil refineries. Six- teen years later, when the couple returned, they were amazed by the bio-diversity, rich landscapes, biomass that are a result of citrus peel waste7. This is an exam- ple to insist on the power of organic waste. Cite this article : Aishwariya S. Textiles from orange peel waste. Sci. Tech. Dev. J.; 23(2):508-516. 508 Science & Technology Development Journal, 23(2):508-516 Figure 1: Amazon rainforest before-during and after dumping the orange peel waste. The organic waste turned into compost and returned the soil nutrients making it fertile vegetation once again. TEXTILES FROMORANGE PEEL WASTES – INVENTION Textile is the second largest polluting industry in the world. There are many factors that contribute to pollution by the textile industry from cultivation, processing, shipping, and consumption (Figure 2 ). World bank has estimated 20% of water pollution is caused by the textile processing industry working on the dyeing and finishing of fabrics8. The excessive consumption of freshwater, discharging pollutants in the water bodies, chopping down trees for fuel, util- ising large tons of oil for production, release of micro plastics into ocean and dumping of textiles on landfills the thread is long. There are different types of organic waste that are specific to that region and available in abundance after cultivation or processing, it is impor- tant to experiment such wastes for its potentialities. In 2012, Adriana Santanocito, a native of the Sicilian city of Catania, found a similar organic waste from her city which was popular as the largest consumer of orange as juice. On further research, she found that globally, 7,00,000 tons of citrus peel waste every year are thrown away in landfills without proper recycling alternatives (Figure 3 ). She decided to conduct a pilot study to convert the peel into textiles for her univer- sity project. The grounded orange peel waste was then processed, and cellulose was separated. This was fur- ther sent to a spinning industry in Spain for making the yarn. This is blended with silk and cotton to make satin and poplin material 9. They also make fabrics from 100% orange peel waste fibre which is similar to viscose (textile made fromwood-also called rayon) available in light shades that can be dyed, printed, and even washed like other conventional materials. The fabric was sold at €30-€40 per meter. Enrica Arena, the hostel mate of Adriana, who as- sisted in documenting the research to be drafted in English, joined the research soon after (Figure 4 ). Fabric made using orange peel waste textiles was re- sembling silk in terms of quality, softness, shiny sur- face, and colour. Nanotechnology and microencap- sulation were employed to retain the beneficial prop- erties of citrus fruits on to fabric and the technology- aided in maintaining these properties till 20 washes. The biodegradable material was good to be blended with cotton, silk, elastane, and pineapple. The duo decided to present this in various forums to demand, scope and market for the developed textile10. ORANGE FIBRE – THE BRAND Adriana Santanocito and Enrica Arena collected or- ange peel waste from the local juice makers in the city andwashed, cleaned, processed them. The orange peel waste is processedwith their patented technology ‘Pastazzo’, that separates the cellulose from the ma- terial11. This will be then mixed with material and made into a filament, which can be used for weav- ing or knitting, as 100% orange peel waste fabric, or a blend with cotton and polyester. The company sells three types of fabrics, lace silk in black and white, cream coloured satin, and viscose like daily wear fab- ric. The inventors won the Global Change Award 509 Science & Technology Development Journal, 23(2):508-516 Figure 2: Facts Sheet on Textile Pollution. Figure 3: Processing of Orange peel waste into textiles (Pollution, Inventors, Process). 2015, which had around 2,700 inventors from 112 countries presenting their work. On winning, they received huge funding through which they installed their large-scale plant to prepare regenerated cellu- lose from orange peel. Sooner, their commercial pro- duction branded “Orange Fibre” with a tagline ‘Sus- tainable and vitaminic textiles from citrus waste’ was launched 12. Further recharging methods with spe- cial fabric softeners experimented. Their company re- ceived many awards during their journey (Figure 5 ). Their patented idea was purchased by international brand H&M. It was the first brand in the world to launch textilesmade fromorange peelwaste under the category, “Conscious Exclusive line - 2019”. A boho- inspired top in collaborationwith BLOOMfoamalgae was also in the series of collections. Victoria Albert Museum in London organized on an exhibition dis- playing 300 works on the title ‘Fashion from Nature’, displaying over 300 garments along with the Ferrag- amo Orange Fibre Collection (Figure 6 ). Citrus peel and pineapple leaf fibre were combined with Italian silk and embroidered with vegan material. Salvatore Ferragamo, the Italian Designer, created high-end shirts, dresses using orange fibre and many designs that they launched as Capsule collection on Earth day (Figure 6 ). In order to expand their produc- 510 Science & Technology Development Journal, 23(2):508-516 Figure 4: Journey of orange peel waste into textile (Orange Fibre brand). Figure 5: Milestones of Orange Fibre Brand (Sustainable and Vitaminic textiles from citrus waste). tion, they arranged for a crowdfunding campaign in 2019 to get 2,50,000 Euros and surprisingly received 6,50,000 Euros13. This initiated the large-scale pro- duction of more than 60 tons of cellulose per year. In a nutshell, we can conclude that fruit textiles received a good reception from consumers worldwide for its eco-friendly nature, biodegradability and sustainabil- ity. The journey and recognitions received are given in the figure below. GOODNESS IN TEXTILESMADE FROMORANGE PEELWASTE Textiles are rightly called as second skin due to its close positioning to the body, whatever is placed over the skin affects the health of the person by releasing the contents into the bloodstream. Synthetic chem- icals of organically derived materials are definitely a choice considering the health benefits for an individ- ual. Fabrics made from orange peel waste have been proved to perform like vitamin C infuser along with 511 Science & Technology Development Journal, 23(2):508-516 Figure 6: Ferragamo Collectionmade using orange peel waste and pineapple leaves. Figure 7: Properties of textiles made from orange peel waste. moisturizing capabilities. The natural oils of orange peel are retained in the fabric and are believed to give nourishment to the skin. The amazing quality of or- ange fiber can be its rich source of vitamin C and es- sential oils that can be like a moisturizing cream on the skin. The reduced carbon footprint by using a material that could be an organic waste dumped on landfills is reverse engineered into a material of value and utility (Figure 7 ). In order to make the cloth- ing more affordable, a blend with yarns made from pineapple leaf. The blend-ability of orange fibre with cotton, silk, elastane is good; hence the product range is also diversified with a prospective future. CURRENT USES OF ORANGE PEEL WASTE Orange peel waste can be collected on a domestic scale, large scale from juice vendors or food process- ing industry. It can be imported or exported to other places for recycling the waste into beneficial products, and there are trade websites that sell orange peel waste for 50$ - 450$ for 100 tonnes. The existing options are not sufficient, considering the expected increase in the future, which unveils the research gap to be filled by future scholars. Oil extraction Food and agricultural organization of the United States suggests that 1.3 billion tonnes of food are wasted in which citrus peel wastes are also enlisted. Thus, exploring new alternatives is essential. One such was the study on extraction of oil from the cit- rus peel waste using hydro-distillation, steam distilla- tion, ultra-sound, microwaves, super-critical-carbon- di-oxide, enzymes, and a combination of technolo- gies. The essential oil from oranges has various bioac- tive compounds like limonene, p- myrcene, sabinene, b-pinene, and linalool that will make it a product of great value6. Another study processed citrus peel waste to produce ellagic acid through the submerged 512 Science & Technology Development Journal, 23(2):508-516 fermentation, that enables in the biotransformation of themoleculeswhich can be used as an antioxidant and antibacterial agent14. In most cases, citrus waste is dried and powdered. One report highlighted that hot air impingement drying is a very effective technique for drying orange peel waste and 65C is the best for protecting the quality of polyphenols, ascorbic acid as well as antioxidant properties 5. Dyeing Dyes from orange peel was the obvious first level re- search. The orange peel waste can be collected and used fresh or sundried. The boiling of peels releases a light orangish-yellow colour to the water. Suitable mordant can be added to hold the dye on to the fab- ric. The resultant fabric had a light shade of yellow along with a sweet citrus smell. In addition, it had mild fragrance, anti-microbial, antioxidant, and as- tringent properties on to the fabric, which can be re- tained up to twenty washes. The colour fastness and wash fastness property were good. It was a suggestion recommendation for functional clothing and sports textiles 15. A study done using wasted peels of orange and lemon with alum and sodium carbonate (30% mordants) gave good quality in shade and fastness. A trial study was done to isolate pectic acid from cit- rus peel waste by acid hydrolysis. This was mixed with a thickening agent and used as a printing paste to print designs on textiles. There is a study reported with sodium alginate that showed better dye take up, brightness in shade and wash fastness16. Anti-microbial finishing Grinded orange peels are used a textile finishing agent. A study quoted that the extracts from cit- rus (lemon and orange) peel waste combined with sodium bicarbonate, coated on a cotton fabric re- sulted in appreciable anti-odour and anti-microbial properties on the fabric. These are very significant entities in medical textiles. It is also reported that the friction occurred during washing was found to have negative impact on the finishing given by de- creasing the efficacy of the active agents and their anti- microbial activity. The use of an alkaline binder how- ever, has resulted in better performance properties. It was also interesting to note that the finished fabric sustained all microbes except C. Albicans16. Another work reported orange peel and papaya skin with sil- ver nanoparticles combined to induce anti-microbial character to the fabric 17. Mosquito-repellent finish These citrus peel help in eliminating deadliest bug on the planet, mosquitos. The collected peel dried, pow- dered and coated on the fabric using padding mangle was found to perform as an effective mosquito repel- lent fabric. The active extracts of limonene extracted fromorange peel using the ultrasonic waves were con- verted into micro-capsules (microencapsulation) and further coated on the cellulosic fabric for better in- sect repellent property. The fabric testing showed very good results for UV protection, self-cleaning, anti- microbial/antioxidant properties18. Print transfer medium In 2018, a group of IIT-Hyderabad scholars under the guidance of Prof. Chandra Shekhar Sharma pub- lished research, which quoted a lack of commercial utilities for orange peel waste. They have suggested that the material can be used as an insulating ma- terial in building construction, a remedy for the oil spill, source of carbon. Limonene is a special material present on the citrus peel, which can be isolated for various utilities, but the process of extraction is ex- pensive. The extract from the citrus peel has a unique property to transfer ink from one surface to another and thus can be a good print transfer medium. Trans- fer of prints can be done on a variety of surfaces like wood, mica, paper, clothes, glass, human skin (for tat- toos) to extract the design. During their course of ex- perimentation, they found three layers in the orange peel extract • The top layer of oil: used in polystyrene recy- cling, • Second cellulosic layer: can be converted to car- bon and used as an electrode in batteries. • Water-like bottom layer: natural solvent for bio- polymers to produce nano-fibres19. Water purification In 2014, Dr. Justin Chalker and his team working in Synthetic Chemistry, Flinders University, developed a polymer with orange peel and sulfur (a by-product of the petroleum industry), which was effective in re- moving mercury from water. The developed poly- mer was suggested to be given as a coating inside the pipes to remove mercury. In a study, the orange peel was combined with Calotropis procera leaves, saw- dust, and coconut shells to remove iron from wastew- ater (after the activation process)20. 513 Science & Technology Development Journal, 23(2):508-516 Textile effluent wastewater Orange peel has pectin, hemicellulose, lignin, and limestone, which can be used as an effective dye ad- sorbent, remove toxins and organic pollutants from the textile effluent water. The study on principles of Green Chemistry suggests that orange peel is effec- tive in reducing pH, colour, and COD (Carbon-di- oxide demand) in the textile effluent water. Orange peel waste fibres are proved to have the property to absorb toxic dye particles from the aqueous medium, and also in removal of specific dyes like Acid violet 1721, burgundy-16 can also be seen. Magnetized or- ange peel powder has been tested as a dye adsorbent to confiscate crystal violet dye from the aqueous solution of textile effluent water. In the process, external mag- nets are used to take back the magnetic particles after adsorption. It is an interesting study that compares with and without magnets along with the citrus peel. The high adsorption affinity, separability, regenerabil- ity, cost-effectiveness makes the technique of magnets induced orange peel to be a good remedy to remove crystal violet from effluent water22. Research publi- cations suggest the role of citrus peelwaste to decolour the effluent in the carpet industry and the combina- tion of citrus peel and banana peel for acting as a dye adsorbent. Studies were done on utilizing activated carbon along with orange peel waste to treat effluent water23–25. Bio-adsorbent At the industrial level, the role bio-adsorbent is well known. There are studies where the citrus peel is of orange peel waste as a converted into a bio-adsorbent (oil adsorbent medium) to combat oil spills in the ocean. Orange peel waste as bio-adsorbent is effec- tive; however, low pH, contact time, high concen- tration, bio-sorbent mass can also influence the rate of adsorption. Design and development of wipes for kitchen and oil spills are also possible using the orange peel wastes26. Biogas Experiments on the production of biogas from waste orange peels are also popular. Organic waste can be treated using a). mono-treatment scenarios (py- rolysis, incineration, and anaerobic mono-digestion), b).co-treatment (four anaerobic co-digestion strate- gies using animal manure and seaweed) and c). traditional non-energy focused handling techniques (landfilling, composting, and animal feeding), among which the co-digestion technique was found to be top rated as a result of trials conducted in the study27,28. Bio-char Orange peels can be used like animals, fertilizer, and feedstock. Recently a study suggested synthesis of bio- char, high in carbon (65-90%), and porous. The col- lected wastes were processed by the use of thermo- chemical energy. The resultant biochar can be used as a soil amendment to restore nutrients, as adsorbents to remove chemicals like ammonium, led, and other ionic compounds from water. It can be used as a cat- alyst in syn-gas production, as bio-composite, and in the production of biofuel29. The very interesting paper on the life cycle assessment of orange peel waste unveils that the commonly avail- able recycling options are composting, animal feed- ing, or landfill disposal30. Commercially success- ful energy conservation and resource utilization tech- niques are still void. Pyrolysis, incineration, anaero- bic mono-digestion and co-digestion (animal manure and seaweed) given the choices, the latterwas found to be the best way to handle the waste with nitrate leach- ing into the soil being one of the drawbacks31. FUTURE PERSPECTIVE FOR TEXTILES FROMORANGE PEEL WASTE There are ongoing researches using orange peel waste to be used for the synthesis of porous carbon using copper carbonate as an activation agent and develop supercapacitors with high power and energy den- sity32. Another research paper indulged in report- ing the study on developing Fe-modified hydrochar from orange peel waste, optimize and characterize the protocols like dose, temperature, time, concentra- tion, and identify the dominant mechanisms through kinetic analysis. Orange peel waste was hydrother- mally carbonized after eight hours at 200 C, and the resultant hydrochar was embedded with magnetite nanoparticles33. Textiles from recycling orange peel waste are considered to be a sustainable alternative as it uses a lesser carbon footprint compared to con- ventional textile production. Handmade paper mak- ing from agricultural wastes is gaining momentum. The brand ‘Crush’, is actively involved in making pa- pers from grapes, cherries, orange peel, almond skin, lavender, coffee dust, corn, olives, kiwis, and hazel- nuts. Thus, paper making can be one of the eco- friendly solutions to hitherto polluting waste. Cellu- lose has an amazing quality, and textiles made from them are known for softness, dye absorbency, and breathability. In a nutshell, the orange peel waste can be used as cat- tle feed, manufacturing of handmade paper, compost, 514 Science & Technology Development Journal, 23(2):508-516 as a soil amendment, perfumes, cosmetics, essential oil, textile dyeing, printing, print transfer medium, and for fragrance finishing, mosquito repellent, anti- microbial finishing on textiles. It is also used in polystyrene production, limonene extraction, purify- ing water, treating textile effluent wastewater, as bio- adsorbent and as a source of carbon, biochar, and bio- fuel. This paper demonstrates a few existing remedies for orange peel waste, which can open up more possi- bilities in the future. CONCLUSION The recent threat by the textile industry is the inva- sion of plastics (as microplastics) into the ocean by the use of synthetic textiles in our everyday life. It is found that polyester, nylon, acrylic make 60% of clothing and release microplastic during processing, walking, and washing. A study done on washing and microfibers generation reported a release of 7,00,000 fibres in washing, 1,900 fibres in case of one synthetic garment, and 1 million fibres during laundering of fleece. Today, 73% of fishes in the ocean is reported to have microplastics in their stomach, which can en- ter the human food chain. It is studied that 35% ofmi- croplastics in the ocean come from the textile industry (2017 International Union for Conservation of Na- ture)The used cups and straws being banned now the identity is shifted to textiles made from petrochemi- cals34. This synthetic debris should seize, and more sustainable materials should enter the supply chain to create sustainable clothing. CONFLICT OF INTEREST Theauthors have declared that no competing interests exist. REFERENCES 1. Aishwariya S. Waste Management Technologies in Textile In- dustry. Innov Energy Res. 2018;07:175–179. Available from: https://doi.org/10.4172/2576-1463.1000211. 2. Aishwariya S, Amsamani S. Exploring the Potentialities and Future of Biomass Briquettes Technology for Sustainable En- ergy. Innov Energy Res. 2018;07. Available from: https://doi. org/10.4172/2576-1463.1000221. 3. Kadam AA, Sharma B, Saratale GD, et al. Super-magnetization of pectin from orange-peel biomass for sulfamethoxazole ad- sorption. Cellulose. 2020;27:3301–3318. Available from: https: //doi.org/10.1007/s10570-020-02988-z. 4. Wang M, Shi R, Gao M, et al. Sensitivity fluorescent switching sensor for Cr (VI) and ascorbic acid detection based on orange peels-derived carbon dots modified with EDTA. Food Chem. 2020;318:126506. PMID: 32126473. Available from: https:// doi.org/10.1016/j.foodchem.2020.126506. 5. DengLZ,MujumdarAS, YangWX. Hot air impingementdrying kinetics and quality attributes of orange peel. J Food Process Preserv. 2020;44:1–11. Available from: https://doi.org/10.1111/ jfpp.14294. 6. Gavahian M, Chu YH, Khaneghah AM. Recent advances in or- ange oil extraction: an opportunity for the valorisation of or- ange peelwaste a review. Int J Food Sci Technol. 2019;54:925– 932. Available from: https://doi.org/10.1111/ijfs.13987. 7. Dockrill P. How 12,000 Tonnes of Dumped Orange Peel Grew Into a Landscape Nobody Expected to Find. 2017;Available from: https://www.sciencealert.com/how-12-000-tonnes- of-dumped-orange-peel-produced-something-nobody- imagined. 8. Periyasamy AP, Ramamoorthy SK, Rwawiire YZS. Sustainable Wastewater Treatment Methods for Textile Industry. Springer Nat Singapore Pte Ltd. 2018;Available from: https://doi.org/10. 1007/978-981-10-8591-8. 9. Favini tells the story of Orange Fiber. In: Sustain Chan- nel;Available from: https://www.favini.com/en/news/favini- tells-the-story-of-orange-fiber/. 10. Yamamori N. Dress yourseflf in orange fiber. In: Conscious Welum. Accessed 19 Apr 2020. 2017;Available from: https: //www.welum.com/article/dress-yourself-with-oranges/. 11. Maria A, Santaocito EV. Production of textile from citrus fruit. 2013;. 12. Fabrics from Oranges - interesting and exciting. In: Unnati silks. Accessed 19 Apr 2020;Available from: https://www.unnatisilks.com/blog/fabrics-from-oranges- interesting-and-exciting/. 13. Boztas S. Nice threads: the waste-based fibres cleaning up fashion. In: Guard. Accessed19Apr 2020. 2018;Available from: https://www.theguardian.com/business-to-business/2018/feb/ 12/nice-threads-the-waste-based-fibres-cleaning-up-fashion. 14. Sepúlveda L, Laredo-Alcalá E, Buenrostro-Figueroa JJ, et al. Ellagic acid production using polyphenols from orange peel waste by submerged fermentation. Electron J Biotechnol. 2020;43:1–7. Available from: https://doi.org/10.1016/j.ejbt. 2019.11.002. 15. Kumar CSS, Dhinakaran M. Extraction and Application of Nat- ural Dyes From Orange Peel and Lemon Peel on Cotton Fab- rics. Int Res J Eng Technol. 2017;4:2008–2009. 16. Amanuel L. Extraction of Pectic Acid from Citrus Fruit Peels and its Application as Textile Printing Thickener. Latest Trends Text Fash Des. 2018;1:45–50. Available from: https://doi.org/ 10.32474/lttfd.2018.01.000111. 17. Rani N, Jajpura L, Butola BS. Ecological Dyeing of Protein Fab- rics with Carica papaya L. Leaf Natural Extract in the Presence of Bio-mordants as an Alternative Copartner to Metal Mor- dants. J Inst Eng Ser E. 2020;Available from: https://doi.org/ 10.1007/s40034-020-00158-1. 18. A AG, A AS. Efficacy of orange peel as a mosquito repellent. 2017;3:143–146. 19. Yadav S, Sharma CS. Novel and green processes for citrus peel extract: a natural solvent to source of carbon. Polym Bull. 2018;75:5133–5142. Available from: https://doi.org/10.1007/ s00289-018-2310-5. 20. Dwivedi P, Vijayakumar RP, Chaudhary AK. Synthesis of UMCNO-cotton fabric and its application inwastewater treat- ment. Cellulose. 2020;27:969–980. Available from: https: //doi.org/10.1007/s10570-019-02840-z. 21. Sivaraj R, Namasivayam C, K K. Orange peel as an adsor- bent in the removal of Acid violet 17 (acid dye) from aqueous solutions. Waste Manag. 2001;21:105–110. Available from: https://doi.org/10.1016/S0956-053X(00)00076-3. 22. Ahmed M, Mashkoor F, Nasar A. Development, characteri- zation, and utilization of magnetized orange peel waste as a novel adsorbent for the confiscation of crystal violet dye from aqueous solution. Groundw Sustain Dev. 2020;10:100322. Available from: https://doi.org/10.1016/j.gsd.2019.100322. 23. Khaled A, Nemr AE, El-Sikaily A, Abdelwahab O. Treatment of artificial textile dye effluent containing Direct Yellow 12 by or- ange peel carbon. Desalination. 2009;238:210–232. Available from: https://doi.org/10.1016/j.desal.2008.02.014. 24. Nguyen TXT. Preparation, micro-structure and mechanical properties of porous carbonate apatite using chicken bone as raw material. Sci Technol Dev J. 2020;22:365–369. Available from: https://doi.org/10.32508/stdj.v22i4.1218. 515 Science & Technology Development Journal, 23(2):508-516 25. Abdurrahman FB, Akter M, Abedin MZ. Dyes Removal From Textile Wastewater Using Orange Peels. Int J Sci Technol Res. 2013;2:47–50. 26. Temesgen F, Gabbiye N, Sahu O. Biosorption of reactive red dye (RRD) on activated surface of banana and orange peels: Economical alternative for textile effluent. Surfaces and In- terfaces. 2018;12:151–159. Available from: https://doi.org/10. 1016/j.surfin.2018.04.007. 27. Wikandari R, NguyenH,Millati R, et al. Improvement of biogas production from orange peel waste by leaching of limonene. Biomed Res Int 2015. 2015;Available from: https://doi.org/10. 1155/2015/494182. 28. Rokaya B, Kerroum D, Hayat Z, et al. Biogas production by an anaerobic digestion process from orange peel waste and its improvement by limonene leaching: Investigation of H2O2 pre-treatment effect. Energy Sources, Part A Recover Util Env- iron Eff. 2019;00:1–9. Available from: https://doi.org/10.1080/ 15567036.2019.1692975. 29. Adeniyi AG, Ighalo JO, Onifade DV. Biochar from the Ther- mochemical Conversion of Orange (Citrus sinensis) Peel and Albedo: Product Quality and Potential Applications. Chem Africa. 2020;Available from: https://doi.org/10.1007/s42250- 020-00119-6. 30. Negro V, Ruggeri B, Fino D, Tonini D. Life cycle assessment of orange peel waste management. Resour Conserv Recycl. 2017;127:148–158. Available from: https://doi.org/10.1016/j. resconrec.2017.08.014. 31. Sial TA, Lan Z, Khan MN, et al. Evaluation of orange peel waste and its biochar on greenhouse gas emissions and soil biochemical properties within a loess soil. Waste Manag. 2019;87:125–134. Available from: https://doi.org/10.1016/j. wasman.2019.01.042. 32. Wan L, Chen D, Liu J, et al. Facile preparation of porous carbons derived from orange peel via basic copper car- bonate activation for supercapacitors. J Alloys Compd. 2020;823:153747. Available from: https://doi.org/10.1016/j. jallcom.2020.153747. 33. Çatlıoğlu FN, Akay S, Gözmen B, et al. Fe-modified hydrochar fromorange peel as adsorbent of food colorant Brilliant Black: process optimization and kinetic studies. Int J Environ Sci Technol. 2020;17:1975–1990. Available from: https://doi.org/ 10.1007/s13762-019-02593-z. 34. Resnick B. More than ever, our clothes aremadeof plastic. Just washing them can pollute the oceans. In: Vox;. 516