STUDY ON PROMOTING EFFECT OF IRON-BASED AND SILICON-BASED MATERIALS ON BIOGAS PRODUCTION BY ANAEROBICFERMENTATION OF ORGANIC WASTE

Dong Xiaoying; Fu Jiahui; Xiao Yonghou; Zhou Yang; Ning Yuewen; Xu Weiping

doi:10.19912/j.0254-0096.tynxb.2021-0964

PDF(1775 KB)

Acta Energiae Solaris Sinica ›› 2022, Vol. 43 ›› Issue (11) : 317-324. DOI: 10.19912/j.0254-0096.tynxb.2021-0964

STUDY ON PROMOTING EFFECT OF IRON-BASED AND SILICON-BASED MATERIALS ON BIOGAS PRODUCTION BY ANAEROBICFERMENTATION OF ORGANIC WASTE

Dong Xiaoying^1,2, Fu Jiahui², Xiao Yonghou², Zhou Yang³, Ning Yuewen³, Xu Weiping^2,4

Author information +

History +

Abstract

Three synthesized functional materials, such as Fe₂O₃, Silicalite-1 and Fe₂O₃@Silicalite-1 are investigated for subsequent promotional effects upon gas generation by utilizing organic waste （chicken manure） in anaerobic fermentation for the first time. The results exhibited that the daily biogas yield and methane contents are effectively improved by using functional materials compared with the blank groups. Among them, the Fe₂O₃@Silicalite-1 demonstrated the best performance in terms of the maximum cumulative gas yield and methane contents are increased by 41.39% and 17.24% compared to date of blank group, respectively. Fe₂O₃ group increases by 31.07% and 10.34%, and Silicalite-1 increases by 23.98% and 12.07% when compared with the date of blank group, respectively. As opposed to agglomeration of nanoparticles in traditional methods, nanostructured Fe₂O₃ dispersed on the surface of porous material Silicate-1 could be employed as an effective anaerobic fermentation catalyst against deactivation caused by agglomeration and hence maintains superior performance. Therefore, the energy and environmental benefits of organic waste treatment process could be accomplished by smart tailoring of composite materials with anaerobic fermentation technology.

Key words

Fe₂O₃ / Silicalite-1 / organic waste oxygenation / anaerobic fermentation / biogas / methane

Cite this article

EndNote

Ris (Procite)

Bibtex

Download Citations

Dong Xiaoying, Fu Jiahui, Xiao Yonghou, Zhou Yang, Ning Yuewen, Xu Weiping. STUDY ON PROMOTING EFFECT OF IRON-BASED AND SILICON-BASED MATERIALS ON BIOGAS PRODUCTION BY ANAEROBICFERMENTATION OF ORGANIC WASTE[J]. Acta Energiae Solaris Sinica. 2022, 43(11): 317-324 https://doi.org/10.19912/j.0254-0096.tynxb.2021-0964

References

[1] ZENG L, MANGAN C, LI X.Ammonia recovery from anaerobically digested cattle manure by steam stripping[J]. Water science and technology, 2006, 54(8): 137-145.
[2] BAYRAKDAR A, MOLAEY R, SURMELI R O, et al.Biogas production from chicken manure: co-digestion with spent poppy straw[J]. International biodeterioration & biodegradation, 2017, 119(14): 205-210.
[3] 卓振, 张卫民, 陈家鸿, 等. 沸石负载纳米氧化铁处理氮磷污水研究[J]. 有色金属(冶炼部分), 2021(6): 101-108.
ZHUO Z,ZHANG W M, CHEN J H, et al.Zeolite@Fe₃O₄ for treatment of nitrogen and phosphorus wastewater[J]. Nonferrous metals(extractive metallurgy), 2021(6): 101-108.
[4] 李冬梅, 林洁漫, 李子亚, 等. 氧化铁改性砂联合生物预处理对氨氮的吸附特性[J]. 环境工程学报, 2015, 9(12): 5683-5688.
LI D M, LIN J M, LI Z Y, et al.Adsorption property of iron oxide coated sand combined with biology pretreatment to NH₃-N[J]. Chinese journal of environmental engineering, 2015, 9(12): 5683-5688.
[5] POIRIER S, DEIEAN S, CHAPLEUR O.Support media can steer methanogenesis in the presence of phenol through biotic and abiotic effects[J]. Water research, 2018, 140(9): 24-33.
[6] POIRIER S, CHAPLEUR O.Influence of support media supplementation to reduce the inhibition of anaerobic digestion by phenol and ammonia: effect on degradation performances and microbial dynamics[J]. Data in brief, 2018, 19(8): 1733-1754.
[7] AMEN T W M, ELJAMAL O, KHALIL A M E, et al. Biochemical methane potential enhancement of domestic sludge digestion by adding pristine iron nanoparticles and iron nanoparticles coated zeolite compositions[J]. Journal of environmental chemical engineering, 2017, 5(5): 5002-5013.
[8] LU X F, WANG H D, MA F, et al.Enhanced anaerobic digestion of cow manure and rice straw by the supplementation of an iron oxide-zeolite system[J]. Energy & fuels, 2017, 31(1): 599-606.
[9] ARIF S, LIAQUAT R, ADIL M.Applications of materials as additives in anaerobic digestion technology[J]. Renewable and sustainable energy reviews, 2018, 97(12): 354-366.
[10] BANIAMERIAN H, ISFAHANI P G, TSAPEKOS P, et al.Application of nano-structured materials in anaerobic digestion: current status and perspectives[J]. Chemosphere, 2019, 229(8): 188-199.
[11] LIN R, CHENG J, ZHANG J, et al.Boosting biomethane yield and production rate with graphene: the potential of direct interspecies electron transfer in anaerobic digestion[J]. Bioresource technology, 2017, 239(9): 345-352.
[12] BARUA S, DHAR B R.Advances towards understanding and engineering direct interspecies electron transfer in anaerobic digestion[J]. Bioresource technology, 2017, 244(11): 698-707.
[13] MARTINS G, SALVADOR A F, PEREIRA L, et al.Methane production and conductive materials: a critical review[J]. Environmental science & technology, 2018, 52(18): 10241-10253.
[14] WU Y, WANG S, LIANG D H, et al.Conductive materials in anaerobic digestion: from mechanism to application[J]. Bioresource technology, 2020, 298(2): 122403-122414.
[15] BARRENA R, VARGAS-GARCIA M, CAPELL G, et al.Sustained effect of zero-valent iron nanoparticles under semi-continuous anaerobic digestion of sewage sludge: evolution of nanoparticles and microbial community dynamics[J]. Science of the total environment, 2021, 777(7): 145969-145980.
[16] AJAY C M, MOHAN S, DINESHA P, et al.Review of impact of nanoparticle additives on anaerobic digestion and methane generation[J]. Fuel, 2020, 277(10): 118234-118245.
[17] ABDELSALAM E, SAMER M, ATTIA Y A, et al.Influence of zero valent iron nanoparticles and magnetic iron oxide nanoparticles on biogas and methane production from anaerobic digestion of manure[J]. Energy, 2017, 120(2): 842-853.
[18] WANG L, XU S D, HE S X, et al.Rational construction of metal nanoparticles fixed in zeolite crystals as highly efficient heterogeneous catalysts[J]. Nano today, 2018, 20(6): 74-83.
[19] WANF Q H, KUNNINOBU M, OGAWA H I, et a1. Degradation of volatile fatty acids in highly efficient anaerobic digestion[J]. Biomass and bioenergy, 1999, 16: 407-416.
[20] WANG T, ZHANG D, DAI L L, et al.Effects of metal nanoparticles on methane production from waste-activated sludge and microorganism community shift in anaerobic granular sludge[J]. Scientific reports, 2016, 6(1): 1-10.
[21] YAN W, NAN S, XIAO Y, et al.The role of conductive materials in the start-up period of thermophilic anaerobic system[J]. Bioresource technology, 2017, 239(9): 336-344.
[22] ZHAO C, SHARMA A, MA Q, et al.A developed hybrid fixed-bed bioreactor with Fe-modified zeolite to enhance and sustain biohydrogen production[J]. Science of the total environment, 2021, 758(3): 143658-143659.
[23] AMBUCHI J J, ZHANG Z H, FENG Y J, et al.Biogas enhancement using iron oxide nanoparticles and multi-wall carbon nanotubes[J]. International scholarly and scientific research & innovation, 2016, 10(10): 1239-1246.
[24] ZHANG J C, LU Y H.Conductive Fe₃O₄ nanoparticles accelerate syntrophic methane production from butyrate oxidation in two different lake sediments[J]. Frontiers in microbiology, 2016, 7(8): 1316-1324.
[25] ZHANG L, ZHANG J X, LOH K C.Enhanced food waste anaerobic digestion: an encapsulated metal additive for shear stress-based controlled release[J]. Journal of cleaner production, 2019, 235: 85-95.
[26] NEL A E, MADLER L, VELEGOL D, et al.Understanding biophysicochemical interactions at the nano-bio interface[J]. Nature materials, 2009, 8(7): 543-557.
[27] VAN STEENDAM C, SMETS I, SKERLOS S, et al.Improving anaerobic digestion via direct interspecies electron transfer requires development of suitable characterization methods[J]. Current opinion in biotechnology, 2019, 57: 183-190.
[28] BI S J, QIAO W, XIONG L P, et al.Improved high solid anaerobic digestion of chicken manure by moderate in situ ammonia stripping and its relation to metabolic pathway[J]. Renewable energy, 2020, 146: 2380-2389.