Publications
62.
Costabel,
Daniel;
Skabeev,
Artem;
Nabiyan,
Afshin;
Luo,
Yusen;
Max,
Johannes;
Rajagopal,
Ashwene;
Kowalczyk,
Daniel;
Dietzek,
Benjamin;
Wächtler,
Maria;
Görls,
Herlmar;
Ziegenbalg,
Dirk;
Zagranyarski,
Yulian;
Streb,
Carsten;
Schacher,
Felix H.;
Peneva,
Kalina
1,7,9,10-tetrasubstituted PMIs accessible via decarboxylative bromination: Synthesis, Characterization, Photophysical Studies and Hydrogen Evolution Catalysis
Herausgeber: Wiley
1,7,9,10-tetrasubstituted PMIs accessible via decarboxylative bromination: Synthesis, Characterization, Photophysical Studies and Hydrogen Evolution Catalysis
Herausgeber: Wiley
DOI: | 10.1002/chem.202004326 |
2020
61.
Straß-Eifert,
Angela;
Sheppard,
Thomas L.;
Damsgaard,
Christian D.;
Grunwaldt,
Jan-Dierk;
Güttel,
Robert
Stability of Cobalt Particles in and outside HZSM‐5 under CO Hydrogenation Conditions Studied by ex situ and in situ Electron Microscopy
ChemCatChem
Oktober 2020
Stability of Cobalt Particles in and outside HZSM‐5 under CO Hydrogenation Conditions Studied by ex situ and in situ Electron Microscopy
ChemCatChem
Oktober 2020
DOI: | 10.1002/cctc.202001533 |
60.
Brandt,
Anja;
Gómez-Nieto,
Beatriz;
Friedland,
Jens;
Güttel,
Robert;
Leopold,
Kerstin
Determination of activation energies for atomization of gold nanoparticles in graphite furnace atomic absorption spectrometry
Spectrochimica Acta Part B: Atomic Spectroscopy, 173 :105976
09 2020
Determination of activation energies for atomization of gold nanoparticles in graphite furnace atomic absorption spectrometry
Spectrochimica Acta Part B: Atomic Spectroscopy, 173 :105976
09 2020
DOI: | 10.1016/j.sab.2020.105976 |
59.
Kirchner,
Johann;
Zambrzycki,
Christian;
Baysal,
Zeynep;
Güttel,
Robert;
Kureti,
Sven
Fe based core-shell model catalysts for the reaction of CO2 with H2
Reaction Kinetics, Mechanisms, and Catalysis, 131 :119-128
09 2020
Fe based core-shell model catalysts for the reaction of CO2 with H2
Reaction Kinetics, Mechanisms, and Catalysis, 131 :119-128
09 2020
DOI: | 10.1007/s11144-020-01859-9 |
58.
Friedland,
Jens;
Kreitz,
Bjarne;
Grimm,
Heiner;
Turek,
Thomas;
Güttel,
Robert
Measuring Adsorption Capacity of Supported Catalysts with a Novel Quasi-Continuous Pulse Chemisorption Method
ChemCatChem, 12 :4373-4386
09 2020
Measuring Adsorption Capacity of Supported Catalysts with a Novel Quasi-Continuous Pulse Chemisorption Method
ChemCatChem, 12 :4373-4386
09 2020
DOI: | 10.1002/cctc.202000278 |
57.
Sánchez,
Agustina;
Milt,
Viviana G.;
Miró,
Eduardo E.;
Güttel,
Robert
Ceramic fiber-based structures as catalyst supports: a study on mass and heat transport behavior applied to CO2 methanation
Industrial & Engineering Chemistry Research, 59 :16539-16552
08 2020
Ceramic fiber-based structures as catalyst supports: a study on mass and heat transport behavior applied to CO2 methanation
Industrial & Engineering Chemistry Research, 59 :16539-16552
08 2020
DOI: | 10.1021/acs.iecr.0c01997 |
56.
Meyer,
Dominik;
Schumacher,
Jannik;
Friedland,
Jens;
Güttel,
Robert
Hydrogenation of CO/CO2 Mixtures on Nickel Catalysts: Kinetics and Flexibility for Nickel Catalysts
Industrial & Engineering Chemistry Research, 59 :14668-14678
07 2020
Hydrogenation of CO/CO2 Mixtures on Nickel Catalysts: Kinetics and Flexibility for Nickel Catalysts
Industrial & Engineering Chemistry Research, 59 :14668-14678
07 2020
DOI: | 10.1021/acs.iecr.0c02072 |
55.
Freund,
Hannsjörg;
Güttel,
Robert;
Horn,
Raimund;
Krewer,
Ulrike;
Sauer,
Jörg
Technische Chemie
Nachrichten aus der Chemie, 68 :46-53
06 2020
Technische Chemie
Nachrichten aus der Chemie, 68 :46-53
06 2020
DOI: | 10.1002/nadc.20204097163 |
54.
Kirchner,
Johann;
Zambrzycki,
Christian;
Kureti,
Sven;
Güttel,
Robert
CO2 Methanation on Fe Catalysts Using Different Structural Concepts
Chemie Ingenieur Technik, 92 :603-607
05 2020
CO2 Methanation on Fe Catalysts Using Different Structural Concepts
Chemie Ingenieur Technik, 92 :603-607
05 2020
DOI: | 10.1002/cite.201900157 |
53.
Theurich,
Steffi;
Rönsch,
Stefan;
Güttel,
Robert
Transient Flow Rate Ramps for Methanation of Carbon Dioxide in an Adiabatic Fixed‐Bed Recycle Reactor
Energy Technology, 8 :1901116
03 2020
Transient Flow Rate Ramps for Methanation of Carbon Dioxide in an Adiabatic Fixed‐Bed Recycle Reactor
Energy Technology, 8 :1901116
03 2020
DOI: | 10.1002/ente.201901116 |
52.
51.
Misra,
Archismita;
Zambrzycki,
Christian;
Kloker,
Gabriele;
Kotryba,
Anika;
Anjass,
Montaha H.;
Franco Castillo,
Isabel;
Mitchell,
Scott G.;
Güttel,
Robert;
Streb,
Carsten
Water Purification and Microplastics Removal using Magnetic Polyoxometalate-Supported Ionic Liquid Phases (MagPOM-SILPs)
Angewandte Chemie, 132 :1618-1622
01 2020
Water Purification and Microplastics Removal using Magnetic Polyoxometalate-Supported Ionic Liquid Phases (MagPOM-SILPs)
Angewandte Chemie, 132 :1618-1622
01 2020
DOI: | 10.1002/ange.201912111 |
50.
Misra,
Archismita;
Zambrzycki,
Christian;
Kloker,
Gabriele;
Kotryba,
Anika;
Anjass,
Montaha H.;
Franco Castillo,
Isabel;
Mitchell,
Scott G.;
Güttel,
Robert;
Streb,
Carsten
Water Purification and Microplastics Removal using Magnetic Polyoxometalate-Supported Ionic Liquid Phases (MagPOM-SILPs)
Angewandte Chemie International Edition, 59 :1601-1605
01 2020
Water Purification and Microplastics Removal using Magnetic Polyoxometalate-Supported Ionic Liquid Phases (MagPOM-SILPs)
Angewandte Chemie International Edition, 59 :1601-1605
01 2020
DOI: | 10.1002/anie.201912111 |
49.
Tastan,
Ümit;
Ziegenbalg,
Dirk
Photochlorination of Toluene - The Thin Line Between Intensification and Selectivity. Part 1: Intensification and Effect of Operation Conditions
Reaction Chemistry & Engineering
2020
Herausgeber: Royal Society of Chemistry (RSC)
Photochlorination of Toluene - The Thin Line Between Intensification and Selectivity. Part 1: Intensification and Effect of Operation Conditions
Reaction Chemistry & Engineering
2020
Herausgeber: Royal Society of Chemistry (RSC)
DOI: | 10.1039/d0re00263a |
48.
Tastan,
Ümit;
Seeber,
Phillip;
Kupfer,
Stephan;
Ziegenbalg,
Dirk
Photochlorination of Toluene - The Thin Line Between Intensification and Selectivity. Part 2: Selectivity
Reaction Chemistry & Engineering
2020
Herausgeber: Royal Society of Chemistry (RSC)
Photochlorination of Toluene - The Thin Line Between Intensification and Selectivity. Part 2: Selectivity
Reaction Chemistry & Engineering
2020
Herausgeber: Royal Society of Chemistry (RSC)
DOI: | 10.1039/d0re00366b |
47.
Wriedt,
Benjamin;
Ziegenbalg,
Dirk
Common pitfalls in chemical actinometry
Journal of Flow Chemistry, 10 (1) :295--306
2020
Herausgeber: Springer Science and Business Media LLC
Common pitfalls in chemical actinometry
Journal of Flow Chemistry, 10 (1) :295--306
2020
Herausgeber: Springer Science and Business Media LLC
DOI: | 10.1007/s41981-019-00072-7 |
46.
Yoon,
Songhak;
Nikoee,
Sheler;
Ranjbar,
Maryam;
Ziegenbalg,
Dirk;
Widenmeyer,
Marc;
Weidenkaff,
Anke
Strongly affected photocatalytic CO2 reduction by CO2 adsorbed to the surface of Ba2(In1.8Cr0.2)O5(H2O) powders
Solid State Sciences, 105 :106212
2020
Herausgeber: Elsevier BV
Strongly affected photocatalytic CO2 reduction by CO2 adsorbed to the surface of Ba2(In1.8Cr0.2)O5(H2O) powders
Solid State Sciences, 105 :106212
2020
Herausgeber: Elsevier BV
DOI: | 10.1016/j.solidstatesciences.2020.106212 |
2019
45.
Ilsemann,
Jan;
Straß-Eifert,
Angela;
Friedland,
Jens;
Kiewidt,
Lars;
Thöming,
Jorg;
Bäumer,
Marcus;
Güttel,
Robert
Cobalt@Silica Core‐Shell Catalysts for Hydrogenation of CO/CO2 Mixtures to Methane
ChemCatChem, 19 :4884-4893
Juli 2019
Cobalt@Silica Core‐Shell Catalysts for Hydrogenation of CO/CO2 Mixtures to Methane
ChemCatChem, 19 :4884-4893
Juli 2019
DOI: | 10.1002/cctc.201900916 |
44.
Neukäufer,
Johannes;
Hanusch,
Florian;
Kutscherauer,
Martin;
Rehfeldt,
Sebastian;
Klein,
Harald;
Grützner,
Thomas
Methodology for the Development of Additively Manufactured Packings in Thermal Separation Technology
Chemical Engineering & Technology
Juni 2019
Methodology for the Development of Additively Manufactured Packings in Thermal Separation Technology
Chemical Engineering & Technology
Juni 2019
DOI: | 10.1002/ceat.201900220 |
43.
Preißinger,
Ulrich;
Ränger,
Lena-Marie;
Grützner,
Thomas
Design Considerations of a Simplified Multiple DividingWall Column Pilot Plant
chemengineering, 3 (2) :34
April 2019
Design Considerations of a Simplified Multiple DividingWall Column Pilot Plant
chemengineering, 3 (2) :34
April 2019
DOI: | 10.3390/chemengineering3020034 |
42.
Grützner,
Thomas;
Ränger,
Lena-Marie;
Preißinger,
Ulrich
Multiple Dividing‐Wall Columns – Current Status and Future Prospects
Chemie Ingenieur Technik, 91 (4) :420-428
April 2019
Multiple Dividing‐Wall Columns – Current Status and Future Prospects
Chemie Ingenieur Technik, 91 (4) :420-428
April 2019
DOI: | 10.1002/cite.201800080 |
41.
Becker,
Henning;
Güttel,
Robert;
Thomas,
Thomas Turek
Performance of diffusion-optimised Fischer-Tropsch catalyst layers in microchannel reactors at integral operation
Catalysis Science & Technology, 9 :2180-2195
April 2019
Performance of diffusion-optimised Fischer-Tropsch catalyst layers in microchannel reactors at integral operation
Catalysis Science & Technology, 9 :2180-2195
April 2019
DOI: | 10.1039/C9CY00457B |
40.
Schlathauer,
Maria;
Friedland,
Jens;
Lindén,
Mika;
Leopold,
Kerstin
Sustainable and reagent-free mercury trace determination in natural waters using nanogold dipsticks
Microchemical Journal (147) :252-262
März 2019
Sustainable and reagent-free mercury trace determination in natural waters using nanogold dipsticks
Microchemical Journal (147) :252-262
März 2019
DOI: | 10.1016/j.microc.2019.03.032 |
39.
Neukäufer,
Johannes;
Hanusch,
Florian;
Kutscherauer,
Martin;
Rehfeldt,
Sebastian;
Klein,
Harald;
Grützner,
Thomas
Methodik zur Entwicklung additiv gefertigter Packungsstrukturen im Bereich der thermischen Trenntechnik
Chemie Ingenieur Technik, 91 (7) :1014 - 1023
März 2019
Methodik zur Entwicklung additiv gefertigter Packungsstrukturen im Bereich der thermischen Trenntechnik
Chemie Ingenieur Technik, 91 (7) :1014 - 1023
März 2019
DOI: | 10.1002/cite.201800171 |
38.
Kreitz,
Bjarne;
Friedland,
Jens;
Güttel,
Robert;
Wehinger,
Gregor D.;
Turek,
Thomas
Dynamic Methanation of CO<sub>2</sub> – Effect of Concentration Forcing
Chemie Ingenieur Technik, 91 (5) :576-582
März 2019
Dynamic Methanation of CO<sub>2</sub> – Effect of Concentration Forcing
Chemie Ingenieur Technik, 91 (5) :576-582
März 2019
DOI: | 10.1002/cite.201800191 |