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2021 | OriginalPaper | Chapter

Cost-Effective Nanomaterials Fabricated by Recycling Spent Batteries

Authors : Himadri Tanaya Das, T. Elango Balaji, K. Mahendraprabhu, S. Vinoth

Published in: Waste Recycling Technologies for Nanomaterials Manufacturing

Publisher: Springer International Publishing

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Abstract

The renewable energies have become affordable and accessible door to door due to well-equipped energy storage devices. Lithium-ion batteries (LiBs) and supercapacitors (SCs) are the prominent energy storage devices in the market. Recycling electronic wastes are one of the steps to build a greener and cleaner environment. In this chapter, reusing of disposed spent batteries components to generate electrode materials for LiBs applications has been discussed. Batteries developed from waste-materials are expected to fulfill the demand of people for energy storage devices with the high energy density in consumer electronics. Recycling LiBs will make the energy storage device, market cost-effective. Thus, apt energy storage devices are creating a new generation of electronics with excellent potential to improve the quality of human life. Owing to the advancement in or advanced, the researchers or industries are focused on developing electrodes for smart electronics by fabricating a potential device from the waste materials which is quite a challenging technique. In the context of making the environment clean and free from electronic wastages, recycling the spent batteries could be an estimable step. In this chapter, the basic recycling methods to extract the electrode materials such as different nanostructured oxides and carbon materials will be discussed along with the configuration of various electrodes and electrolytes in batteries. Such extensive discussion can bring out a summary on operational parameters such as stability, storage capacity, energy density, and cycle life of the LiBs developed from spent batteries. The discussions in-depth, on the general pros and cons of conventional energy storage devices, can lead to the next phase for generating advance battery technology from recycling the wastage.

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Literature
1.
go back to reference Das HT, Mahendraprabhu K, Maiyalagan T, Elumalai P (2017) Performance of solid-state hybrid energy-storage device using reduced graphene-oxide anchored sol-gel derived Ni/NiO nanocomposite. Sci Rep 7(1):1–14CrossRef Das HT, Mahendraprabhu K, Maiyalagan T, Elumalai P (2017) Performance of solid-state hybrid energy-storage device using reduced graphene-oxide anchored sol-gel derived Ni/NiO nanocomposite. Sci Rep 7(1):1–14CrossRef
2.
go back to reference Duraisamy E, Das HT, Sharma AS, Elumalai P (2018) Supercapacitor and photocatalytic performances of hydrothermally-derived Co3O4/CoO@ carbon nanocomposite. New J Chem 42(8):6114–6124CrossRef Duraisamy E, Das HT, Sharma AS, Elumalai P (2018) Supercapacitor and photocatalytic performances of hydrothermally-derived Co3O4/CoO@ carbon nanocomposite. New J Chem 42(8):6114–6124CrossRef
3.
go back to reference Pinna EG, Ruiz MC, Ojeda MW, Rodriguez MH (2017) Cathodes of spent Li-ion batteries: dissolution with phosphoric acid and recovery of lithium and cobalt from leach liquors. Hydrometallurgy 167:66–71CrossRef Pinna EG, Ruiz MC, Ojeda MW, Rodriguez MH (2017) Cathodes of spent Li-ion batteries: dissolution with phosphoric acid and recovery of lithium and cobalt from leach liquors. Hydrometallurgy 167:66–71CrossRef
4.
go back to reference Rajkumar S, Elanthamilan E, Balaji TE, Sathiyan A, Jafneel NE, Merlin JP (2020) Recovery of copper oxide nanoparticles from waste SIM cards for supercapacitor electrode material. J Alloy Compd 156582 Rajkumar S, Elanthamilan E, Balaji TE, Sathiyan A, Jafneel NE, Merlin JP (2020) Recovery of copper oxide nanoparticles from waste SIM cards for supercapacitor electrode material. J Alloy Compd 156582
5.
go back to reference Ali GAM, Lih Teo EY, Aboelazm EAA, Sadegh H, Memar AOH, Shahryari-Ghoshekandi R, Chong KF (2017) Capacitive performance of cysteamine functionalized carbon nanotubes. Mater Chem Phys 197:100–104CrossRef Ali GAM, Lih Teo EY, Aboelazm EAA, Sadegh H, Memar AOH, Shahryari-Ghoshekandi R, Chong KF (2017) Capacitive performance of cysteamine functionalized carbon nanotubes. Mater Chem Phys 197:100–104CrossRef
6.
go back to reference Aboelazm EAA, Ali GAM, Algarni H, Yin H, Zhong YL, Chong KF (2018) Magnetic electrodeposition of the hierarchical cobalt oxide nanostructure from spent lithium-ion batteries: its application as a supercapacitor electrode. J Phy Chem C 122(23):12200–12206CrossRef Aboelazm EAA, Ali GAM, Algarni H, Yin H, Zhong YL, Chong KF (2018) Magnetic electrodeposition of the hierarchical cobalt oxide nanostructure from spent lithium-ion batteries: its application as a supercapacitor electrode. J Phy Chem C 122(23):12200–12206CrossRef
7.
go back to reference Gu F, Guo J, Yao X, Summers PA, Widijatmoko SD, Hall P (2017) An investigation of the current status of recycling spent lithium-ion batteries from consumer electronics in China. J Clean Prod 161:765–780CrossRef Gu F, Guo J, Yao X, Summers PA, Widijatmoko SD, Hall P (2017) An investigation of the current status of recycling spent lithium-ion batteries from consumer electronics in China. J Clean Prod 161:765–780CrossRef
8.
go back to reference Rarotra S, Sahu S, Kumar P, Kim KH, Tsang YF, Kumar V, Kumar P, Srinivasan M, Veksha A, Lisak G (2020) Progress and challenges on battery waste management: a critical review. ChemistrySelect 5(20):6182–6193CrossRef Rarotra S, Sahu S, Kumar P, Kim KH, Tsang YF, Kumar V, Kumar P, Srinivasan M, Veksha A, Lisak G (2020) Progress and challenges on battery waste management: a critical review. ChemistrySelect 5(20):6182–6193CrossRef
9.
go back to reference Li L, Bian Y, Zhang X, Guan Y, Fan E, Wu F, Chen R (2018) Process for recycling mixed-cathode materials from spent lithium-ion batteries and kinetics of leaching. Waste Manag 71:362–371CrossRef Li L, Bian Y, Zhang X, Guan Y, Fan E, Wu F, Chen R (2018) Process for recycling mixed-cathode materials from spent lithium-ion batteries and kinetics of leaching. Waste Manag 71:362–371CrossRef
10.
go back to reference Ganter MJ, Landi BJ, Babbitt CW, Anctil A, Gaustad G (2014) Cathode refunctionalization as a lithium ion battery recycling alternative. J Power Sources 256:274–280CrossRef Ganter MJ, Landi BJ, Babbitt CW, Anctil A, Gaustad G (2014) Cathode refunctionalization as a lithium ion battery recycling alternative. J Power Sources 256:274–280CrossRef
11.
go back to reference Lee CK, Rhee K-I (2002) Preparation of LiCoO2 from spent lithium-ion batteries. J Power Sources 109(1):17–21CrossRef Lee CK, Rhee K-I (2002) Preparation of LiCoO2 from spent lithium-ion batteries. J Power Sources 109(1):17–21CrossRef
12.
go back to reference Ali GAM, Tan LL, Jose R, Yusoff MM, Chong KF (2014) Electrochemical performance studies of MnO2 nanoflowers recovered from spent battery. Mater Res Bull 60:5–9CrossRef Ali GAM, Tan LL, Jose R, Yusoff MM, Chong KF (2014) Electrochemical performance studies of MnO2 nanoflowers recovered from spent battery. Mater Res Bull 60:5–9CrossRef
13.
go back to reference Ali GAM, Yusoff MM, Shaaban ER, Chong KF (2017) High performance MnO2 nanoflower supercapacitor electrode by electrochemical recycling of spent batteries. Ceram Int 43:8440–8448CrossRef Ali GAM, Yusoff MM, Shaaban ER, Chong KF (2017) High performance MnO2 nanoflower supercapacitor electrode by electrochemical recycling of spent batteries. Ceram Int 43:8440–8448CrossRef
14.
go back to reference Aboelazm EAA, Ali GAM, Chong KF (2018) Cobalt oxide supercapacitor electrode recovered from spent lithium-ion battery. Chem Adv Mater 3:67–74 Aboelazm EAA, Ali GAM, Chong KF (2018) Cobalt oxide supercapacitor electrode recovered from spent lithium-ion battery. Chem Adv Mater 3:67–74
15.
go back to reference Ali GAM (2020) Recycled MnO2 nanoflowers and graphene nanosheets for low-cost and high performance asymmetric supercapacitor. J Electron Mater 49(9):5411–5421 Ali GAM (2020) Recycled MnO2 nanoflowers and graphene nanosheets for low-cost and high performance asymmetric supercapacitor. J Electron Mater 49(9):5411–5421
16.
go back to reference Ordoñez J, Gago EJ, Girard A (2016) Processes and technologies for the recycling and recovery of spent lithium-ion batteries. Renew Sustain Energy Rev 60:195–205CrossRef Ordoñez J, Gago EJ, Girard A (2016) Processes and technologies for the recycling and recovery of spent lithium-ion batteries. Renew Sustain Energy Rev 60:195–205CrossRef
17.
go back to reference Tian X, Gong Y, Wu Y, Agyeiwaa A, Zuo T (2014) Management of used lead acid battery in China: secondary lead industry progress, policies and problems. Resour Conserv Recycl 93:75–84CrossRef Tian X, Gong Y, Wu Y, Agyeiwaa A, Zuo T (2014) Management of used lead acid battery in China: secondary lead industry progress, policies and problems. Resour Conserv Recycl 93:75–84CrossRef
18.
go back to reference Das HT, Saravanya S, Elumalai P (2018) Disposed dry cells as sustainable source for generation of few layers of graphene and manganese oxide for solid-state symmetric and asymmetric supercapacitor applications. ChemistrySelect 3(46):13275–13283CrossRef Das HT, Saravanya S, Elumalai P (2018) Disposed dry cells as sustainable source for generation of few layers of graphene and manganese oxide for solid-state symmetric and asymmetric supercapacitor applications. ChemistrySelect 3(46):13275–13283CrossRef
19.
go back to reference Ali GAM, Yusoff MM, Algarni H, and Chong KF (2018) One-step electrosynthesis of MnO2/rGO nanocomposite and its enhanced electrochemical performance. Ceramics Int Ali GAM, Yusoff MM, Algarni H, and Chong KF (2018) One-step electrosynthesis of MnO2/rGO nanocomposite and its enhanced electrochemical performance. Ceramics Int
20.
go back to reference Zeng X, Li J, Singh N (2014) Recycling of spent lithium-ion battery: a critical review. Crit Rev Environ Sci Technol 44(10):1129–1165CrossRef Zeng X, Li J, Singh N (2014) Recycling of spent lithium-ion battery: a critical review. Crit Rev Environ Sci Technol 44(10):1129–1165CrossRef
21.
go back to reference Zubi G, Dufo-López R, Carvalho M, Pasaoglu G (2018) The lithium-ion battery: state of the art and future perspectives. Renew Sustain Energy Rev 89:292–308CrossRef Zubi G, Dufo-López R, Carvalho M, Pasaoglu G (2018) The lithium-ion battery: state of the art and future perspectives. Renew Sustain Energy Rev 89:292–308CrossRef
22.
go back to reference Winslow KM, Laux SJ, Townsend TG (2018) A review on the growing concern and potential management strategies of waste lithium-ion batteries. Resour Conserv Recycl 129:263–277CrossRef Winslow KM, Laux SJ, Townsend TG (2018) A review on the growing concern and potential management strategies of waste lithium-ion batteries. Resour Conserv Recycl 129:263–277CrossRef
23.
go back to reference Richa K, Babbitt CW, Gaustad G (2017) Eco-efficiency analysis of a lithium-ion battery waste hierarchy inspired by circular economy. J Ind Ecol 21(3):715–730CrossRef Richa K, Babbitt CW, Gaustad G (2017) Eco-efficiency analysis of a lithium-ion battery waste hierarchy inspired by circular economy. J Ind Ecol 21(3):715–730CrossRef
24.
go back to reference Godt J, Scheidig F, Grosse-Siestrup C, Esche V, Brandenburg P, Reich A, Groneberg DA (2006) The toxicity of cadmium and resulting hazards for human health. J Occup Med Toxicol 1(1):22CrossRef Godt J, Scheidig F, Grosse-Siestrup C, Esche V, Brandenburg P, Reich A, Groneberg DA (2006) The toxicity of cadmium and resulting hazards for human health. J Occup Med Toxicol 1(1):22CrossRef
25.
go back to reference Ku H, Jung Y, Jo M, Park S, Kim S, Yang D, Rhee K, An E-M, Sohn J, Kwon K (2016) Recycling of spent lithium-ion battery cathode materials by ammoniacal leaching. J Hazard Mater 313:138–146CrossRef Ku H, Jung Y, Jo M, Park S, Kim S, Yang D, Rhee K, An E-M, Sohn J, Kwon K (2016) Recycling of spent lithium-ion battery cathode materials by ammoniacal leaching. J Hazard Mater 313:138–146CrossRef
26.
go back to reference Mishra A, Mehta A, Basu S, Malode SJ, Shetti NP, Shukla SS, Nadagouda MN, Aminabhavi TM (2018) Electrode materials for lithium-ion batteries. Mater Sci Energy Technol 1(2):182–187 Mishra A, Mehta A, Basu S, Malode SJ, Shetti NP, Shukla SS, Nadagouda MN, Aminabhavi TM (2018) Electrode materials for lithium-ion batteries. Mater Sci Energy Technol 1(2):182–187
27.
go back to reference Li X, Liu J, Meng X, Tang Y, Banis MN, Yang J, Hu Y, Li R, Cai M, Sun X (2014) Significant impact on cathode performance of lithium-ion batteries by precisely controlled metal oxide nanocoatings via atomic layer deposition. J Power Sources 247:57–69CrossRef Li X, Liu J, Meng X, Tang Y, Banis MN, Yang J, Hu Y, Li R, Cai M, Sun X (2014) Significant impact on cathode performance of lithium-ion batteries by precisely controlled metal oxide nanocoatings via atomic layer deposition. J Power Sources 247:57–69CrossRef
28.
go back to reference Wiedemann AH, Goldin GM, Barnett SA, Zhu H, Kee RJ (2013) Effects of three-dimensional cathode microstructure on the performance of lithium-ion battery cathodes. Electrochim Acta 88:580–588CrossRef Wiedemann AH, Goldin GM, Barnett SA, Zhu H, Kee RJ (2013) Effects of three-dimensional cathode microstructure on the performance of lithium-ion battery cathodes. Electrochim Acta 88:580–588CrossRef
29.
go back to reference Uddin J, Bryantsev VS, Giordani V, Walker W, Chase GV, Addison D (2013) Lithium nitrate as regenerable SEI stabilizing agent for rechargeable Li/O2 batteries. J Phys Chem Lett 4(21):3760–3765CrossRef Uddin J, Bryantsev VS, Giordani V, Walker W, Chase GV, Addison D (2013) Lithium nitrate as regenerable SEI stabilizing agent for rechargeable Li/O2 batteries. J Phys Chem Lett 4(21):3760–3765CrossRef
30.
go back to reference Nagasubramanian A, Yu DYW, Hoster H, Srinivasan M (2014) Enhanced cycling stability of o-LiMnO2 cathode modified by lithium boron oxide coating for lithium-ion batteries. J Solid State Electrochem 18(7):1915–1922CrossRef Nagasubramanian A, Yu DYW, Hoster H, Srinivasan M (2014) Enhanced cycling stability of o-LiMnO2 cathode modified by lithium boron oxide coating for lithium-ion batteries. J Solid State Electrochem 18(7):1915–1922CrossRef
31.
go back to reference Hua AC-C, Syue BZ-W (2010) Charge and discharge characteristics of lead-acid battery and LiFePO4 battery. In: The 2010 international power electronics conference-ECCE ASIA. IEEE Hua AC-C, Syue BZ-W (2010) Charge and discharge characteristics of lead-acid battery and LiFePO4 battery. In: The 2010 international power electronics conference-ECCE ASIA. IEEE
32.
go back to reference Prasad KH, Vinoth S, Ratnakar A, Venkateswarlu M, Satyanarayana N (2016) Structural and electrical conductivity studies of spinel LiMn2O4 cathode films grown by RF sputtering. Mater Today Proc 3(10):4046–4051CrossRef Prasad KH, Vinoth S, Ratnakar A, Venkateswarlu M, Satyanarayana N (2016) Structural and electrical conductivity studies of spinel LiMn2O4 cathode films grown by RF sputtering. Mater Today Proc 3(10):4046–4051CrossRef
33.
go back to reference Prasad KH, Arumugama R, Srinadhu E, Satyanarayana N. AC conductivity and electric modulus studies of LiNi1/3Mn1/3Co1/3O2 cathode thin films grown by pulsed laser deposition technique Prasad KH, Arumugama R, Srinadhu E, Satyanarayana N. AC conductivity and electric modulus studies of LiNi1/3Mn1/3Co1/3O2 cathode thin films grown by pulsed laser deposition technique
34.
go back to reference Bankole OE, Gong C, Lei L (2013) Battery recycling technologies: recycling wastelithium ion batteries with the impact on the environment in-view. J Environ Ecol 4:14–28CrossRef Bankole OE, Gong C, Lei L (2013) Battery recycling technologies: recycling wastelithium ion batteries with the impact on the environment in-view. J Environ Ecol 4:14–28CrossRef
35.
go back to reference Lewandowski A, Świderska-Mocek A (2009) Ionic liquids as electrolytes for Li-ion batteries—an overview of electrochemical studies. J Power Sources 194(2):601–609CrossRef Lewandowski A, Świderska-Mocek A (2009) Ionic liquids as electrolytes for Li-ion batteries—an overview of electrochemical studies. J Power Sources 194(2):601–609CrossRef
36.
go back to reference Kato Y, Hori S, Saito T, Suzuki K, Hirayama M, Mitsui A, Yonemura M, Iba H, Kanno R (2016) High-power all-solid-state batteries using sulfide superionic conductors. Nat Energy 1(4):1–7CrossRef Kato Y, Hori S, Saito T, Suzuki K, Hirayama M, Mitsui A, Yonemura M, Iba H, Kanno R (2016) High-power all-solid-state batteries using sulfide superionic conductors. Nat Energy 1(4):1–7CrossRef
37.
go back to reference Fergus JW (2010) Recent developments in cathode materials for lithium ion batteries. J Power Sources 195(4):939–954CrossRef Fergus JW (2010) Recent developments in cathode materials for lithium ion batteries. J Power Sources 195(4):939–954CrossRef
38.
go back to reference Gonçalves MCA, Garcia EM, Taroco HA, Gorgulho HF, Melo JO, Silva RR, Souza AG (2015) Chemical recycling of cell phone Li-ion batteries: application in environmental remediation. Waste Manag 40:144–150CrossRef Gonçalves MCA, Garcia EM, Taroco HA, Gorgulho HF, Melo JO, Silva RR, Souza AG (2015) Chemical recycling of cell phone Li-ion batteries: application in environmental remediation. Waste Manag 40:144–150CrossRef
39.
go back to reference Richa K, Babbitt CW, Gaustad G, Wang X (2014) A future perspective on lithium-ion battery waste flows from electric vehicles. Resour Conserv Recycl 83:63–76CrossRef Richa K, Babbitt CW, Gaustad G, Wang X (2014) A future perspective on lithium-ion battery waste flows from electric vehicles. Resour Conserv Recycl 83:63–76CrossRef
40.
go back to reference Huang B, Pan Z, Su X, An L (2018) Recycling of lithium-ion batteries: recent advances and perspectives. J Power Sources 399:274–286CrossRef Huang B, Pan Z, Su X, An L (2018) Recycling of lithium-ion batteries: recent advances and perspectives. J Power Sources 399:274–286CrossRef
41.
go back to reference Scansetti G, Lamon S, Talarico S, Botta G, Spinelli P, Sulotto F, Fantoni F (1985) Urinary cobalt as a measure of exposure in the hard metal industry. Int Arch Occup Environ Health 57(1):19–26CrossRef Scansetti G, Lamon S, Talarico S, Botta G, Spinelli P, Sulotto F, Fantoni F (1985) Urinary cobalt as a measure of exposure in the hard metal industry. Int Arch Occup Environ Health 57(1):19–26CrossRef
42.
go back to reference Ahmad S, Khan MH, Khandker S, Sarwar A, Yasmin N, Faruquee M, Yasmin R (2014) Blood lead levels and health problems of lead acid battery workers in Bangladesh. Sci World J Ahmad S, Khan MH, Khandker S, Sarwar A, Yasmin N, Faruquee M, Yasmin R (2014) Blood lead levels and health problems of lead acid battery workers in Bangladesh. Sci World J
43.
go back to reference Gratz E, Sa Q, Apelian D, Wang Y (2014) A closed loop process for recycling spent lithium ion batteries. J Power Sources 262:255–262CrossRef Gratz E, Sa Q, Apelian D, Wang Y (2014) A closed loop process for recycling spent lithium ion batteries. J Power Sources 262:255–262CrossRef
44.
go back to reference Castillo S, Ansart F, Laberty-Robert C, Portal J (2002) Advances in the recovering of spent lithium battery compounds. J Power Sources 112(1):247–254CrossRef Castillo S, Ansart F, Laberty-Robert C, Portal J (2002) Advances in the recovering of spent lithium battery compounds. J Power Sources 112(1):247–254CrossRef
45.
go back to reference Zeng X, Li J, Shen B (2015) Novel approach to recover cobalt and lithium from spent lithium-ion battery using oxalic acid. J Hazard Mater 295:112–118CrossRef Zeng X, Li J, Shen B (2015) Novel approach to recover cobalt and lithium from spent lithium-ion battery using oxalic acid. J Hazard Mater 295:112–118CrossRef
46.
go back to reference Boyden A, Soo VK, Doolan M (2016) The environmental impacts of recycling portable lithium-ion batteries. Procedia Cirp 48:188–193CrossRef Boyden A, Soo VK, Doolan M (2016) The environmental impacts of recycling portable lithium-ion batteries. Procedia Cirp 48:188–193CrossRef
47.
go back to reference Li J, Wang G, Xu Z (2016) Environmentally-friendly oxygen-free roasting/wet magnetic separation technology for in situ recycling cobalt, lithium carbonate and graphite from spent LiCoO2/graphite lithium batteries. J Hazard Mater 302:97–104CrossRef Li J, Wang G, Xu Z (2016) Environmentally-friendly oxygen-free roasting/wet magnetic separation technology for in situ recycling cobalt, lithium carbonate and graphite from spent LiCoO2/graphite lithium batteries. J Hazard Mater 302:97–104CrossRef
48.
go back to reference Barbieri E, Lima E, Cantarino S, Lelis M, Freitas M (2014) Recycling of spent ion-lithium batteries as cobalt hydroxide, and cobalt oxide films formed under a conductive glass substrate, and their electrochemical properties. J Power Sources 269:158–163CrossRef Barbieri E, Lima E, Cantarino S, Lelis M, Freitas M (2014) Recycling of spent ion-lithium batteries as cobalt hydroxide, and cobalt oxide films formed under a conductive glass substrate, and their electrochemical properties. J Power Sources 269:158–163CrossRef
49.
go back to reference Dewulf J, Van der Vorst G, Denturck K, Van Langenhove H, Ghyoot W, Tytgat J, Vandeputte K (2010) Recycling rechargeable lithium ion batteries: critical analysis of natural resource savings. Resour Conserv Recycl 54(4):229–234CrossRef Dewulf J, Van der Vorst G, Denturck K, Van Langenhove H, Ghyoot W, Tytgat J, Vandeputte K (2010) Recycling rechargeable lithium ion batteries: critical analysis of natural resource savings. Resour Conserv Recycl 54(4):229–234CrossRef
50.
go back to reference Li L, Ge J, Chen R, Wu F, Chen S, Zhang X (2010) Environmental friendly leaching reagent for cobalt and lithium recovery from spent lithium-ion batteries. Waste Manag 30(12):2615–2621CrossRef Li L, Ge J, Chen R, Wu F, Chen S, Zhang X (2010) Environmental friendly leaching reagent for cobalt and lithium recovery from spent lithium-ion batteries. Waste Manag 30(12):2615–2621CrossRef
51.
go back to reference Freitas M, Garcia E (2007) Electrochemical recycling of cobalt from cathodes of spent lithium-ion batteries. J Power Sources 171(2):953–959CrossRef Freitas M, Garcia E (2007) Electrochemical recycling of cobalt from cathodes of spent lithium-ion batteries. J Power Sources 171(2):953–959CrossRef
52.
go back to reference Garcia EM, Tar HA, Matencio T, Domingues RZ, dos Santos JA, Ferreira RV, Lorenšon E, Lima DQ, de Freitas MB (2012) Electrochemical recycling of cobalt from spent cathodes of lithium-ion batteries: its application as supercapacitor. J Appl Electrochem 42(6):361–366CrossRef Garcia EM, Tar HA, Matencio T, Domingues RZ, dos Santos JA, Ferreira RV, Lorenšon E, Lima DQ, de Freitas MB (2012) Electrochemical recycling of cobalt from spent cathodes of lithium-ion batteries: its application as supercapacitor. J Appl Electrochem 42(6):361–366CrossRef
53.
go back to reference Rothermel S, Evertz M, Kasnatscheew J, Qi X, Grützke M, Winter M, Nowak S (2016) Graphite recycling from spent lithium-ion batteries. Chemsuschem 9(24):3473–3484CrossRef Rothermel S, Evertz M, Kasnatscheew J, Qi X, Grützke M, Winter M, Nowak S (2016) Graphite recycling from spent lithium-ion batteries. Chemsuschem 9(24):3473–3484CrossRef
54.
go back to reference He X, Peng X, Zhu Y, Lai C, Ducati C, Kumar RV (2015) Producing hierarchical porous carbon monoliths from hydrometallurgical recycling of spent lead acid battery for application in lithium ion batteries. Green Chem 17(9):4637–4646CrossRef He X, Peng X, Zhu Y, Lai C, Ducati C, Kumar RV (2015) Producing hierarchical porous carbon monoliths from hydrometallurgical recycling of spent lead acid battery for application in lithium ion batteries. Green Chem 17(9):4637–4646CrossRef
55.
go back to reference Chagnes A, Pospiech B (2013) A brief review on hydrometallurgical technologies for recycling spent lithium-ion batteries. J Chem Technol Biotechnol 88(7):1191–1199CrossRef Chagnes A, Pospiech B (2013) A brief review on hydrometallurgical technologies for recycling spent lithium-ion batteries. J Chem Technol Biotechnol 88(7):1191–1199CrossRef
56.
go back to reference Hannan MA, Hoque MM, Hussain A, Yusof Y, Ker PJ (2018) State-of-the-art and energy management system of lithium-ion batteries in electric vehicle applications: issues and recommendations. IEEE Access 6:19362–19378CrossRef Hannan MA, Hoque MM, Hussain A, Yusof Y, Ker PJ (2018) State-of-the-art and energy management system of lithium-ion batteries in electric vehicle applications: issues and recommendations. IEEE Access 6:19362–19378CrossRef
57.
go back to reference Li L, Chen R, Sun F, Wu F, Liu J (2011) Preparation of LiCoO2 films from spent lithium-ion batteries by a combined recycling process. Hydrometallurgy 108(3–4):220–225CrossRef Li L, Chen R, Sun F, Wu F, Liu J (2011) Preparation of LiCoO2 films from spent lithium-ion batteries by a combined recycling process. Hydrometallurgy 108(3–4):220–225CrossRef
58.
go back to reference Nie H, Xu L, Song D, Song J, Shi X, Wang X, Zhang L, Yuan Z (2015) LiCoO2: recycling from spent batteries and regeneration with solid state synthesis. Green Chem 17(2):1276–1280CrossRef Nie H, Xu L, Song D, Song J, Shi X, Wang X, Zhang L, Yuan Z (2015) LiCoO2: recycling from spent batteries and regeneration with solid state synthesis. Green Chem 17(2):1276–1280CrossRef
59.
go back to reference Li L, Bian Y, Zhang X, Xue Q, Fan E, Wu F, Chen R (2018) Economical recycling process for spent lithium-ion batteries and macro-and micro-scale mechanistic study. J Power Sources 377:70–79CrossRef Li L, Bian Y, Zhang X, Xue Q, Fan E, Wu F, Chen R (2018) Economical recycling process for spent lithium-ion batteries and macro-and micro-scale mechanistic study. J Power Sources 377:70–79CrossRef
60.
go back to reference Gaines L, Sullivan J, Burnham A, Belharouak I (2011) Life-cycle analysis of production and recycling of lithium ion batteries. Transp Res Rec 2252(1):57–65CrossRef Gaines L, Sullivan J, Burnham A, Belharouak I (2011) Life-cycle analysis of production and recycling of lithium ion batteries. Transp Res Rec 2252(1):57–65CrossRef
61.
go back to reference Huang K, Li J, Xu Z (2010) Characterization and recycling of cadmium from waste nickel–cadmium batteries. Waste Manag 30(11):2292–2298CrossRef Huang K, Li J, Xu Z (2010) Characterization and recycling of cadmium from waste nickel–cadmium batteries. Waste Manag 30(11):2292–2298CrossRef
62.
go back to reference Vassura I, Morselli L, Bernardi E, Passarini F (2009) Chemical characterisation of spent rechargeable batteries. Waste Manag 29(8):2332–2335CrossRef Vassura I, Morselli L, Bernardi E, Passarini F (2009) Chemical characterisation of spent rechargeable batteries. Waste Manag 29(8):2332–2335CrossRef
63.
go back to reference Freitas M, De Pietre M (2004) Electrochemical recycling of the zinc from spent Zn–MnO2 batteries. J Power Sources 128(2):343–349CrossRef Freitas M, De Pietre M (2004) Electrochemical recycling of the zinc from spent Zn–MnO2 batteries. J Power Sources 128(2):343–349CrossRef
64.
go back to reference Kim S, Kim J, Kim S, Lee J, Yoon J (2018) Electrochemical lithium recovery and organic pollutant removal from industrial wastewater of a battery recycling plant. Environ Sci Water Res Technol 4(2):175–182CrossRef Kim S, Kim J, Kim S, Lee J, Yoon J (2018) Electrochemical lithium recovery and organic pollutant removal from industrial wastewater of a battery recycling plant. Environ Sci Water Res Technol 4(2):175–182CrossRef
65.
go back to reference Fouad O, Farghaly F, Bahgat M (2007) A novel approach for synthesis of nanocrystalline γ-LiAlO2 from spent lithium-ion batteries. J Anal Appl Pyrol 78(1):65–69CrossRef Fouad O, Farghaly F, Bahgat M (2007) A novel approach for synthesis of nanocrystalline γ-LiAlO2 from spent lithium-ion batteries. J Anal Appl Pyrol 78(1):65–69CrossRef
66.
go back to reference Chen J, Li Q, Song J, Song D, Zhang L, Shi X (2016) Environmentally friendly recycling and effective repairing of cathode powders from spent LiFePO4 batteries. Green Chem 18(8):2500–2506CrossRef Chen J, Li Q, Song J, Song D, Zhang L, Shi X (2016) Environmentally friendly recycling and effective repairing of cathode powders from spent LiFePO4 batteries. Green Chem 18(8):2500–2506CrossRef
67.
go back to reference Renault S, Brandell D, Edström K (2014) Environmentally-friendly lithium recycling from a spent organic Li-ion battery. Chemsuschem 7(10):2859–2867CrossRef Renault S, Brandell D, Edström K (2014) Environmentally-friendly lithium recycling from a spent organic Li-ion battery. Chemsuschem 7(10):2859–2867CrossRef
68.
go back to reference Ciez RE, Whitacre J (2019) Examining different recycling processes for lithium-ion batteries. Nat Sustain 2(2):148–156CrossRef Ciez RE, Whitacre J (2019) Examining different recycling processes for lithium-ion batteries. Nat Sustain 2(2):148–156CrossRef
69.
go back to reference Poyraz AS, Huang J, Cheng S, Bock DC, Wu L, Zhu Y, Marschilok AC, Takeuchi KJ, Takeuchi ES (2016) Effective recycling of manganese oxide cathodes for lithium based batteries. Green Chem 18(11):3414–3421CrossRef Poyraz AS, Huang J, Cheng S, Bock DC, Wu L, Zhu Y, Marschilok AC, Takeuchi KJ, Takeuchi ES (2016) Effective recycling of manganese oxide cathodes for lithium based batteries. Green Chem 18(11):3414–3421CrossRef
70.
go back to reference Heelan J, Gratz E, Zheng Z, Wang Q, Chen M, Apelian D, Wang Y (2016) Current and prospective Li-ion battery recycling and recovery processes. JOM 68(10):2632–2638CrossRef Heelan J, Gratz E, Zheng Z, Wang Q, Chen M, Apelian D, Wang Y (2016) Current and prospective Li-ion battery recycling and recovery processes. JOM 68(10):2632–2638CrossRef
71.
go back to reference Pagnanelli F, Moscardini E, Altimari P, Atia TA, Toro L (2017) Leaching of electrodic powders from lithium ion batteries: optimization of operating conditions and effect of physical pretreatment for waste fraction retrieval. Waste Manag 60:706–715CrossRef Pagnanelli F, Moscardini E, Altimari P, Atia TA, Toro L (2017) Leaching of electrodic powders from lithium ion batteries: optimization of operating conditions and effect of physical pretreatment for waste fraction retrieval. Waste Manag 60:706–715CrossRef
72.
go back to reference Wang X, Gaustad G, Babbitt CW, Richa K (2014) Economies of scale for future lithium-ion battery recycling infrastructure. Resour Conserv Recycl 83:53–62CrossRef Wang X, Gaustad G, Babbitt CW, Richa K (2014) Economies of scale for future lithium-ion battery recycling infrastructure. Resour Conserv Recycl 83:53–62CrossRef
73.
go back to reference Zhang X, Xie Y, Cao H, Nawaz F, Zhang Y (2014) A novel process for recycling and resynthesizing LiNi1/3Co1/3Mn1/3O2 from the cathode scraps intended for lithium-ion batteries. Waste Manag 34(9):1715–1724CrossRef Zhang X, Xie Y, Cao H, Nawaz F, Zhang Y (2014) A novel process for recycling and resynthesizing LiNi1/3Co1/3Mn1/3O2 from the cathode scraps intended for lithium-ion batteries. Waste Manag 34(9):1715–1724CrossRef
74.
go back to reference Wang MM, Zhang CC, Zhang FS (2017) Recycling of spent lithium-ion battery with polyvinyl chloride by mechanochemical process. Waste Manag 67:232–239CrossRef Wang MM, Zhang CC, Zhang FS (2017) Recycling of spent lithium-ion battery with polyvinyl chloride by mechanochemical process. Waste Manag 67:232–239CrossRef
75.
go back to reference Xiao J, Li J, Xu Z (2017) Recycling metals from lithium ion battery by mechanical separation and vacuum metallurgy. J Hazard Mater 338:124–131CrossRef Xiao J, Li J, Xu Z (2017) Recycling metals from lithium ion battery by mechanical separation and vacuum metallurgy. J Hazard Mater 338:124–131CrossRef
76.
go back to reference Guan J, Li Y, Guo Y, Su R, Gao G, Song H, Yuan H, Liang B, Guo Z (2017) Mechanochemical process enhanced cobalt and lithium recycling from wasted lithium-ion batteries. ACS Sustain Chem Eng 5(1):1026–1032CrossRef Guan J, Li Y, Guo Y, Su R, Gao G, Song H, Yuan H, Liang B, Guo Z (2017) Mechanochemical process enhanced cobalt and lithium recycling from wasted lithium-ion batteries. ACS Sustain Chem Eng 5(1):1026–1032CrossRef
77.
go back to reference Yun L, Linh D, Shui L, Peng X, Garg A, Le MLP, Asghari S, Sandoval J (2018) Metallurgical and mechanical methods for recycling of lithium-ion battery pack for electric vehicles. Resour Conserv Recycl 136:198–208CrossRef Yun L, Linh D, Shui L, Peng X, Garg A, Le MLP, Asghari S, Sandoval J (2018) Metallurgical and mechanical methods for recycling of lithium-ion battery pack for electric vehicles. Resour Conserv Recycl 136:198–208CrossRef
78.
go back to reference Lupi C, Pasquali M, Dell’Era A (2005) Nickel and cobalt recycling from lithium-ion batteries by electrochemical processes. Waste Manag 25(2):215–220CrossRef Lupi C, Pasquali M, Dell’Era A (2005) Nickel and cobalt recycling from lithium-ion batteries by electrochemical processes. Waste Manag 25(2):215–220CrossRef
79.
go back to reference Granata G, Pagnanelli F, Moscardini E, Takacova Z, Havlik T, Toro L (2012) Simultaneous recycling of nickel metal hydride, lithium ion and primary lithium batteries: accomplishment of European guidelines by optimizing mechanical pre-treatment and solvent extraction operations. J Power Sources 212:205–211CrossRef Granata G, Pagnanelli F, Moscardini E, Takacova Z, Havlik T, Toro L (2012) Simultaneous recycling of nickel metal hydride, lithium ion and primary lithium batteries: accomplishment of European guidelines by optimizing mechanical pre-treatment and solvent extraction operations. J Power Sources 212:205–211CrossRef
80.
go back to reference Santana I, Moreira T, Lelis M, Freitas M (2017) Photocatalytic properties of Co3O4/LiCoO2 recycled from spent lithium-ion batteries using citric acid as leaching agent. Mater Chem Phys 190:38–44CrossRef Santana I, Moreira T, Lelis M, Freitas M (2017) Photocatalytic properties of Co3O4/LiCoO2 recycled from spent lithium-ion batteries using citric acid as leaching agent. Mater Chem Phys 190:38–44CrossRef
81.
go back to reference Nan J, Han D, Zuo X (2005) Recovery of metal values from spent lithium-ion batteries with chemical deposition and solvent extraction. J Power Sources 152:278–284CrossRef Nan J, Han D, Zuo X (2005) Recovery of metal values from spent lithium-ion batteries with chemical deposition and solvent extraction. J Power Sources 152:278–284CrossRef
82.
go back to reference Paulino JF, Busnardo NG, Afonso JC (2008) Recovery of valuable elements from spent Li-batteries. J Hazard Mater 150(3):843–849CrossRef Paulino JF, Busnardo NG, Afonso JC (2008) Recovery of valuable elements from spent Li-batteries. J Hazard Mater 150(3):843–849CrossRef
83.
go back to reference Schauerman CM, Ganter MJ, Gaustad G, Babbitt CW, Raffaelle RP, Landi BJ (2012) Recycling single-wall carbon nanotube anodes from lithium ion batteries. J Mater Chem 22(24):12008–12015CrossRef Schauerman CM, Ganter MJ, Gaustad G, Babbitt CW, Raffaelle RP, Landi BJ (2012) Recycling single-wall carbon nanotube anodes from lithium ion batteries. J Mater Chem 22(24):12008–12015CrossRef
84.
go back to reference Lain MJ (2001) Recycling of lithium ion cells and batteries. J Power Sources 97:736–738CrossRef Lain MJ (2001) Recycling of lithium ion cells and batteries. J Power Sources 97:736–738CrossRef
85.
go back to reference Zheng X, Gao W, Zhang X, He M, Lin X, Cao H, Zhang Y, Sun Z (2017) Spent lithium-ion battery recycling–reductive ammonia leaching of metals from cathode scrap by sodium sulphite. Waste Manag 60:680–688CrossRef Zheng X, Gao W, Zhang X, He M, Lin X, Cao H, Zhang Y, Sun Z (2017) Spent lithium-ion battery recycling–reductive ammonia leaching of metals from cathode scrap by sodium sulphite. Waste Manag 60:680–688CrossRef
86.
go back to reference Lee CK, Rhee K-I (2003) Reductive leaching of cathodic active materials from lithium ion battery wastes. Hydrometallurgy 68(1–3):5–10CrossRef Lee CK, Rhee K-I (2003) Reductive leaching of cathodic active materials from lithium ion battery wastes. Hydrometallurgy 68(1–3):5–10CrossRef
87.
go back to reference Hanisch C, Loellhoeffel T, Diekmann J, Markley KJ, Haselrieder W, Kwade A (2015) Recycling of lithium-ion batteries: a novel method to separate coating and foil of electrodes. J Clean Prod 108:301–311CrossRef Hanisch C, Loellhoeffel T, Diekmann J, Markley KJ, Haselrieder W, Kwade A (2015) Recycling of lithium-ion batteries: a novel method to separate coating and foil of electrodes. J Clean Prod 108:301–311CrossRef
88.
go back to reference Zhang X, Xue Q, Li L, Fan E, Wu F, Chen R (2016) Sustainable recycling and regeneration of cathode scraps from industrial production of lithium-ion batteries. ACS Sustain Chem Eng 4(12):7041–7049CrossRef Zhang X, Xue Q, Li L, Fan E, Wu F, Chen R (2016) Sustainable recycling and regeneration of cathode scraps from industrial production of lithium-ion batteries. ACS Sustain Chem Eng 4(12):7041–7049CrossRef
89.
go back to reference Zhang T, He Y, Ge L, Fu R, Zhang X, Huang Y (2013) Characteristics of wet and dry crushing methods in the recycling process of spent lithium-ion batteries. J Power Sources 240:766–771CrossRef Zhang T, He Y, Ge L, Fu R, Zhang X, Huang Y (2013) Characteristics of wet and dry crushing methods in the recycling process of spent lithium-ion batteries. J Power Sources 240:766–771CrossRef
90.
go back to reference Sun L, Qiu K (2012) Organic oxalate as leachant and precipitant for the recovery of valuable metals from spent lithium-ion batteries. Waste Manag 32(8):1575–1582CrossRef Sun L, Qiu K (2012) Organic oxalate as leachant and precipitant for the recovery of valuable metals from spent lithium-ion batteries. Waste Manag 32(8):1575–1582CrossRef
91.
go back to reference Jha MK, Kumari A, Jha AK, Kumar V, Hait J, Pandey BD (2013) Recovery of lithium and cobalt from waste lithium ion batteries of mobile phone. Waste Manag 33(9):1890–1897CrossRef Jha MK, Kumari A, Jha AK, Kumar V, Hait J, Pandey BD (2013) Recovery of lithium and cobalt from waste lithium ion batteries of mobile phone. Waste Manag 33(9):1890–1897CrossRef
92.
go back to reference Chen X, Chen Y, Zhou T, Liu D, Hu H, Fan S (2015) Hydrometallurgical recovery of metal values from sulfuric acid leaching liquor of spent lithium-ion batteries. Waste Manag 38:349–356CrossRef Chen X, Chen Y, Zhou T, Liu D, Hu H, Fan S (2015) Hydrometallurgical recovery of metal values from sulfuric acid leaching liquor of spent lithium-ion batteries. Waste Manag 38:349–356CrossRef
93.
go back to reference Pagnanelli F, Moscardini E, Altimari P, Atia TA, Toro L (2016) Cobalt products from real waste fractions of end of life lithium ion batteries. Waste Manag 51:214–221CrossRef Pagnanelli F, Moscardini E, Altimari P, Atia TA, Toro L (2016) Cobalt products from real waste fractions of end of life lithium ion batteries. Waste Manag 51:214–221CrossRef
94.
go back to reference Barik S, Prabaharan G, Kumar B (2016) An innovative approach to recover the metal values from spent lithium-ion batteries. Waste Manag 51:222–226CrossRef Barik S, Prabaharan G, Kumar B (2016) An innovative approach to recover the metal values from spent lithium-ion batteries. Waste Manag 51:222–226CrossRef
95.
go back to reference Nayaka GP, Pai KV, Manjanna J, Keny SJ (2016) Use of mild organic acid reagents to recover the Co and Li from spent Li-ion batteries. Waste Manag 51:234–238CrossRef Nayaka GP, Pai KV, Manjanna J, Keny SJ (2016) Use of mild organic acid reagents to recover the Co and Li from spent Li-ion batteries. Waste Manag 51:234–238CrossRef
96.
go back to reference Yang Y, Xu S, He Y (2017) Lithium recycling and cathode material regeneration from acid leach liquor of spent lithium-ion battery via facile co-extraction and co-precipitation processes. Waste Manag 64:219–227CrossRef Yang Y, Xu S, He Y (2017) Lithium recycling and cathode material regeneration from acid leach liquor of spent lithium-ion battery via facile co-extraction and co-precipitation processes. Waste Manag 64:219–227CrossRef
97.
go back to reference Li L, Ge J, Wu F, Chen R, Chen S, Wu B (2010) Recovery of cobalt and lithium from spent lithium ion batteries using organic citric acid as leachant. J Hazard Mater 176(1–3):288–293CrossRef Li L, Ge J, Wu F, Chen R, Chen S, Wu B (2010) Recovery of cobalt and lithium from spent lithium ion batteries using organic citric acid as leachant. J Hazard Mater 176(1–3):288–293CrossRef
98.
go back to reference Nayaka G, Pai K, Santhosh G, Manjanna J (2016) Recovery of cobalt as cobalt oxalate from spent lithium ion batteries by using glycine as leaching agent. J Environ Chem Eng 4(2):2378–2383CrossRef Nayaka G, Pai K, Santhosh G, Manjanna J (2016) Recovery of cobalt as cobalt oxalate from spent lithium ion batteries by using glycine as leaching agent. J Environ Chem Eng 4(2):2378–2383CrossRef
99.
go back to reference Nayl A, Elkhashab R, Badawy SM, El-Khateeb M (2017) Acid leaching of mixed spent Li-ion batteries. Arabian J Chem 10:S3632–S3639CrossRef Nayl A, Elkhashab R, Badawy SM, El-Khateeb M (2017) Acid leaching of mixed spent Li-ion batteries. Arabian J Chem 10:S3632–S3639CrossRef
100.
go back to reference Wang J, Chen M, Chen H, Luo T, Xu Z (2012) Leaching study of spent Li-ion batteries. Procedia Environ Sci 16:443–450CrossRef Wang J, Chen M, Chen H, Luo T, Xu Z (2012) Leaching study of spent Li-ion batteries. Procedia Environ Sci 16:443–450CrossRef
101.
go back to reference Sun L, Qiu K (2011) Vacuum pyrolysis and hydrometallurgical process for the recovery of valuable metals from spent lithium-ion batteries. J Hazard Mater 194:378–384CrossRef Sun L, Qiu K (2011) Vacuum pyrolysis and hydrometallurgical process for the recovery of valuable metals from spent lithium-ion batteries. J Hazard Mater 194:378–384CrossRef
102.
go back to reference Chen X, Ma H, Luo C, Zhou T (2017) Recovery of valuable metals from waste cathode materials of spent lithium-ion batteries using mild phosphoric acid. J Hazard Mater 326:77–86CrossRef Chen X, Ma H, Luo C, Zhou T (2017) Recovery of valuable metals from waste cathode materials of spent lithium-ion batteries using mild phosphoric acid. J Hazard Mater 326:77–86CrossRef
Metadata
Title
Cost-Effective Nanomaterials Fabricated by Recycling Spent Batteries
Authors
Himadri Tanaya Das
T. Elango Balaji
K. Mahendraprabhu
S. Vinoth
Copyright Year
2021
DOI
https://doi.org/10.1007/978-3-030-68031-2_6

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