nach oben

Erschienen in:

2024 | OriginalPaper | Buchkapitel

Waste to Energy Conversion: Key Elements for Sustainable Waste Management

verfasst von : Karambir Singh, Naveen Kumar, Akhilesh Bharti, Pankaj Thakur, Vinod Kumar

Erschienen in: Integrated Waste Management

Verlag: Springer Nature Singapore

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

By prioritizing cleaner waste-to-energy (WTE) conversion technology, world is trying to meet its sustainable development goals. This requires investigating any and all sustainable options across the globe. The most exciting of them is the sustainable bio-economy, followed by power and waste management. When considering the three dimensions of sustainability (social, environmental, and economic), previous sustainability assessments of electricity generation through waste to energy supply chain technologies have been limited. Although several waste treatment options have been investigated over the last few decades, and their widespread adoption has been hampered by a number of drawbacks, such as the need for chemicals, the generation of disinfection by-products (DBPs), the length of time required, and the cost involved. Nanotechnology has shown remarkable progress in various fields, including waste treatment. Nanomaterials (1–100 nm) have a greater capacity of oxidation/reduction reaction, catalytic activity, and heavy metal adsorption, making them an innovative eco-waste handling tool. In this study, we have discussed various waste types. We've tried to cover all the cutting-edge waste to energy conversion methods. It includes thermal and biological processing to use of landfill gas and biorefineries and the use of various nanomaterials for enhancement of waste to energy conversion technologies. Prior to enacting and enforcing applicable laws and regulations, policymakers and agencies might consider employing these technologies to address community concerns. It is also crucial to identify barriers, including finance constraints, institutional and technological limitations, and regulatory challenges before implementing rules and regulations for Waste-to-Energy Supply chain (WTE-SC). Overall, this literature evaluation suggests continuation of research in this field.

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Vorheriges Kapitel Agriculture Waste to Wealth: Unlocking the Hidden Potential

Nächstes Kapitel Chemical Management of Industrial Hazardous and Non-hazardous Waste

Kan A (2009) General characteristics of waste management: a review. Energy Educ Sci Technol Part a-Energy Sci Res 23

Dijkema GPJ, Reuter MA, Verhoef EV (2000) A new paradigm for waste management. Waste Manag 20:633–638CrossRef

Herva M, Neto B, Roca E (2014) Environmental assessment of the integrated municipal solid waste management system in Porto (Portugal). J Clean Prod 70:183–193CrossRef

Attahiru YB, Aziz MMA, Kassim KA, Shahid S, Bakar WAWA, NSashruddin TF, Rahman FA, Ahamed MI (2019) A review on green economy and development of green roads and highways using carbon neutral materials. Renew Sustain Energy Rev 101:600–613

Geng Y, Fu J, Sarkis J, Xue B (2012) Towards a national circular economy indicator system in China: an evaluation and critical analysis. J Clean Prod 23:216–224CrossRef

Liu Q, Li H, Zuo X, Zhang F, Wang L (2009) A survey and analysis on public awareness and performance for promoting circular economy in China: a case study from Tianjin. J Clean Prod 17:265–270CrossRef

Demirbas A (2011) Waste management, waste resource facilities and waste conversion processes. Energy Convers Manag 52:1280–1287. https://doi.org/10.1016/j.enconman.2010.09.025CrossRef

Li W, Ju M, Liu L, Wang Y, Li T (2011) The effects of biomass solid waste resources technology in economic development. Energy Procedia 5:2455–2460CrossRef

Jekayinfa SO, Omisakin OS (2005) The energy potentials of some agricultural wastes as local fuel materials in Nigeria

10.

ElMekawy A, Srikanth S, Bajracharya S, Hegab HM, Nigam PS, Singh A, Mohan SV, Pant D (2015) Food and agricultural wastes as substrates for bioelectrochemical system (BES): the synchronized recovery of sustainable energy and waste treatment. Food Res Int 73:213–225CrossRef

11.

Ahmad F, Atiyeh MN, Pereira B, Stephanopoulos GN (2013) A review of cellulosic microbial fuel cells: performance and challenges. Biomass Bioenerg 56:179–188CrossRef

12.

Kumar R, Sudhaik A, Raizada P, Nguyen V-H, Van Le Q, Ahamad T, Thakur S, Hussain CM, Singh P (2023) Integrating K and P co-doped g-C3N4 with ZnFe2O4 and graphene oxide for S-scheme-based enhanced adsorption coupled photocatalytic real wastewater treatment. Chemosphere 337:139267CrossRef

13.

Skaggs RL, Coleman AM, Seiple TE, Milbrandt AR (2018) Waste-to-Energy biofuel production potential for selected feedstocks in the conterminous United States. Renew Sustain Energy Rev 82:2640–2651CrossRef

14.

Gupta GK, Shukla P (2020) Insights into the resources generation from pulp and paper industry wastes: challenges, perspectives and innovations. Bioresour Technol 297:122496CrossRef

15.

Sonkar M, Kumar M, Dutt D, Kumar V (2019) Treatment of pulp and paper mill effluent by a novel bacterium Bacillus sp. IITRDVM-5 through a sequential batch process. Biocatal Agric Biotechnol 20:101232

16.

Khan AAP, Sudhaik A, Raizada P, Khan A, Rub MA, Azum N, Alotaibi MM, Singh P, Asiri AM (2023) AgI coupled SiO2@ CuFe2O4 novel photocatalytic nano-material for photo-degradation of organic dyes. Catal Commun 179:106685CrossRef

17.

Dutta V, Raizada P, Verma PK, Ahamad T, Thakur S, Hussain CM, Singh P (2022) Constructing carbon nanotubes@ CuBi2O4/AgBiO3 all solid-state mediated Z-scheme photocatalyst with enhanced photocatalytic activity. Mater Lett 320:132374CrossRef

18.

Malhotra M, Sudhaik A, Raizada P, Ahamad T, Nguyen V-H, Van Le Q, Selvasembian R, Mishra AK, Singh P (2023) An overview on cellulose-supported photocatalytic materials for the efficient removal of toxic dyes. Ind Crops Prod 202:117000CrossRef

19.

Zhong ZW, Song B, Zaki MBM (2010) Life-cycle assessment of flash pyrolysis of wood waste. J Clean Prod 18:1177–1183CrossRef

20.

Rao YKSS, Dhanalakshmi CS, Vairavel DK, Surakasi R, Kaliappan S, Patil PP, Socrates S, Lalvani J (2022) Investigation on forestry wood wastes: pyrolysis and thermal characteristics of Ficus religiosa for energy recovery system. Adv Mater Sci Eng

21.

Ju C, Wang F, Huang Y, Fang Y (2018) Selective extraction of neutral lipid from wet algae paste and subsequently hydroconversion into renewable jet fuel. Renew Energy 118:521–526CrossRef

22.

Chaudhary V, Chowdhury R, Thukral P, Pathania D, Saklani S, Rustagi S, Gautam A, Mishra YK, Singh P, Kaushik A (2023) Biogenic green metal nano systems as efficient anti-cancer agents. Environ Res 115933

23.

Kumar BR, Mathimani T, Sudhakar MP, Rajendran K, Nizami A-S, Brindhadevi K, Pugazhendhi A (2021) A state of the art review on the cultivation of algae for energy and other valuable products: application, challenges, and opportunities. Renew Sustain Energy Rev 138:110649CrossRef

24.

Soni V, Singh P, Thakur S, Thakur P, Ahamad T, Nguyen V-H, Van Le Q, Hussain CM, Raizada P (2023) Fabricating cattle dung-derived nitrogen-doped biochar supported oxygen-deficient ZnO and Cu2O-based novel step-scheme photocatalytic system for aqueous Doxycycline hydrochloride mitigation and Cr (VI) reduction. J Environ Chem Eng 11:110856CrossRef

25.

Tyagi VK, Lo S-L (2013) Sludge: a waste or renewable source for energy and resources recovery? Renew Sustain Energy Rev 25:708–728CrossRef

26.

Agun L, Ahmad N, Redzuan NH, Misnal MFI, Zainal MNF (2022) Plasma technology in waste-to-energy valorization: fundamentals, current status, and future directions. Handb Waste Biorefinery Circ Econ Renew Energy 813–830

27.

Ali J, Rasheed T, Afreen M, Anwar MT, Nawaz Z, Anwar H, Rizwan K (2020) Modalities for conversion of waste to energy—challenges and perspectives. Sci Total Environ 727:138610CrossRef

28.

Andriamanohiarisoamanana FJ, Matsunami N, Yamashiro T, Iwasaki M, Ihara I, Umetsu K (2017) High-solids anaerobic mono-digestion of riverbank grass under thermophilic conditions. J Environ Sci 52:29–38CrossRef

29.

Hsieh P-H, Lai Y-C, Chen K-Y, Hung C-H (2016) Explore the possible effect of TiO2 and magnetic hematite nanoparticle addition on biohydrogen production by Clostridium pasteurianum based on gene expression measurements. Int J Hydrogen Energy 41:21685–21691CrossRef

30.

Gadhe A, Sonawane SS, Varma MN (2015) Influence of nickel and hematite nanoparticle powder on the production of biohydrogen from complex distillery wastewater in batch fermentation. Int J Hydrogen Energy 40:10734–10743CrossRef

31.

Han H, Cui M, Wei L, Yang H, Shen J (2011) Enhancement effect of hematite nanoparticles on fermentative hydrogen production. Bioresour Technol 102:7903–7909CrossRef

32.

Li H, Cui F, Liu Z, Li D (2017) Transport, fate, and long-term impacts of metal oxide nanoparticles on the stability of an anaerobic methanogenic system with anaerobic granular sludge. Bioresour Technol 234:448–455CrossRef

33.

Zheng L, Zhang Z, Tian L, Zhang L, Cheng S, Li Z, Cang D (2019) Mechanistic investigation of toxicological change in ZnO and TiO2 multi-nanomaterial systems during anaerobic digestion and the microorganism response. Biochem Eng J 147:62–71CrossRef

34.

Abdelsalam E, Samer M, Attia YA, Abdel-Hadi MA, Hassan HE, Badr Y (2017) Influence of zero valent iron nanoparticles and magnetic iron oxide nanoparticles on biogas and methane production from anaerobic digestion of manure. Energy 120:842–853CrossRef

35.

Dong Z, Guo H, Zhang M, Xia D, Yin X, Lv J (2022) Enhancing biomethane yield of coal in anaerobic digestion using iron/copper nanoparticles synthesized from corn straw extract. Fuel 319:123664. https://doi.org/10.1016/j.fuel.2022.123664

36.

Abdelsalam E, Samer M, Attia YA, Abdel-Hadi MA, Hassan HE, Badr Y (2017) Effects of Co and Ni nanoparticles on biogas and methane production from anaerobic digestion of slurry. Energy Convers Manag 141:108–119. https://doi.org/10.1016/j.enconman.2016.05.051

37.

Cerrillo M, Burgos L, Ruiz B, Barrena R, Moral-Vico J, Font X, Sánchez A, Bonmatí A (2021) In-situ methane enrichment in continuous anaerobic digestion of pig slurry by zero-valent iron nanoparticles addition under mesophilic and thermophilic conditions. Renew Energy 180:372–382. https://doi.org/10.1016/j.renene.2021.08.072

38.

Zhang H, Li W, Zhou C, Zhang J, Pei Y, Zang L (2022) Comparison of cobalt ferrate-based nanoparticles for promoting biomethane evolution from lactic acid anaerobic digestion. Bioresour Technol 347:126689. https://doi.org/10.1016/j.biortech.2022.126689

39.

Kaushal R, Baitha R (2021) Biogas and methane yield enhancement using graphene oxide nanoparticles and Ca(OH)2 pre-treatment in anaerobic digestion. Int J Ambient Energy 42:618–625. https://doi.org/10.1080/01430750.2018.1562975CrossRef

40.

García A, Delgado L, Torà JA, Casals E, González E, Puntes V, Font X, Carrera J, Sánchez A (2012) Effect of cerium dioxide, titanium dioxide, silver, and gold nanoparticles on the activity of microbial communities intended in wastewater treatment. J Hazard Mater 199–200:64–72. https://doi.org/10.1016/j.jhazmat.2011.10.057

41.

Qi L, Liu X, Miao Y, Chatzisymeon E, Yang P, Lu H, Pang L (2021) Response of cattle manure anaerobic digestion to zinc oxide nanoparticles: Methane production, microbial community, and functions. J Environ Chem Eng 9:106704. https://doi.org/10.1016/j.jece.2021.106704

42.

Wang T, Zhang D, Dai L, Chen Y, Dai X (2016) Effects of metal nanoparticles on methane production from waste-activated sludge and microorganism community shift in anaerobic granular sludge. Sci Rep 6:25857. https://doi.org/10.1038/srep25857CrossRef

43.

Ghofrani-Isfahani P, Baniamerian H, Tsapekos P, Alvarado-Morales M, Kasama T, Shahrokhi M, Vossoughi M, Angelidaki I (2020) Effect of metal oxide based TiO2 nanoparticles on anaerobic digestion process of lignocellulosic substrate. Energy 191:116580. https://doi.org/10.1016/j.energy.2019.116580

44.

Lin R, Cheng J, Zhang J, Zhou J, Cen K, Murphy JD (2017) Boosting biomethane yield and production rate with graphene: the potential of direct interspecies electron transfer in anaerobic digestion. Bioresour Technol 239:345–352. https://doi.org/10.1016/j.biortech.2017.05.017

45.

Wang P, Zheng Y, Lin P, Li J, Dong H, Yu H, Qi L, Ren L (2021) Effects of graphite, graphene, and graphene oxide on the anaerobic co-digestion of sewage sludge and food waste: Attention to methane production and the fate of antibiotic resistance genes. Bioresour Technol 339:125585. https://doi.org/10.1016/j.biortech.2021.125585

46.

Gundoshmian TM, Ahmadi-Pirlou M (2022) Increasing biogas and methane yield by adding sewage sludge and zero-valent iron nanoparticles during the single-stage anaerobic digestion with municipal solid waste. Int J Energy Res 46:20611–20623CrossRef

47.

Singh RP, Tyagi VV, Allen T, Ibrahim MH, Kothari R (2011) An overview for exploring the possibilities of energy generation from municipal solid waste (MSW) in Indian scenario. Renew Sustain Energy Rev 15:4797–4808CrossRef

48.

Nguyen MK, Lin C, Hoang HG, Sanderson P, Dang BT, Bui XT, Nguyen NSH, Vo D-VN, Tran HT (2022) Evaluate the role of biochar during the organic waste composting process: a critical review. Chemosphere 299:134488CrossRef

49.

Stamou I, Antizar-Ladislao B (2016) The impact of silver and titanium dioxide nanoparticles on the in-vessel composting of municipal solid waste. Waste Manag 56:71–78CrossRef

50.

Phung LD, Afriani SD, Pertiwi PAP, Ito H, Kumar A, Watanabe T (2023) Effects of CuO nanoparticles in composted sewage sludge on rice-soil systems and their potential human health risks. Chemosphere 338:139555CrossRef

51.

Zhang L, Zhu Y, Zhang J, Zeng G, Dong H, Cao W, Fang W, Cheng Y, Wang Y, Ning Q (2019) Impacts of iron oxide nanoparticles on organic matter degradation and microbial enzyme activities during agricultural waste composting. Waste Manag 95:289–297. https://doi.org/10.1016/j.wasman.2019.06.025

52.

Medina J, Calabi-Floody M, Aponte H, Santander C, Paneque M, Meier S, Panettieri M, Cornejo P, Borie F, Knicker H (2021) Utilization of inorganic nanop1 J. Medina, M. Calabi-Floody, H. Aponte, C. Santander, M. Paneque, S. Meier, M. Panettieri, P. Cornejo, F. Borie and H. Knicker, Agronomy, 2021, 11, 767. Articles and biochar as additives of agricultural waste composting: eff. Agronomy 11:767

53.

Gitipour A, El Badawy A, Arambewela M, Miller B, Scheckel K, Elk M, Ryu H, Gomez-Alvarez V, Santo Domingo J, Thiel S (2013) The impact of silver nanoparticles on the composting of municipal solid waste. Environ Sci Technol 47:14385–14393CrossRef

54.

Yang Y, Heaven S, Venetsaneas N, Banks CJ, Bridgwater AV (2018) Slow pyrolysis of organic fraction of municipal solid waste (OFMSW): Characterisation of products and screening of the aqueous liquid product for anaerobic digestion. Appl Energy 213:158–168CrossRef

55.

Alsurakji IH, El-Qanni A, El-Hamouz AM, Warad I, Odeh Y (2021) Thermogravimetric kinetics study of scrap tires pyrolysis using silica embedded with NiO and/or MgO nanocatalysts. J Energy Resour Technol 143:92302CrossRef

56.

Jadav K, Pandian S, Sircar A, Subramanian D (2022) Investigation of nano catalyst to enhance fuel quality in waste tyre pyrolysis. Energy Sourc Part A Rec Util Environ Eff 44:1468–1477

57.

Song Q, Zhao H, Jia J, Yang L, Lv W, Bao J, Shu X, Gu Q, Zhang P (2020) Pyrolysis of municipal solid waste with iron-based additives: A study on the kinetic, product distribution and catalytic mechanisms. J Clean Prod 258:120682. https://doi.org/10.1016/j.jclepro.2020.120682

58.

Cao C-Y, Zhang D, Liu C-C, Lu S, Zhang H-P (2019) Experimental investigation on combustion behaviors and reaction mechanisms for 5-aminotetrazole solid propellant with nanosized metal oxide additives under elevated pressure conditions. Appl Therm Eng 162:114207CrossRef

59.

Gabani C, Ranchh Y, Barodia R, Sivakumar P (2018) Tyre pyrolysis by using nano-catalyst to improve energy efficiency and fuel quality. In: Nanotechnology for Energy and Water: Proceedings of the International Conference NEW-2017 1. Springer, pp 201–206

60.

Arafat HA, Jijakli K (2013) Modeling and comparative assessment of municipal solid waste gasification for energy production. Waste Manag 33:1704–1713CrossRef

61.

Norouzi O, Safari F, Jafarian S, Tavasoli A, Karimi A (2017) Hydrothermal gasification performance of Enteromorpha intestinalis as an algal biomass for hydrogen-rich gas production using Ru promoted Fe–Ni/γ-Al2O3 nanocatalysts. Energy Convers Manag 141:63–71. https://doi.org/10.1016/j.enconman.2016.04.083

62.

Rashidi M, Tavasoli A (2015) Hydrogen rich gas production via supercritical water gasification of sugarcane bagasse using unpromoted and copper promoted Ni/CNT nanocatalysts. J Supercrit Fluids 98:111–118. https://doi.org/10.1016/j.supflu.2015.01.008

63.

Li Y, Li G, Yang Y, Chen X, Peng W, Li H (2022) Incorporation of Nanocatalysts for the production of Bio-Oil from Staphylea holocarpa Wood. Polymers (Basel) 14:4385CrossRef

64.

Li J, Chang G, Song K, Hao B, Wang C, Zhang J, Yue G, Hu S (2023) Influence of coal bottom ash additives on catalytic reforming of biomass pyrolysis gaseous tar and biochar/steam gasification reactivity. Renew Energy 203:434–444CrossRef

65.

Xu G, Murakami T, Suda T, Kusama S, Fujimori T (2005) Distinctive effects of CaO additive on atmospheric gasification of biomass at different temperatures. Ind Eng Chem Res 44:5864–5868CrossRef

66.

Kwoczynski Z, Čmelík J (2021) Characterization of biomass wastes and its possibility of agriculture utilization due to biochar production by torrefaction process. J Clean Prod 280:124302CrossRef

67.

Cahyanti MN, Doddapaneni TRKC, Kikas T (2020) Biomass torrefaction: an overview on process parameters, economic and environmental aspects and recent advancements. Bioresour Technol 301:122737CrossRef

68.

Medic D, Darr M, Potter B, Shah A (2010) Effect of torrefaction process parameters on biomass feedstock upgrading. In: 2010 Pittsburgh, Pennsylvania, June 20-June 23, 2010. American Society of Agricultural and Biological Engineers, p 1

69.

Shankar Tumuluru J, Sokhansanj S, Hess JR, Wright CT, Boardman RD (2011) A review on biomass torrefaction process and product properties for energy applications. Ind Biotechnol 7:384–401CrossRef

70.

Bilal M, Iqbal HMN, Hu H, Wang W, Zhang X (2018) Metabolic engineering and enzyme-mediated processing: a biotechnological venture towards biofuel production–a review. Renew Sustain Energy Rev 82:436–447CrossRef

71.

Ahlgren S, Björklund A, Ekman A, Karlsson H, Berlin J, Börjesson P, Ekvall T, Finnveden G, Janssen M, Strid I (2015) Review of methodological choices in LCA of biorefinery systems-key issues and recommendations. Biofuels, Bioprod Biorefining 9:606–619CrossRef

72.

Parra-Saldivar R, Bilal M, Iqbal HMN (2020) Life cycle assessment in wastewater treatment technology. Curr Opin Environ Sci Heal 13:80–84CrossRef

73.

Kang NK, Jeon S, Kwon S, Koh HG, Shin S-E, Lee B, Choi G-G, Yang J-W, Jeong B, Chang YK (2015) Effects of overexpression of a bHLH transcription factor on biomass and lipid production in Nannochloropsis salina. Biotechnol Biofuels 8:1–13CrossRef

74.

Gumienna M, Szambelan K, Jeleń H, Czarnecki Z (2014) Evaluation of ethanol fermentation parameters for bioethanol production from sugar beet pulp and juice. J Inst Brew 120:543–549

75.

Jutakridsada P, Saengprachatanarug K, Kasemsiri P, Hiziroglu S, Kamwilaisak K, Chindaprasirt P (2019) Bioconversion of saccharum officinarum leaves for ethanol production using separate hydrolysis and fermentation processes. Waste Biomass Valoriz 10:817–825CrossRef

76.

Kumar V, Nanda M, Joshi HC, Singh A, Sharma S, Verma M (2018) Production of biodiesel and bioethanol using algal biomass harvested from fresh water river. Renew Energy 116:606–612CrossRef

77.

Jiang W, Brueggeman AJ, Horken KM, Plucinak TM, Weeks DP (2014) Successful transient expression of Cas9 and single guide RNA genes in Chlamydomonas reinhardtii. Eukaryot Cell 13:1465–1469CrossRef

78.

Paulino RFS, Essiptchouk AM, Silveira JL (2020) The use of syngas from biomedical waste plasma gasification systems for electricity production in internal combustion: thermodynamic and economic issues. Energy 199:117419CrossRef

79.

Sanito RC, You S-J, Wang Y-F (2021) Sanito RC et al (2021) Application of plasma technology for treating e-waste: a review. J Environ Manag 288(200):112380

80.

Bhatt M, Chakinala AG, Joshi JB, Sharma A, Pant KK, Shah K, Sharma A (2021) Valorization of solid waste using advanced thermo-chemical process: a review. J Environ Chem Eng 9:105434CrossRef

81.

Kiran EU, Trzcinski AP, Ng WJ, Liu Y (2014) Bioconversion of food waste to energy: a review. Fuel 134:389–399CrossRef

82.

Cherian E, Dharmendirakumar M, Baskar G (2015) Immobilization of cellulase onto MnO2 nanoparticles for bioethanol production by enhanced hydrolysis of agricultural waste. Chinese J Catal 36:1223–1229CrossRef

83.

Sanusi IA, Suinyuy TN, Lateef A, Kana GEB (2020) Effect of nickel oxide nanoparticles on bioethanol production: process optimization, kinetic and metabolic studies. Process Biochem 92:386–400CrossRef

84.

Sanusi IA, Suinyuy TN, Kana GEB (2021) Impact of nanoparticle inclusion on bioethanol production process kinetic and inhibitor profile. Biotechnol Reports 29:e00585CrossRef

85.

Beniwal A, Saini P, Kokkiligadda A, Vij S (2018) Use of silicon dioxide nanoparticles for β-galactosidase immobilization and modulated ethanol production by co-immobilized K. marxianus and S. cerevisiae in deproteinized cheese whey. Lwt 87:553–561CrossRef

86.

Kim Y-K, Lee H (2016) Use of magnetic nanoparticles to enhance bioethanol production in syngas fermentation. Bioresour Technol 204:139–144CrossRef

87.

Kim Y-K, Park SE, Lee H, Yun JY (2014) Enhancement of bioethanol production in syngas fermentation with Clostridium ljungdahlii using nanoparticles. Bioresour Technol 159:446–450CrossRef

88.

Elreedy A, Ibrahim E, Hassan N, El-Dissouky A, Fujii M, Yoshimura C, Tawfik A (2017) Nickel-graphene nanocomposite as a novel supplement for enhancement of biohydrogen production from industrial wastewater containing mono-ethylene glycol. Energy Convers Manag 140:133–144CrossRef

89.

Mostafa A, El-Dissouky A, Fawzy A, Farghaly A, Peu P, Dabert P, Le Roux S, Tawfik A (2016) Magnetite/graphene oxide nano-1 A. Mostafa, A. El-Dissouky, A. Fawzy, A. Farghaly, P. Peu, P. Dabert, S. Le Roux and A. Tawfik, Bioresour. Technol., 2016, 216, 520–528. Composite for enhancement of hydrogen production from gelatinaceous wastewater.. https://doi.org/10.1016/j.biortech.2016.05.072

90.

Mullai P, Yogeswari MK, Sridevi K (2013) Optimisation and enhancement of biohydrogen production using nickel nanoparticles – a novel approach. Bioresour Technol 141:212–219. https://doi.org/10.1016/j.biortech.2013.03.082

91.

Zhang Y, Shen J (2007) Enhancement effect of gold nanoparticles on biohydrogen production from artificial wastewater. Int J Hydrogen Energy 32:17–23. https://doi.org/10.1016/j.ijhydene.2006.06.004

92.

Ramprakash B, Lindblad P, Eaton-Rye JJ, Incharoensakdi A (2022) Current strategies and future perspectives in biological hydrogen production: a review. Renew Sustain Energy Rev 168:112773CrossRef

93.

Sangyoka S, Reungsang A, Lin C-Y (2016) Optimization of biohydrogen production from sugarcane bagasse by mixed cultures using a statistical method. Sustain Environ Res 26:235–242CrossRef

94.

Mishra P, Singh L, Islam MA, Nasrullah M, Sakinah AMM, Ab Wahid Z (2019) NiO and CoO nanoparticles mediated biological hydrogen production: Effect of Ni/Co oxide NPs-ratio. Bioresour Technol Reports 5:364–368CrossRef

95.

Zhang Y-T, Wei W, Ni B-J (2021) Revealing the mechanism of zinc oxide nanoparticles facilitating hydrogen production in alkaline anaerobic fermentation of waste activated sludge. J Clean Prod 328:129580CrossRef

96.

Khajuria A, Matsui T, Machimura T, Morioka T (2010) Assessment of the challenge of sustainable recycling of municipal solid waste management in India. Int J Environ Technol Manag 13:171–187CrossRef

Titel: Waste to Energy Conversion: Key Elements for Sustainable Waste Management
verfasst von: Karambir Singh
Naveen Kumar
Akhilesh Bharti
Pankaj Thakur
Vinod Kumar
Verlag: Springer Nature Singapore
Buch: Integrated Waste Management
Print ISBN: 978-981-9708-22-2

Electronic ISBN: 978-981-9708-23-9

Copyright-Jahr: 2024
DOI: https://doi.org/10.1007/978-981-97-0823-9_5