サイズW7.5cm×H4.35cm配置位置横11cm、縦2.5cmNNOPh2PCatalystRROHOHCatalystC6H5COCl, i -Pr2EtNRROCOC6H5OHUp to 94 % ee18214151617He678910CNOFNe1415161718SiPSClAr33343536AsSeBrKrDeveloping novel organocatalysts for highly stereoselective synthesis of organic molecules41Department of Chemistry and MaterialsOutlookforresearchOutlook for students after graduationOrganicmoleculessometimescomeinachiralformwithanenantiotopicrelationship.Iamcarryingoutresearchfocusedprimarilyonthedevelopmentofanasymmetricalcatalysttoselectivelysynthesizeonesideofachiralmolecule.Mygoalindoingsoistocreatenewcatalyststhatarehighlyselectiveandhighlyactivated,thatdonotuseraremetals,andthatcanbesynthesizedsimply.Expectedapplicationsincludethefunctionalizationofglycerin,atypeofbiomass,usingtheasymmetricesterificationreactionandtheeasysupplyofopticallyactivealcoholandamine,inadditiontothecarbon‐carbonbond‐formingreactionthatisimportantfororganicsynthesis.Graduates have gone to work for manufactures of low‐and high‐polymer products and pharmaceuticals.AssociateProfessorTetsuyaFujimotoAssociateProfessorFujimotofirstcompletedaShinshuUniversityGraduateSchoolofEngineeringresearchcoursespecializinginthestudyoffunctionalpolymers.Hisareaofresearchisorganicsyntheticchemistry,andhisworkfocusesonnewmethodsfororganicsynthesisandthedevelopmentofnewcatalysts.Aviewofthelab.Numerousreagents,solvents,andglasscontainersareusedtosynthesizethetargetorganiccompounds,yieldingsubstanceswhosestructurecanbeconfirmedusingNMR.Anasymmetricesterificationsolutiondesignedbasedonatomicprinciples,andassociatedreactions.Esterificationproceedsbydifferentiatingbetweenthetwosymmetricalhydroxylsinthediol.Realizing a sustainable society through the effective utilization of biomass resourcesDepartment of Chemistry and MaterialsOutlookforresearchOutlook for students after graduationVariousbiomassresourcessuchaslipid,wood,andmicroalgaehavepotentialassustainablealternativefuels.However,itisessentialtoimprovetheefficiencyofconversiontorealizetheenergyutilizationofbiomassresources.Ourlaboratoryaimstoefficientlyconvertbiomassresourcestohigh‐gradefuelsandchemicalrawmaterialsusinganinexpensiveprocess.Weareworkingontheelucidationofcatalyticreactionmechanismanddesignofnewcatalysttoachievethesegoals.Mygoalistohelpdevelopasocietypoweredbycleanandsustainableenergythatdoesnotrelyonexhaustibleresourcessuchasfossilfuels.Further,Ihopetodevelopmethodsforsynthesizingusefulsubstancesusingbiomasstoreplacethemanychemicalproductsthatarecurrentlysynthesizedfromoilresources.Chemicalengineeringcanbeusefulinvariousfieldsofmanufacturingincludingchemicals,energy,materials,plantengineeringandsoon.Inourlaboratory,wewanttoacquireknowledgeofchemicalreactionengineeringaswellaswearitthroughresearchonhowtoutilizetheknowledge.LecturerIoriSHIMADADr.IoriShimadagraduatedfromTheUniversityofTokyoandobtainedhisdoctorateinenvironmentalstudiesin2013.Hetookhiscurrentpositionin2018afterworkingasaresearchfellowattheJapanSocietyforthePromotionofScienceandanAssistantProfessoratFacultyofTextileScienceandTechnology,ShinshuUniversity.Hisspecialtyischemicalreactionengineering.Energy and material uses of biomass resources. Optimizing catalytic reactions is the key to practical application.Catalytic activity test reactorCatalysts and reaction products from microalgae. The products can be used as gasoline additive.
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