開發離子導體材料回收生物質發酵液中琥珀酸

廖裕倫; Yu-Lun Liao

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/90497

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	潘述元	zh_TW
dc.contributor.advisor	Shu-Yuan Pan	en
dc.contributor.author	廖裕倫	zh_TW
dc.contributor.author	Yu-Lun Liao	en
dc.date.accessioned	2023-10-03T16:21:11Z	-
dc.date.available	2023-11-09	-
dc.date.copyright	2023-10-03	-
dc.date.issued	2023	-
dc.date.submitted	2023-08-09	-
dc.identifier.citation	1.Sauer, M., et al., Microbial production of organic acids: expanding the markets. Trends in Biotechnology, 2008. 26(2): p. 100-108. 2.Sadare, O.O., et al., Membrane Purification Techniques for Recovery of Succinic Acid Obtained from Fermentation Broth during Bioconversion of Lignocellulosic Biomass: Current Advances and Future Perspectives. Sustainability, 2021. 13(12). 3.Handojo, L., et al., Electro-membrane processes for organic acid recovery. RSC Advances, 2019. 9(14): p. 7854-7869. 4.Narisetty, V., et al., Technological advancements in valorization of second generation (2G) feedstocks for bio-based succinic acid production. Bioresource Technology, 2022. 360: p. 127513. 5.Hülber-Beyer, É., K. Bélafi-Bakó, and N. Nemestóthy, Low-waste fermentation-derived organic acid production by bipolar membrane electrodialysis—an overview. Chemical Papers, 2021. 75(10): p. 5223-5234. 6.Wang, J., A.-p. Zeng, and W. Yuan, Succinic acid fermentation from agricultural wastes: The producing microorganisms and their engineering strategies. Current Opinion in Environmental Science & Health, 2022. 25: p. 100313. 7.Zhou, S., et al., Hydrolysis of lignocellulose to succinic acid: a review of treatment methods and succinic acid applications. Biotechnology for Biofuels and Bioproducts, 2023. 16(1): p. 1. 8.Werpy, T. and G. Petersen, Top Value Added Chemicals from Biomass: Volume I -- Results of Screening for Potential Candidates from Sugars and Synthesis Gas. 2004: United States. 9.Almqvist, H., et al., Succinic acid production by Actinobacillus succinogenes from batch fermentation of mixed sugars. Journal of Industrial Microbiology and Biotechnology, 2016. 43(8): p. 1117-1130. 10.Dickson, R., et al., Sustainable bio-succinic acid production: superstructure optimization, techno-economic, and lifecycle assessment. Energy & Environmental Science, 2021. 14(6): p. 3542-3558. 11.Ioannidou, S.M., et al., Sustainable production of bio-based chemicals and polymers via integrated biomass refining and bioprocessing in a circular bioeconomy context. Bioresource Technology, 2020. 307: p. 123093. 12.Akhtar, J., A. Idris, and R. Abd. Aziz, Recent advances in production of succinic acid from lignocellulosic biomass. Applied Microbiology and Biotechnology, 2014. 98(3): p. 987-1000. 13.Karp, E.M., et al., Post-Fermentation Recovery of Biobased Carboxylic Acids. ACS Sustainable Chemistry & Engineering, 2018. 6(11): p. 15273-15283. 14.Garcia-Aguirre, J., et al., Up-concentration of succinic acid, lactic acid, and ethanol fermentations broths by forward osmosis. Biochemical Engineering Journal, 2020. 155: p. 107482. 15.Lee, J.-S., et al., Production of succinic acid through the fermentation of Actinobacillus succinogenes on the hydrolysate of Napier grass. Biotechnology for Biofuels and Bioproducts, 2022. 15(1): p. 9. 16.Law, J.Y., et al., Recovery of succinic acid from fermentation broth by forward osmosis-assisted crystallization process. Journal of Membrane Science, 2019. 583: p. 139-151. 17.Xu, C., et al., Liquid hot water pretreatment combined with high-solids enzymatic hydrolysis and fed-batch fermentation for succinic acid sustainable processed from sugarcane bagasse. Bioresource Technology, 2023. 369: p. 128389. 18.Louasté, B. and N. Eloutassi, Succinic acid production from whey and lactose by Actinobacillus succinogenes 130Z in batch fermentation. Biotechnology Reports, 2020. 27: p. e00481. 19.Song, Y., et al., Utilization of bamboo as biorefinery feedstock: Co-production of xylo-oligosaccharide with succinic acid and lactic acid. Bioresource Technology, 2023. 372: p. 128694. 20.Omwene, P.I., et al., Recovery of succinic acid from whey fermentation broth by reactive extraction coupled with multistage processes. Journal of Environmental Chemical Engineering, 2020. 8(5): p. 104216. 21.Li, Q., et al., One step recovery of succinic acid from fermentation broths by crystallization. Separation and Purification Technology, 2010. 72(3): p. 294-300. 22.Thuy, N.T.H. and A. Boontawan, Production of very-high purity succinic acid from fermentation broth using microfiltration and nanofiltration-assisted crystallization. Journal of Membrane Science, 2017. 524: p. 470-481. 23.Cheng, K.-K., et al., Downstream processing of biotechnological produced succinic acid. Applied Microbiology and Biotechnology, 2012. 95(4): p. 841-850. 24.Kurzrock, T. and D. Weuster-Botz, Recovery of succinic acid from fermentation broth. Biotechnology Letters, 2010. 32(3): p. 331-339. 25.López-Garzón, C.S. and A.J.J. Straathof, Recovery of carboxylic acids produced by fermentation. Biotechnology Advances, 2014. 32(5): p. 873-904. 26.Gausmann, M., et al., Recovery of succinic acid by integrated multi-phase electrochemical pH-shift extraction and crystallization. Separation and Purification Technology, 2020. 240: p. 116489. 27.Hong, Y.K., W.H. Hong, and D.H. Han, Application of reactive extraction to recovery of carboxylic acids. Biotechnology and Bioprocess Engineering, 2001. 6(6): p. 386-394. 28.Islam, M.A., et al., Adsorption of humic and fulvic acids onto a range of adsorbents in aqueous systems, and their effect on the adsorption of other species: A review. Separation and Purification Technology, 2020. 247: p. 116949. 29.Luongo, V., et al., Lactic acid recovery from a model of Thermotoga neapolitana fermentation broth using ion exchange resins in batch and fixed-bed reactors. Separation Science and Technology, 2019. 54(6): p. 1008-1025. 30.Huang, C., et al., Application of electrodialysis to the production of organic acids: State-of-the-art and recent developments. Journal of Membrane Science, 2007. 288(1): p. 1-12. 31.Tedesco, M., H.V.M. Hamelers, and P.M. Biesheuvel, Nernst-Planck transport theory for (reverse) electrodialysis: III. Optimal membrane thickness for enhanced process performance. Journal of Membrane Science, 2018. 565: p. 480-487. 32.Arar, Ö., et al., Various applications of electrodeionization (EDI) method for water treatment—A short review. Desalination, 2014. 342: p. 16-22. 33.Hakim, A.N., et al., Ionic Separation in Electrodeionization System: Mass Transfer Mechanism and Factor Affecting Separation Performance. Separation & Purification Reviews, 2020. 49(4): p. 294-316. 34.Zhang, D., et al., Atomic scale understanding of organic anion separations using ion-exchange resins. Journal of Membrane Science, 2021. 624: p. 118890. 35.Rathi, B.S., P.S. Kumar, and R. Parthiban, A review on recent advances in electrodeionization for various environmental applications. Chemosphere, 2022. 289: p. 133223. 36.Chen, T., et al., Application of bipolar membrane electrodialysis for simultaneous recovery of high-value acid/alkali from saline wastewater: An in-depth review. Water Research, 2022. 226: p. 119274. 37.Bunani, S., et al., Application of bipolar membrane electrodialysis (BMED) for simultaneous separation and recovery of boron and lithium from aqueous solutions. Desalination, 2017. 424: p. 37-44. 38.Tang, W., et al., Various cell architectures of capacitive deionization: Recent advances and future trends. Water Research, 2019. 150: p. 225-251. 39.Zhao, R., P.M. Biesheuvel, and A. van der Wal, Energy consumption and constant current operation in membrane capacitive deionization. Energy & Environmental Science, 2012. 5(11): p. 9520-9527. 40.Alvarado, L. and A. Chen, Electrodeionization: Principles, Strategies and Applications. Electrochimica Acta, 2014. 132: p. 583-597. 41.Chen, T.-L., et al., Advanced ammonia nitrogen removal and recovery technology using electrokinetic and stripping process towards a sustainable nitrogen cycle: A review. Journal of Cleaner Production, 2021. 309: p. 127369. 42.Bazinet, L. and T.R. Geoffroy, Electrodialytic Processes: Market Overview, Membrane Phenomena, Recent Developments and Sustainable Strategies. Membranes, 2020. 10(9). 43.Sauer, M.C., et al., Electrical Conductance of Porous Plugs - Ion Exchange Resin-Solution Systems. Industrial & Engineering Chemistry, 1955. 47(10): p. 2187-2193. 44.Alvarado, L., I. Rodríguez-Torres, and P. Balderas, Investigation of Current Routes in Electrodeionization System Resin Beds During Chromium Removal. Electrochimica Acta, 2015. 182: p. 763-768. 45.La Cerva, M., et al., Determination of limiting current density and current efficiency in electrodialysis units. Desalination, 2018. 445: p. 138-148. 46.Song, J.-H., et al., Purification of a primary coolant in a nuclear power plant using a magnetic filter — electrodeionization hybrid separation system. Journal of Radioanalytical and Nuclear Chemistry, 2005. 262(3): p. 725-732. 47.Song, J.-H., K.-H. Yeon, and S.-H. Moon, Effect of current density on ionic transport and water dissociation phenomena in a continuous electrodeionization (CEDI). Journal of Membrane Science, 2007. 291(1): p. 165-171. 48.Pan, S.-Y., et al., Energy-efficient resin wafer electrodeionization for impaired water reclamation. Journal of Cleaner Production, 2018. 174: p. 1464-1474. 49.Arora, M.B., et al., The Separative Bioreactor: A Continuous Separation Process for the Simultaneous Production and Direct Capture of Organic Acids. Separation Science and Technology, 2007. 42(11): p. 2519-2538. 50.Lopez, A.M. and J.A. Hestekin, Improved organic acid purification through wafer enhanced electrodeionization utilizing ionic liquids. Journal of Membrane Science, 2015. 493: p. 200-205. 51.McKeen, L.W., 9 - Polyolefins, Polyvinyls, and Acrylics, in Permeability Properties of Plastics and Elastomers (Third Edition), L.W. McKeen, Editor. 2012, William Andrew Publishing: Oxford. p. 145-193. 52.Chen, M., et al., Self-adhesive ionomers for durable low-temperature anion exchange membrane electrolysis. Journal of Power Sources, 2022. 536: p. 231495. 53.Palakkal, V.M., et al., Advancing electrodeionization with conductive ionomer binders that immobilize ion-exchange resin particles into porous wafer substrates. npj Clean Water, 2020. 3(1): p. 5. 54.Fasuyi, A. and A.M. Lopez, Influence of poly(ionic) liquid incorporation within resin wafer electrodeionization for reduced energy consumption in brackish water desalination. Chemical Engineering Journal, 2023. 454: p. 140209. 55.Jordan, M.L., et al., Integrated Ion-Exchange Membrane Resin Wafer Assemblies for Aromatic Organic Acid Separations Using Electrodeionization. ACS Sustainable Chemistry & Engineering, 2023. 11(3): p. 945-956. 56.Parnian, M.J., S. Rowshanzamir, and F. Gashoul, Comprehensive investigation of physicochemical and electrochemical properties of sulfonated poly (ether ether ketone) membranes with different degrees of sulfonation for proton exchange membrane fuel cell applications. Energy, 2017. 125: p. 614-628. 57.Maria Mahimai, B., et al., Sulfonated poly(ether ether ketone): efficient ion-exchange polymer electrolytes for fuel cell applications–a versatile review. Materials Advances, 2022. 3(15): p. 6085-6095. 58.Akhtar, F.H., et al., Defining sulfonation limits of poly(ether-ether-ketone) for energy-efficient dehumidification. Journal of Materials Chemistry A, 2021. 9(33): p. 17740-17748. 59.Zheng, X.-Y., et al., Optimization of resin wafer electrodeionization for brackish water desalination. Separation and Purification Technology, 2018. 194: p. 346-354. 60.Ulusoy Erol, H.B., C.N. Hestekin, and J.A. Hestekin, Effects of Resin Chemistries on the Selective Removal of Industrially Relevant Metal Ions Using Wafer-Enhanced Electrodeionization. Membranes, 2021. 11(1). 61.Sun, X., H. Lu, and J. Wang, Recovery of citric acid from fermented liquid by bipolar membrane electrodialysis. Journal of Cleaner Production, 2017. 143: p. 250-256. 62.Park, S. and R. Kwak, Microscale electrodeionization: In situ concentration profiling and flow visualization. Water Research, 2020. 170: p. 115310. 63.Alvarado, L., A. Ramírez, and I. Rodríguez-Torres, Cr(VI) removal by continuous electrodeionization: Study of its basic technologies. Desalination, 2009. 249(1): p. 423-428. 64.Prochaska, K., et al., Removal of succinic acid from fermentation broth by multistage process (membrane separation and reactive extraction). Separation and Purification Technology, 2018. 192: p. 360-368. 65.Szczygiełda, M., J. Antczak, and K. Prochaska, Separation and concentration of succinic acid from post-fermentation broth by bipolar membrane electrodialysis (EDBM). Separation and Purification Technology, 2017. 181: p. 53-59. 66.Fu, L., et al., Preparation of succinic acid using bipolar membrane electrodialysis. Separation and Purification Technology, 2014. 127: p. 212-218. 67.TPC, Rate schedules. 2021: https://www.taipower.com.tw/tc/index.aspx. 68.Chen, T.-H., et al., Technological and economic perspectives of membrane capacitive deionization (MCDI) systems in high-tech industries: From tap water purification to wastewater reclamation for water sustainability. Resources, Conservation and Recycling, 2022. 177: p. 106012. 69.Strathmann, H., A. Grabowski, and G. Eigenberger, Ion-Exchange Membranes in the Chemical Process Industry. Industrial & Engineering Chemistry Research, 2013. 52(31): p. 10364-10379. 70.Tang, H., et al., Ion migration characteristics during the bipolar membrane electrodialysis treatment of concentrated reverse osmosis brine. Desalination, 2023. 561: p. 116660.	-
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/90497	-
dc.description.abstract	在生物精煉概念下，將生物質作為原料，透過微生物發酵轉化為高價化學品或化學原料的生產途徑，因相較於化學合成生產途徑，可減少對於石化原料依賴，實現循環經濟目標，引起研究單位和產業的關注。琥珀酸便是一種能透過微生物發酵生產之高價化學品，但發酵液複雜成分具其他副產物（例如：醋酸、甲酸），需要透過下游分離純化技術來獲得高純度之琥珀酸產品。目前傳統分離純化處理技術成本高，因此相較於化學合成途徑，發酵過程生產出的琥珀酸的較不具經濟優勢。本研究開發離子導體材料應用於電去離子（Electrodeionization，簡稱EDI）技術，以高效率且低能耗的分離純化程序來回收琥珀酸。本研究首先進行由離子聚合物與離子交換樹脂組成的離子導體材料（Ionically Conductive Material，簡稱ICM）開發與製作，並對其物化特性進行探討。相較於傳統的樹脂晶圓（Resin wafer，簡稱RW），ICM表現出更高的樹脂填充量，及更優異之導電特性，使系統在分離稀薄琥珀酸溶液時系統導電度可提升兩個數量級，且展現出較高的極限電流密度；將ICM材料導入雙極膜電去離子模組中，來研析ICM材料對於合成的發酵液之琥珀酸關鍵分離指標（例如：回收效率、能耗、產率及電流效率）。根據本研究結果顯示，相較於傳統RW材料，本研究開發之ICM能在25 V時提升1.4倍之產率（至0.55 kg/m2/h），程序能耗約為2.53 kWh/kg，且電流效率維持在90%以上。最後，本研究為了解離子導體材料應用於雙極膜電去離子模組回收琥珀酸之可行性，進行初步成本效益分析，在25 V之施加電壓情況下，益本比約為4.49，顯示出此技術結合ICM材料於回收琥珀酸上具有經濟效益。綜合以上，本研究成功開發離子導電材料並應用於電去離子技術中，提升從生物質發酵液中回收琥珀酸之效率，並降低分離程序能耗，促進生物精煉和永續化學品生產加速落實。	zh_TW
dc.description.abstract	Under the concept of biorefinery, the utilization of biomass as a raw material and its conversion into high-value chemicals or chemical feedstocks through microbial fermentation has gained significant attention from research institutions and industries. This approach offers several advantages, including reduced reliance on petrochemicals and contributions to achieving a circular economy. One such high-value chemical is succinic acid, which can be produced through microbial fermentation. However, the fermentation broth contains complex components and by-products like acetic acid and formic acid, necessitating downstream separation and purification processes to obtain high-purity succinic acid products. Currently, traditional separation and purification techniques are costly, making the production of succinic acid through the fermentation process less economically advantageous compared to chemical synthesis routes. To address this challenge, this study aims to develop an ionically conductive material (ICM) for use in electrodeionization (EDI) technology, enabling efficient and low-energy consumption separation and purification processes for succinic acid recovery. Initially, the ICM, composed of ionomer and ion exchange resins, is developed and manufactured, and its physicochemical properties are thoroughly investigated. Compared to the traditional resin wafer (RW), the ICM exhibits higher resin loading and superior electric conductivity performance, resulting in a two-order of magnitude increase in system conductivity when separating low concentration succinic acid solutions. Additionally, the ICM demonstrates higher limiting current density. These characteristics make it a promising candidate for succinic acid recovery. The ICM material is then integrated into a bipolar membrane electrodeionization (BMEDI) module to evaluate its key performance indicators, including recovery efficiency, energy consumption, productivity, and current efficiency, in the separation of simulated succinate fermentation broth. The research results demonstrate that, when compared to RW, the ICM achieves a remarkable 1.4-fold increase in productivity, reaching 0.55 kg/m2/h at 25 V, with an energy consumption of 2.53 kWh/kg, while maintaining a current efficiency above 90%. Finally, a preliminary cost-benefit analysis is conducted to assess the feasibility of applying the ICM in succinic acid recovery through BMEDI. The analysis reveals a benefit-cost ratio (BCR) of 4.49 under a voltage of 25 V, indicating that this technology holds significant economic benefits for the recovery of succinic acid. In conclusion, the development and application of the ionically conductive material in electrodeionization technology present a promising and economically viable approach to enhance the efficiency of succinic acid recovery from fermentation broth, thereby advancing the prospects of biorefinery concepts and sustainable chemical production.	en
dc.description.provenance	Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2023-10-03T16:21:11Z No. of bitstreams: 0	en
dc.description.provenance	Made available in DSpace on 2023-10-03T16:21:11Z (GMT). No. of bitstreams: 0	en
dc.description.tableofcontents	口試委員會審定書 i 誌謝 ii 中文摘要 iii ABSTRACT v CONTENTS vii LIST OF FIGURES x LIST OF TABLEES xiii Abbreviation xiv Chapter 1 Introduction 1 1.1 Background 1 1.2 Objective 4 Chapter 2 Literature review 5 2.1 Succinic acid production and recovery 5 2.1.1 Bio-base Succinic acid market value 5 2.1.2 Biomass for succinic acid production 7 2.1.3 Traditional succinic acid recovery methods 10 2.1.3.1 Precipitation 10 2.1.3.2 Reactive Extraction 10 2.1.3.3 Ion exchange adsorption 11 2.2 Electro-membrane technology 13 2.2.1 Electrodialysis (ED) 13 2.2.2 Electrodeionization (EDI) 15 2.2.3 Bipolar membrane electrodialysis (BMED) 16 2.2.4 Membrane capacitive deionization (MCDI) 18 2.3 EDI mechanisms and model 20 2.3.1 Ion separation mechanism in EDI 20 2.3.2 Water dissociation reaction 21 2.3.3 Porous plug model 23 2.3.4 Limiting current density 25 2.4 Emerging innovation porous material in EDI 27 2.4.1 Innovation in resin wafer material 27 2.4.2 Resin-Wafer EDI system improvement 28 Chapter 3 Materials and Methods 30 3.1 Research framework 30 3.2 Material and apparatus 31 3.2.1 Chemicals 31 3.2.2 Membranes 32 3.2.3 Ion exchange resin 33 3.2.4 Apparatus 34 3.2.5 Simulation fermentation broth 35 3.3 Methods 36 3.3.1 SPEEK Ionomer Preparation 36 3.3.2 Manufacture ICM and Resin Wafer 38 3.3.3 Electrical conductivity test 41 3.3.4 BMEDI processes 43 3.4 Analytical instrument 45 3.4.1 Nuclear Magnetic Resonance, NMR 45 3.4.2 Inductance capacitance resistance meter (LCR) 46 3.4.3 Scanning Electron Microscope (SEM) 47 3.4.4 High Performance Liquid Chromatography (HPLC) 48 3.5 Key Performance Indicators 49 3.5.1 Material characteristic performance 49 3.5.2 Separation performance in BMEDI 52 Chapter 4 Results and Discussion 54 4.1 Characteristics of ICM and Resin-Wafer Materials 54 4.1.1 Resin characteristics 54 4.1.2 SPEEK characteristics 55 4.1.3 Physical characteristic analysis 56 4.1.4 SEM analysis 57 4.1.5 Electric Conductivity analysis 59 4.2 Porous plug model 63 4.3 Limiting current density 67 4.4 Evaluating BMEDI performance in separation of succinic acid 69 4.4.1 Effect of different applied voltage on recovery efficiency 70 4.4.2 Effect of different flowrate on recovery efficiency 76 4.4.3 Effect of different AER type on recovery efficiency 78 4.4.4 Effect of resin ratio on recovery efficiency 80 4.4.5 Current efficiency, Energy consumption, and Productivity 82 4.4.6 First order kinetic model 86 4.5 Cost and benefit analysis for recovery succinic acid 89 Chapter 5 Conclusions and Recommendations 96 5.1 Conclusions 96 5.2 Recommendations 98 References 99 Appendix I 105 Appendix II: Response to the Comments from Committees 115	-
dc.language.iso	en	-
dc.subject	琥珀酸	zh_TW
dc.subject	電去離子	zh_TW
dc.subject	離子導體材料	zh_TW
dc.subject	發酵液	zh_TW
dc.subject	循環經濟	zh_TW
dc.subject	Ionically conductive materials	en
dc.subject	Electrodeionization	en
dc.subject	Fermentation broth	en
dc.subject	Succinic acid	en
dc.subject	Circular Economy	en
dc.title	開發離子導體材料回收生物質發酵液中琥珀酸	zh_TW
dc.title	Development of ionically conductive materials for recovery of succinic acid from biomass fermentation broth	en
dc.type	Thesis	-
dc.date.schoolyear	111-2	-
dc.description.degree	碩士	-
dc.contributor.oralexamcommittee	范致豪;侯嘉洪;邱求三;高夢瑤	zh_TW
dc.contributor.oralexamcommittee	Chih-Hao Fan;Chia-Hung Hou;Chyow-San Chiou ;Meng-Yao Gao	en
dc.subject.keyword	琥珀酸,離子導體材料,電去離子,發酵液,循環經濟,	zh_TW
dc.subject.keyword	Succinic acid,Ionically conductive materials,Electrodeionization,Fermentation broth,Circular Economy,	en
dc.relation.page	118	-
dc.identifier.doi	10.6342/NTU202302122	-
dc.rights.note	未授權	-
dc.date.accepted	2023-08-10	-
dc.contributor.author-college	生物資源暨農學院	-
dc.contributor.author-dept	生物環境系統工程學系	-
顯示於系所單位：	生物環境系統工程學系

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