GREEN SUSTAINABLE PROCESS FOR CHEMICAL AND ENVIRONMENTAL ENGINEERING AND SCIENCE GREEN SUSTAINABLE PROCESS FOR CHEMICAL AND ENVIRONMENTAL ENGINEERING AND SCIENCE Carbon Dioxide Capture and Utilization Editedby Inamuddin DepartmentofAppliedChemistry,ZakirHusainCollegeofEngineeringandTechnology,Facultyof EngineeringandTechnology,AligarhMuslimUniversity,Aligarh,UttarPradesh,India Tariq Altalhi DepartmentofChemistry,CollegeofScience,TaifUniversity,Taif,SaudiArabia Elsevier Radarweg29,POBox211,1000AEAmsterdam,Netherlands TheBoulevard,LangfordLane,Kidlington,OxfordOX51GB,UnitedKingdom 50HampshireStreet,5thFloor,Cambridge,MA02139,UnitedStates Copyright©2023ElsevierInc.Allrightsreserved. Nopartofthispublicationmaybereproducedortransmittedinanyformorbyanymeans,electronic ormechanical,includingphotocopying,recording,oranyinformationstorageandretrievalsystem, withoutpermissioninwritingfromthepublisher.Detailsonhowtoseekpermission,further informationaboutthePublisher’spermissionspoliciesandourarrangementswithorganizationssuch astheCopyrightClearanceCenterandtheCopyrightLicensingAgency,canbefoundatourwebsite: www.elsevier.com/permissions. Thisbookandtheindividualcontributionscontainedinitareprotectedundercopyrightbythe Publisher(otherthanasmaybenotedherein). Notices Knowledgeandbestpracticeinthisfieldareconstantlychanging.Asnewresearchandexperience broadenourunderstanding,changesinresearchmethods,professionalpractices,ormedicaltreatment maybecomenecessary. Practitionersandresearchersmustalwaysrelyontheirownexperienceandknowledgeinevaluating andusinganyinformation,methods,compounds,orexperimentsdescribedherein.Inusingsuch informationormethodstheyshouldbemindfuloftheirownsafetyandthesafetyofothers,including partiesforwhomtheyhaveaprofessionalresponsibility. Tothefullestextentofthelaw,neitherthePublishernortheauthors,contributors,oreditors,assume anyliabilityforanyinjuryand/ordamagetopersonsorpropertyasamatterofproductsliability, negligenceorotherwise,orfromanyuseoroperationofanymethods,products,instructions,orideas containedinthematerialherein. ISBN:978-0-323-99429-3 ForInformationonallElsevierpublicationsvisitourwebsiteat https://www.elsevier.com/books-and-journals Publisher:SusanDennis AcquisitionsEditor:AnitaKoch EditorialProjectManager:FranchezcaA.Cabural ProductionProjectManager:SwapnaSrinivasan CoverDesigner:ChristianJ.Bilbow TypesetbyAptara,NewDelhi,India Contents Contributors xi Acknowledgment 49 References 49 Chapter1 Carbondioxidecaptureandits utilizationtowardsefficientbiofuels Chapter3 Cookstovesforbiochar production 1 productionandcarboncapture 53 AbhinayThakur,andAshishKumar MashuraShammi,JulienWinter,Md.MahbubulIslam, BeautyAkter,andNazmulHasan 1.1 Introduction 1 3.1 Introduction 53 1.2 Utilizationofcapturedcarbondioxide 3.2 Cookstovesdesignedforbiochar forbiofuelproduction 5 production 54 1.3 Conclusionandfutureperspectives 13 3.3 Biocharproductionandclimate-change References 13 implications 62 3.4 Conclusion 64 Chapter2 Deepeutecticliquidsforcarbon References 65 capturingandfixation 17 ZainabLiaqat,SumiaAkram,HafizMuhammadAthar, Chapter4 Metalsupportinteractionfor andMuhammadMushtaq electrochemicalvalorizationofCO 69 2 2.1 Carbondioxideemissions 17 AbinayaStalinraja,andKeerthigaGopalram 2.2 Deepeutecticliquids 19 2.3 Typesofdeepeutecticliquids 19 4.1 Introduction 69 2.4 PreparationofDELs 20 4.2 MetalsupportsforECRofCO2 70 2.5 AuthenticationofDELs 21 4.3 Conclusion 80 2.6 DELbasedCO absorption 22 Acknowledgment 80 2 2.7 Carboncaptureefficiencyofvarious References 81 HBDs 24 Chapter5 Utilizationofcarbondioxideasa 2.8 CO absorptioninaqueoussolution 2 ofDELs 40 buildingblockinsynthesisofactive 2.9 CO2absorptioninternaryDELs 41 pharmaceuticalingredients 85 2.10 Ammonium-BasedDELs 42 MuhammadFaisal 2.11 PhosphoniumbasedDELs 44 2.12 AzolebasedDELs 44 5.1 Introduction 85 2.13 Bio-phenolderivedsuperbasebasedDELs 45 5.2 N–Nucleophile-triggered 2.14 HydrophobicDELs 45 CO -incorporatedcarboxylation 2 2.15 Non-ionicDELs 46 toformC–Nbonds 87 2.16 DELsupportedmembranes 46 5.3 N–Nucleophile-triggered 2.17 DELswithmultiplesitesinteraction 47 CO -incorporatedmethylation 2 2.18 Conclusionandfutureprospects 48 toformC–Nbonds 95 v vi Contents 5.4 O–Nucleophile-triggered Chapter8 Ionicliquidsaspotential CO2-incorporatedcarboxylation materialsforcarbondioxidecapture toformC–Obonds 96 andutilization 177 5.5 CO -catalyzedoxidationof 2 alcoholstoformC–Obonds 97 MdAbuShahynIslam,MohdArhamKhan,NimraShakeel, MohdImranAhamed,andNaushadAnwar 5.6 C-Nucleophile-triggered CO -incorporatedreductivecarboxylation 2 8.1 Introduction 178 toformC–Cbonds 97 8.2 TypesofILs 179 5.7 C-nucleophile-triggered 8.3 FutureapplicationsofILandGR-basedIL 191 CO -incorporateddirectC–Hcarboxylation 2 8.4 Conclusion 192 toformC–Cbond 99 References 193 5.8 C-nucleophile-triggeredCO -incorporated 2 organozinc-mediatedcarboxylationtoform C–Cbonds 101 Chapter9 Recentadvancesin 5.9 C-nucleophile-triggeredCO -incorporated 2 carbondioxideutilization organolithium-mediatedcarboxylation asrenewableenergy 197 toformaC–Cbond 102 5.10 C-Nucleophile-triggeredCO2-incorporated MuhammadHussnainSiddique,FareehaMaqbool,TanvirShahzad, organomagnesium-mediatedcarboxylation MuhammadWaseem,IjazRasul,SumreenHayat,MuhammadAfzal, MuhammadFaisal,andSaimaMuzammil toformaC–Cbond 108 5.11 Conclusion 111 9.1 Introduction 197 References 113 9.2 CO utilizationtechnologies 198 2 9.3 DevelopmentsinworldwideCO Chapter6 ElectrochemicalCarbonDioxide 2 utilizationprojects 204 Detection 119 9.4 Marketscaleandvalue 205 S.Aslan,C.I¸sık,andA.E.Mamuk 9.5 Regulationandpolicy 205 9.6 Conclusionandfutureprospects 206 6.1 Introduction 119 References 206 6.2 CapturetechnologiesofCO 121 2 6.3 Fundamentalsofelectrochemistry 126 6.4 Directpotentiometricmethods 128 Chapter10 MetalOrganicFrameworks 6.5 Summaryandconclusion 139 asanEfficientMethodforCarbon References 141 dioxidecapture 211 Chapter7 Carbondioxideinjectionfor BhartiKataria,andChristineJeyaseelan enhancedoilrecoveryandunderground 10.1 Introduction 211 storagetoreducegreenhousegas 149 10.2 Metalorganicframework(MOF) 212 ShubhamSaraf,andAchintaBera 10.3 SynthesisofsomeMOFS 215 10.4 PropertiesofMOFs 217 7.1 Introduction 149 10.5 CO captureusingMOF 217 7.2 OilrecoveryusingCO 156 2 2 10.6 Adsorptionofcarbondioxidein 7.3 Undergroundstorageof metalorganicframeworks 219 CO inunconventionalreservoirs 167 2 10.7 MethodstoenhanceCO adsorption 219 7.4 Currentstatus,challengesand 2 10.8 MethodstoenhanceMOF futuredirections 169 stability 222 7.5 Conclusions 170 10.9 Conclusion 227 Acknowledgment 172 References 227 References 172 vii Contents Chapter11 Industrialcarbondioxide 12.11 Conclusionandfutureinsights 291 captureandutilization 231 References 291 UzmaHira,AhmedKamal,andJaveriaTahir Chapter13 Advancesin 11.1 Introduction 231 utilizationofcarbon-dioxideforfood 11.2 CO collectionsystemsbasedonliquid 233 preservationandstorage 297 2 11.3 CO capturingwithionicliquidsolvents 242 2 AdeshinaFadeyibi 11.4 Applications,implementation andchallenges 244 13.1 Introduction 297 11.5 SolidCO2adsorbentsforlow-temperature 13.2 Utilizationofcarbon-dioxidein applications 245 foodpreservation 298 11.6 Carbonadsorbents 246 13.3 Utilizationofcarbon-dioxidein 11.7 Zeoliteadsorbents 248 foodstorage 302 11.8 AdsorbentsoftheMOF(metal–organic 13.4 Prospectsandconclusion 305 framework)type 250 References 305 11.9 Adsorbentspredicatedon carbonate-basedalkalis 252 Chapter14 Aninsightintotherecent 11.10 Layereddoublehydroxides (LDHs)-basedadsorbents 254 developmentsinmembrane-basedcarbon 11.11 Adsorbentsmadeofmagnesium dioxidecaptureandutilization 311 oxide(MgO) 255 PritamDey,PritamSingh,andMitaliSaha 11.12 SolidCO sorbentsfor 2 high-temperatureapplications 257 14.1 Introduction 311 11.13 Pre-combustionapplications, 14.2 Carbondioxidecapturetechnologies 312 implementationandproblems 260 14.3 Abriefaboutmembranetechnology 314 11.14 TheutilisationofCO2in 14.4 CO2separationusingmembranes 316 industrialprocesses 262 14.5 CO utilizationusingmembranes 321 2 11.15 Conclusionsandprospects 268 14.6 Conclusions 322 References 270 References 323 Chapter12 Ionicliquidsforcarbon Chapter15 Carbondioxidetofuelusing capturingandstorage 279 solarenergy 327 FaizanWaseemButt,HafizMuhammadAthar,SumiaAkram, SrijitaBasumallick ZainabLiaqat,andMuhammadMushtaq 15.1 Introduction 327 12.1 Introduction 279 15.2 CO reductionontosemiconductor 2 12.2 CO capturetechnologies 280 surface 327 2 12.3 Ionicliquids(ILs) 281 15.3 MajorbottleneckforCO reduction 328 2 12.4 FeaturesofILs 281 15.4 Differenttypesofphotocatalyst 329 12.5 ILasabsorbentsforCO capture 283 15.5 ReductionofCO tomethanol 2 2 12.6 ILhybridsasadsorbentsfor usingCu Oasphotocatalyst 330 2 CO capture 289 15.6 ReductionofCO tomethanolusing 2 2 12.7 ILhybridswithmembranesfor Cu Oaselectrocatalyst 330 2 CO capture 289 15.7 BenefitsofusingRGOinthe 2 12.8 Ionicliquidsupportedmembrane 290 compositecatalyst 331 12.9 PolyILsmembrane 290 15.8 Conclusions 333 12.10 Compositemembranes 290 viii Contents Acknowledgment 333 19.1 Introduction 441 References 333 19.2 CO application–Supercriticaldrying 442 2 19.3 StarchaerogelandCO utilization 445 2 Chapter16 Adsorbentsforcarbon 19.4 CelluloseaerogelsandCO utilization 447 2 capture 337 19.5 Conclusions 448 Authorcontributions 449 VijayVaishampayan,MukeshKumar,MuthamilselviPonnuchamy, Ethicalapproval 449 andAshishKapoor Declarationofcompetinginterest 449 16.1 Introduction 337 Acknowledgment 449 16.2 Carboncaptureprocesses 338 References 449 16.3 AdsorbentsforCO capture 338 2 16.4 Futureperspectiveandconclusion 342 Chapter20 Advancesincarbon References 342 bio-sequestration 451 NigelTwi-Yeboah,DacostaOsei,andMichaelK.Danquah Chapter17 Carbondioxidecaptureand utilizationinionicliquids 345 20.1 Introduction 451 20.2 Carbonsequestrationmethods 452 GuocaiTian 20.3 Limitationsofcarbonsequestration 17.1 Introduction 345 methods 453 17.2 CaptureofCO inILs 349 20.4 Overviewofbiologicalsequestration 2 17.3 ElectroreductionofCO inILs 391 (Cycle/Mechanism) 454 2 17.4 Conclusions 406 20.5 Bioresourcesforcarbon Acknowledgments 407 bio-sequestration 455 References 407 20.6 Cyanobacteria 456 20.7 Microalgae 457 Chapter18 Hydrothermalcarbonizationof 20.8 Plants 457 20.9 Bacteria 458 sewagesludgeforcarbonnegativeenergy 20.10 Nanomaterialsincarbonsequestration 458 production 427 20.11 Futureperspectives 459 MilanMalhotra,AnushaSathyanadh,andKhanh-QuangTran 20.12 Conclusion 459 References 460 18.1 Introduction 427 18.2 Sludgeasapotentialsourceof Chapter21 Photosyntheticcellfactories, alternateenergy 431 anewparadigmforcarbondioxide 18.3 Hydrothermal(HT)treatmentsforthe (CO )valorization 463 productionoffuel 432 2 18.4 Hydrothermalcarbonization+ BijayaNag,AbdalahMakaranga,MukulSureshKareya, gasification+ccs 437 AshaArumugamNesamma,andPannagaPavanJutur 18.5 Conclusion 437 21.1 Introduction 463 Acknowledgement 438 21.2 Carboncapture,utilizationand References 438 storagemechanism 465 21.3 Biologicalmechanismofcarboncapture 469 Chapter19 Utilizationofsupercritical 21.4 ProductsfromCCU 470 CO fordryingandproduction 2 21.5 Challengesandopportunities 472 ofstarchandcelluloseaerogels 441 21.6 Futureperspectivesandconclusions 475 JeieliWendelGasparLima,ClaraPrestesFerreira, Fundinginformation 476 JhonatasRodriguesBarbosa,andRaulNunesdeCarvalhoJunior References 476 ix Contents Chapter22 Carbondioxidecapture Chapter24 Carbondioxidecapture andsequestrationtechnologies– anditsenhancedutilization currentperspective,challenges usingmicroalgae 531 andprospects 481 PinkuChandraNath,BiswanathBhunia, andTarunKantiBandyopadhyay IfeanyiMichaelSmarteAnekwe,EmmanuelKweinorTetteh, StephenAkpasi,SamailaJoelAtuman, 24.1 Introduction 531 EdwardKwakuArmah,andYusufMakarfiIsa 24.2 PhotosynthesisandCO fixationusing 2 22.1 Introduction 481 microalgae 532 22.2 Carboncaptureandsequestration(CCS) 24.3 Cultivationsystemsforcarbondioxide technologies 484 capturebymicroalgae 533 22.3 CO transportation,storage 24.4 CO captureimprovementstrategies 541 2 2 andopportunities/applicationsfor 24.5 Conclusion 541 CCStechnologies 493 References 541 22.4 Currentperspectiveandpoliciesof CSStechnologiesinvariouscountries throughouttheworld 497 Chapter25 Supportedsingle-atom 22.5 Challengesandsocio-economic catalystsincarbondioxide implicationsofCCStechnologies 501 electrochemicalactivation 22.6 Applicationsandopportunities andreduction 547 forCCStechniques 504 22.7 Prospectsandfuturework AmosAfugu,CarolineR.Kwawu,ElliotMenkah,andEvansAdei considerationsforCCSapproaches 507 25.1 Introduction 547 22.8 Conclusion 508 25.2 CO ERRproducts 549 References 509 2 25.3 Single-Atomcatalystsefficiency descriptors 549 Chapter23 Microbialcarbon 25.4 Single-Atomcatalystsupports 551 dioxidefixationfortheproduction 25.5 MechanismsforCO ERRon 2 ofbiopolymers 517 single-atomcatalysts 554 TubaSaleem,IjazRasul,MuhammadAsif,andHabibullahNadeem 25.6 Conclusion 556 References 557 23.1 Introduction 517 23.2 SourcesofCO emission 519 2 23.3 SequestrationmethodsofCO 519 Chapter26 Organicmatterand 2 23.4 Carbonconcentratingmechanisms 520 mineralogicalacumensinCO 2 23.5 Advancementsincarboncaptureand sequestration 561 storage&carboncaptureutilization 521 23.6 Carbondioxidefixationpathways 521 SantanuGhosh,TusharAdsul,andAtulKumarVarma 23.7 Factorsaffectingthecarbondioxide 26.1 Overview 562 biofixation 527 26.2 Introduction 562 23.8 Productionofbiopolymers/bioplastics 527 26.3 Geo-sequestration 563 23.9 Conclusion 529 26.4 Bio-sequestration 563 References 529 x Contents 26.5 Mechanismsofcarboncapture 564 26.10 AnoteonCO disposalinbasalt 2 26.6 Transportofcarbondioxide 566 formations 587 26.7 Mechanismofcarbonaccommodation 566 26.11 Summary 587 26.8 Carbondioxidesequestration References 588 inorganicmatter 566 26.9 Mineralogicalacumenofcarbon Index 595 sequestration 573