about
Expanding the world of endohedral fullerenes--the Tm3N@C2n (39< or =n< or =43) clusterfullerene family.Novel catalysts, room temperature, and the importance of oxygen for the synthesis of single-walled carbon nanotubes.Expanding the number of stable isomeric structures of the C80 cage: a new fullerene Dy3N@C80.Electrochemical doping of chirality-resolved carbon nanotubes.Rotating cell for in situ Raman spectroelectrochemical studies of photosensitive redox systems.Selective etching of thin single-walled carbon nanotubes.Modern thermoelectrochemistry.In situ Raman cell for high pressure and temperature studies of metal and complex hydrides.Gain of a 500-fold sensitivity on an intravital MR contrast agent based on an endohedral gadolinium-cluster-fullerene-conjugate: a new chance in cancer diagnosticsSynthesis, isolation, and spectroscopic characterization of holmium-based mixed-metal nitride clusterfullerenes: HoxSc3-xN@C80 (x=1, 2).Spectroelectrochemistry of carbon nanostructures.Endohedral clusterfullerenes--playing with cluster and cage sizes.Metal nitride cluster fullerenes: their current state and future prospects.Spectroelectrochemistry of carbon nanotubes.Gd-Sc-based mixed-metal nitride cluster fullerenes: mutual influence of the cage and cluster size and the role of scandium in the electronic structure.Growth of all-carbon horizontally aligned single-walled carbon nanotubes nucleated from fullerene-based structures.A platform for specific delivery of lanthanide-scandium mixed-metal cluster fullerenes into target cells.A facile route to metal nitride clusterfullerenes by using guanidinium salts: a selective organic solid as the nitrogen source.Sexithiophene encapsulated in a single-walled carbon nanotube: an in situ Raman spectroelectrochemical study of a peapod structure.Highly charged cations from N,N,N',N'-tetrakis(4-aminophenyl)benzidine and its N,N,N',N'-tetrakis(4-methoxyphenyl)-substituted homologue studied by thin-layer in situ electron spin resonance/UV-vis-NIR spectroelectrochemistry.Influence of phenazine structure on polaron formation in polyaniline: in situ electron spin resonance-ultraviolet/visible-near-infrared spectroelectrochemical study.In situ NMR spectroelectrochemistry of higher sensitivity by large scale electrodes.In situ ESR-UV-Vis-NIR spectroelectrochemical study of the p-doping of poly[2-(3-thienyl)ethyl acetate] and its hydrolyzed derivatives.Novel sodium aluminium borohydride containing the complex anion [Al(BH4,Cl)4]-.Marked stabilization of redox states and enhanced catalytic activity in galactose oxidase models based on transition metal S-methylisothiosemicarbazonates with -SR group in ortho position to the phenolic oxygen.In situ ESR/UV-vis-NIR and ATR-FTIR spectroelectrochemical studies on the p-doping of copolymers of 3-methylthiophene and 3-hexylthiophene.Carbon nanotube electrodes for hot-wire electrochemistry.Structural changes in 2-diarylthiophene-substituted starburst compounds upon charging: a theoretical and spectroelectrochemical study.The extended view on the empty C2(3)-C82 fullerene: isolation, spectroscopic, electrochemical, and spectroelectrochemical characterization and DFT calculations.In situ spectroelectrochemical studies on ladder-type oligomers in solution and the solid state.Spectroelectrochemistry of poly(ethylenedithiathiophene)--the sulfur analogue of poly(ethylenedioxythiophene).Pi-dimer of an aniline dimer: an ESR-UV-vis spectroelectrochemical study.Endohedral metal or a fullerene cage based oxidation? Redox duality of nitride clusterfullerenes Ce(x)M(3-x)N@C(78-88) (x = 1, 2; M = Sc and Y) dictated by the encaged metals and the carbon cage size.Thiophene-thiophene versus phenyl-phenyl coupling in 2-(Diphenylamino)-Thiophenes: an ESR-UV/Vis/NIR spectroelectrochemical study.C78 cage isomerism defined by trimetallic nitride cluster size: a computational and vibrational spectroscopic study.Gadolinium nitride Gd3N in carbon cages: the influence of cluster size and bond strength.Influence of the cage size on the dynamic behavior of fullerenes: a study of (13)c NMR spin-lattice relaxation.ESR-Vis/NIR spectroelectrochemical study of C70(CF3)2-(*) and C70(C2F5)2-(*) radical anions.Ionic liquid for in situ Vis/NIR and Raman spectroelectrochemistry: Doping of carbon nanostructures.Al3Li4(BH4)13: a complex double-cation borohydride with a new structure.
P50
Q30977783-15EEBE3A-7456-4F49-B9AF-0602E32712B4Q33223776-70F4D19B-2E89-4194-B27A-9B7FAC0EAF28Q33225158-2836B7FC-B413-45D2-884C-11E12371172FQ33250944-50F0CCC9-6D2F-48DA-820F-6BCC2119D879Q33405569-8342F05C-BC99-4C02-B5A2-8274B38D578BQ33421498-55DA12D9-1F3C-4BDF-B616-8F81FD2E6234Q33487273-4272B3E5-5AD8-40DF-ADB4-501B9FE03056Q33848278-0022D6E8-ACD1-48BB-8CA0-78A5EFFD753AQ33894429-0F6B4A09-D9A9-4FEB-B210-C035D3480E80Q34320869-A1E960D6-12B9-4630-80F4-94FDA46F42F9Q36809878-6C9D274A-C95E-407D-B1A3-B413FB2520BCQ36870948-B53A0236-7F6C-44E1-BD66-E30BD91ACB2BQ36893785-E9E02E56-E549-4EAC-9F8D-F739BA54EB1CQ37827839-43547354-EEF9-4C5B-A7C3-7502F74B4A64Q38087363-EC219679-81E0-4A64-AEE5-12C58AEFD9C8Q41839009-6C2102E3-1D73-458C-94A0-F5F7D4D15526Q41951086-942B1094-7849-4C46-AE2E-5CCA393CE649Q42880082-B9433DD0-A7CF-4842-9C2B-876EBA538D09Q42924299-0E45C5C4-453F-4F0B-A1E8-3DFEC97CC000Q43131727-A61AE3B7-202F-4F82-843F-803FA61F41B4Q43237948-E17CCA3F-FE4B-4421-9E3E-DE88A85B470BQ43242823-DF9D4A55-E853-4CCD-92BB-F41BC2B24C5AQ43265970-7A064D4A-7C97-4B64-B277-088B8389F3D4Q44653418-55AB5069-95AD-481A-BA69-9C9CC075C8C9Q45777184-EDA7CCD5-ACEA-47AB-8924-4B1D49BB0E21Q46134370-AFB57FAC-4963-4BE1-A469-73755F6F75F5Q46163841-9CDE3199-83FF-46D1-A9BA-02FD787D987CQ46227738-85AF2C93-E9CA-4A3E-AAD3-9D4EA6BF0E45Q46358175-1B4161A5-CCBF-4099-9E82-73AB397FA54EQ46908485-052905EE-0F0A-4600-B39F-15EE569921A5Q46939151-65B27177-E9FB-441A-A9B3-B90AF61B28E7Q46964515-4E26DB7E-8A94-43B1-822B-8B6AA65E11A4Q46965153-47898ECF-8145-4787-BD15-66156C30C8FEQ46978513-A2AFD2A8-D50C-46F8-9DA5-3D6B07BE93DAQ47295137-FEBC4365-DBF2-4B10-A19F-B935444B7B28Q47394057-962F1145-CFC4-4AB6-A45E-B1F6125675FEQ47432703-C2D61265-1572-469C-B319-C6D5B9B4BB09Q50460912-CC576D5C-5910-437C-9E72-F2A9712231FBQ50492457-916B48F9-AF40-46B3-BDC9-6DDA0661264CQ50785346-D3CC9C1C-DEBE-4035-855D-0A0FB6EC08A8
P50
description
Fachgebiete: Physikalische Chemie, Technische Chemie, Elektrochemie
@de
scheikundige
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name
Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
@fr
Lothar Dunsch
@it
Lothar Dunsch
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Lothar Dunsch
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Lothar Dunsch
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prefLabel
Lothar Dunsch
@ast
Lothar Dunsch
@de
Lothar Dunsch
@en
Lothar Dunsch
@es
Lothar Dunsch
@fr
Lothar Dunsch
@it
Lothar Dunsch
@nl
Lothar Dunsch
@pt
Lothar Dunsch
@sl
P1006
P1015
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0000 0001 1688 2093
P214
P227
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P31
P569
1948-02-14T00:00:00Z
P570
2013-11-28T00:00:00Z
P691
jx20090821042
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P7859
lccn-n79031186