Abstract
Hydrogen gas (H2) is a clean fuel and contained a relatively high energy density which is about 142 kJ g−1. Recently, increasing attention has been given to the production of H2 from biological route. The biological H2 (biohydrogen) process is an H2 production by microorganisms that utilize renewable energy resources as substrates. Possible biohydrogen production technologies include biophotolysis, photo-fermentation processes, and the dark fermentation route. Among these three production processes, the dark fermentation process is often regarded as the most potential route. It generates H2 by utilizing carbohydrates as the carbon sources whereby glucose was found to be the most commonly used substrate. A high yield of biohydrogen, i.e., about 4 mol of H2 per mole of glucose consumed can possibly be achieved through this route. Despite a reasonably high yield, industrial-grade glucose (35–50 USD per kg) is expensive and therefore, rendering the process less economical especially considering market value for H2 typically ranging only between 3 and 5 USD per kg. Obviously, cheaper substrates are needed if dark fermentation process is ever to strive as the potential route for biohydrogen production. In Malaysia, abundance of agricultural waste is disposed into landfills annually and thus, making it free un-tap resources. This chapter reports the prospect and challenges of utilizing agro-waste as the carbon source for biohydrogen production in Malaysia. The work will provide basis evaluation on the potential of biohydrogen production where agro-waste is capitalized as main substrates for the process.
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References
Abd Jalil NK, Asli UA, Hashim H, Abd Jalil A, Ahmad A, Khamis AK (2018) Biohydrogen production from pineapple biomass residue using immobilized co-cultured Clostridium sporogenes and Enterobacter aerogenes. J Energy Saf Technol 1(1):51–57
Abdeen FRH, Mel M, Jami MS, Ihsan SI, Ismail AF (2016) A review of chemical absorption of carbon dioxide for biogas upgrading. Chin J Chem Eng 24(6). https://doi.org/10.1016/j.cjche.2016.05.006
Abdul MNA, Asli UA (2019) Purification of biohydrogen from fermentation gas mixture using two-stage chemical absorption. In: E3S Web of Conferences 90. 01012. https://doi.org/10.1051/e3sconf/20199001012
Abdullah N, Sulaiman F (2013) The oil palm wastes in Malaysia. In: Matovic MD (ed) Biomass now—sustainable growth and use. IntechOpen, London
Aditiya HB, Chong WT, Mahlia TMI, Sebayang AH, Berawi MA, Nur H (2016) Second generation bioethanol potential from selected Malaysia’s biodiversity biomasses: a review. Waste Manag 47:46–61
Arisht SN, Abdul PM, Liu CM, Lin SK, Maarof RM, Wu SY, Jahim JM (2019) Biotoxicity assessment and lignocellulosic structural changes of phosphoric acid pre-treated young coconut husk hydrolysate for biohydrogen production. Int J Hydrogen Energy 44:5830–5843
Bharathiraja B, Sudharsanaa T, Bharghavi A, Jayamuthunagai J, Praveenkumar R (2016) Biohydrogen and biogas—an overview on feedstocks and enhancement process. Fuel 185:810–828
Boshagha F, Rostamib K, Moazamib N (2019) Immobilization of Enterobacter aerogenes on carbon fiber and activated carbon to study hydrogen production enhancement. Biochem Eng J 144:64–72
Chandaekar K, Lee YJ, Lee DW (2015) Biohydrogen production: strategies to improve process efficiency through microbial routes. Int J Mol Sci 16:8266–8293
Chandrasekhar K, Lee Y-J, Lee D-W (2015) Biohydrogen production: strategies to improve process efficiency through microbial routes. Int J Mol Sci 16(4):8266–8293
De Araujo Guilherme A, Dantas PVF, Padilha CE d A, dos Santos ES, de Macedo GR (2019) Ethanol production from sugarcane bagasse: use of different fermentation strategies to enhance an environmental-friendly process. J Environ Manag 234:44–51
Department of Statistic Malaysia (2018) Selected agricultural indicators. Malaysia
Ding TY, Hii SL, Ong L (2012) Comparison of pretreatment strategies for conversion of coconut husk fiber to fermentable sugars. Bioresources 7(2):1540
dos Passos VF, Marcilio R, Aquino-Neto S, Santana FB, Dias ACF, Andreote FD, de Andrade AR, Reginatto V (2019) Hydrogen and electrical energy co-generation by a cooperative fermentation system comprising Clostridium and microbial fuel cell inoculated with port drainage sediment. Bioresour Technol 277:94–103
Ghimire A, Frunzo L, Pirozzi F, Trably E, Escudie R, Lens PNL, Esposito G (2015) A review on dark fermentative biohydrogen production from organic biomass: process parameters and use of by-products. Appl Energy 144:73–95
Guo XM, Trably E, Latrille E, Carrere H, Steyer JP (2010) Hydrogen production from agriculture waste by dark fermentation: a review. Int J Hydrog Energy 35:10660–10673
Hossain MA, Jewaratnam J, Ganesan P (2016) Prospect of hydrogen production from oil palm biomass by thermochemical process: a review. Int J Hydrog Energy 41:16637–16655
ISO 14687-2:2012(en) Hydrogen fuel—product specification—Part 2: Proton exchange membrane (PEM) fuel cell applications for road vehicles
Jamil NH (2004) Biomass potential energy from agricultural wastes. Faculty of Engineering, Universiti Malaysia Sarawak
Kanchanasuta S, Prommeenate P, Boonapatcharone N, Pisutpaisal N (2017) Stability of Clostridium butyricum in biohydrogen production from non-sterile food waste. Int J Hydrog Energy 42:3454–3465
Kelly-yong TL, Lee KT, Mohamed AR, Bhatia S (2007) Potential of hydrogen from oil palm biomass as a source of renewable energy worldwide. Energy Policy 35:5692–5701
Kozłowski K, Lewicki A, Malińska K, Wei Q (2019) Current state, challenges and perspectives of biological production of hydrogen in dark fermentation process in Poland. J Ecol Eng 20:146–160
Kushairi A, Loh SK, Azman I, Hishamuddin E, Ong-Abdullah M, Mohd Noor Izuddin ZB, Razmah G, Sundram S, Ahmad Parveez GK (2018) Oil palm economic performance in Malaysia and R&D progress in 2017—review article. J Oil Palm Res 30:163–195
Lim JS, Manan ZA, Wan Alwi SR, Hashim H (2012) A review on utilisation of biomass from rice industry as a source of renewable energy. Renew Sust Energ Rev 16:3084–3094
Maarof RM, Jahim JM, Azahar AM, Abdul PM, Masdar MS, Nordin D, Abd Nasir MA (2018) Biohydrogen production from palm oil mill effluent (POME) by two stage anaerobic sequencing batch reactor (ASBR) system for better utilization of carbon sources in POME. Int J Hydrog Energy 44:3395–3406
Maeda T, Tran KT, Yamasaki R, Wood TK (2018) Current state and perspectives in hydrogen production by Escherichia coli: roles of hydrogenases in glucose or glycerol metabolism. Appl Microbiol Biotechnol. https://doi.org/10.1007/s00253-018-8752-8
Mansor AM, Lim JS, Ani FN, Hashim H, Ho WS (2018) Ultimate and proximate analysis of Malaysia pineapple biomass from MD2 cultivar for biofuel application. Chem Eng Trans 63:127–132
Mishra P, Krishnan S, Rana S, Singh L, Sakinah M, Ab Wahid Z (2019) Outlook of fermentative hydrogen production techniques: an overview of dark, photo and intergrated dark-photo fermentative approach to biomass. Energ Strat Rev 24:27–37
Ntaikou I, Antonopoulou G, Lyberatos G (2010) Biohydrogen production from biomass and wastes via dark fermentation: a review. Waste Biomass Valor 1:21–39
Pariatamby A (2017) Country chapter: state of the 3Rs in Asia and the Pacific—Malaysia. United Nations Centre for Regional Development (UNCRD). Institute for Global Environmental Strategies (IGES)
Prabakar D, Manimudi VT, Suventha SK, Sampath S, Mahapatra DM, Rajendran K, Pugazhendhi A (2018) Advanced biohydrogen production using pretreated industrial waste: outlook and prospects. Renew Sust Energ Rev 96:306–324
Puad NIM, Sulaiman S, Azmi AS, Shamsudin Y, Mel M (2015) Preliminary study on biohydrogen production by E. coli from sago waste. J Eng Sci Technol 10:12–21. Special issue on SOMCHE 2014 & RSCE 2014 Conference
Puad NIM, Mamat NA, Azmi AS (2016) Screening of various parameters of Enterobacter aerogenes batch culture for biohydrogen production. Int Proc Chem Biol Environ Eng 93:55–61
Rahman SNA, Masdar MS, Rosli MI, Majlan EH, Husaini T, Kamarudin SK, Daud WRW (2016) Overview of biohydrogen technologies and application in fuel cell technology. Renew Sust Energ Rev 66:137–162
Shafie SM (2015) Paddy residue based power generation in Malaysia: environmental assessment using LCA approach. ARPN J Eng Appl Sci 10(15)
Shafie SM, Mahlia TMI, Masjuki HH, Ahmad-Yazid A (2012) A review on electricity generation based on biomass residue in Malaysia. Renew Sust Energ Rev 16:5879–5889
Shamsuddin AH (2012) Development of renewable energy in Malaysia strategic initiatives for carbon reduction in the power generation sector. Proc Eng 49:384–391
Shell (2017) Shell hydrogen study: energy for the future? Sustainable mobility through fuel cells and H2. Hamburg
Smith BC (2019) Organic nitrogen compounds II: primary amines. Spectroscopy 34(3):22–25
Tahir TA, Hamid FS (2012) Vermicomposting of two types of coconut wastes employing Eudrilus eugeniae: a comparative study. Int J Recycling Org Waste Agric 1:7
Ulhiza TA, Puad NIM, Azmi AS (2018) Optimization of culture conditions for biohydrogen production from sago wastewater by Enterobacter aerogenes using response surface methodology. Int J Hydrog Energy 43:22148–22158
Umar MS, Jennings P, Urmee T (2014) Sustainable electricity generation from oil palm biomass wastes in Malaysia: an industry survey. Energy 67:496–505
Zheng Y, Zhao J, Xu F, Li Y (2014) Pretreatment of lignocellulosic biomass for enhanced biogas production. Prog Energy Combust Sci 42:35–53
Ziara RMM, Miller DN, Subbiah J, Dvorak BI (2019) Lactate wastewater dark fermentation: the effect of temperature and initial pH on biohydrogen production and microbial community. Int J Hydrog Energy 44:661–673
Zulkarnain D, Zuprizal, Wihandoyo, Supadmo (2006) Effects of sago waste as local feed resource that gives cellulose enzyme in feed on carcass and organ characteristics of broiler chickens. In: The 7th International Seminar on Tropical Animal Production
Acknowledgment
The work was financially supported by Universiti Teknologi Malaysia (UTM), Research University Trans-disciplinary Grants (TDR), vote no. Q.J130000.3551.06G46.
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Zainal Alam, M.N.H., Adrus, N., Abdul Wahab, M.F., Kamaruddin, M.J., Sani, M.H. (2020). Utilization of Agro-Waste as Carbon Source for Biohydrogen Production: Prospect and Challenges in Malaysia. In: Zakaria, Z., Boopathy, R., Dib, J. (eds) Valorisation of Agro-industrial Residues – Volume I: Biological Approaches. Applied Environmental Science and Engineering for a Sustainable Future. Springer, Cham. https://doi.org/10.1007/978-3-030-39137-9_6
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