Home / Publications / Kinetic aspects of operando studies: state-of-the-art and unexplored possibilities

Kinetic aspects of operando studies: state-of-the-art and unexplored possibilities

Anna Arkad'evna Kurokhtina 1
Anna Arkad'evna Kurokhtina
Elizaveta Vladimirovna Larina 1
Elizaveta Vladimirovna Larina
10.1016/j.mencom.2017.05.001
Published 2017-04-25
Focus articleVolume 27, Issue 3, 213-223
7
Share
Cite this
GOST
 | 
Cite this
GOST Copy
Schmidt A. F., Kurokhtina A. A., Larina E. V. Kinetic aspects of operando studies: state-of-the-art and unexplored possibilities // Mendeleev Communications. 2017. Vol. 27. No. 3. pp. 213-223.
GOST all authors (up to 50) Copy
Schmidt A. F., Kurokhtina A. A., Larina E. V. Kinetic aspects of operando studies: state-of-the-art and unexplored possibilities // Mendeleev Communications. 2017. Vol. 27. No. 3. pp. 213-223.
RIS
 | 
Cite this
RIS Copy
TY - JOUR
DO - 10.1016/j.mencom.2017.05.001
UR - https://mendcomm.colab.ws/publications/10.1016/j.mencom.2017.05.001
TI - Kinetic aspects of operando studies: state-of-the-art and unexplored possibilities
T2 - Mendeleev Communications
AU - Schmidt, Alexander Fedorovich
AU - Kurokhtina, Anna Arkad'evna
AU - Larina, Elizaveta Vladimirovna
PY - 2017
DA - 2017/04/25
PB - Mendeleev Communications
SP - 213-223
IS - 3
VL - 27
ER -
BibTex
 | 
Cite this
BibTex (up to 50 authors) Copy
@article{2017_Schmidt,
author = {Alexander Fedorovich Schmidt and Anna Arkad'evna Kurokhtina and Elizaveta Vladimirovna Larina},
title = {Kinetic aspects of operando studies: state-of-the-art and unexplored possibilities},
journal = {Mendeleev Communications},
year = {2017},
volume = {27},
publisher = {Mendeleev Communications},
month = {Apr},
url = {https://mendcomm.colab.ws/publications/10.1016/j.mencom.2017.05.001},
number = {3},
pages = {213--223},
doi = {10.1016/j.mencom.2017.05.001}
}
MLA
Cite this
MLA Copy
Schmidt, Alexander Fedorovich, et al. “Kinetic aspects of operando studies: state-of-the-art and unexplored possibilities.” Mendeleev Communications, vol. 27, no. 3, Apr. 2017, pp. 213-223. https://mendcomm.colab.ws/publications/10.1016/j.mencom.2017.05.001.
Views / Downloads
1 / 8

Abstract

Operando spectroscopy is one of the most effective tools for investigating catalytic systems, providing unique experimental data that has long been required for kinetic studies of catalytic reactions. However, the utilization of kinetic methods in operando studies is frequently not taken into account. To address this issue, this article provides a discussion of the current status, problems, and prospects of operando kinetic studies of complex catalytic reactions.

References

1.
10.1016/j.mencom.2017.05.001_bib0005
Temkin
Homogeneous Catalysis with Metal Complexes: Kinetic Aspects and Mechanisms, 2012
2.
10.1016/j.mencom.2017.05.001_bib0010
Eremin
Coord. Chem. Rev., 2017
3.
10.1016/j.mencom.2017.05.001_bib0015
Via
in EXAFS Spectroscopy: Techniques and Applications, 1981
4.
10.1016/j.mencom.2017.05.001_bib0020
Rowe
in Synchrotron Radiation Research, 1992
5.
Molecular structures of supported metal oxide catalysts under different environments
Bañares M.A., Wachs I.E.
Journal of Raman Spectroscopy, 2002
7.
In-situ UV-visible study of Pd nanocluster formation in solution
Gaikwad A.V., Rothenberg G.
Physical Chemistry Chemical Physics, 2006
8.
Ultraviolet–visible absorption spectra of the colloidal metallic elements
Creighton J.A., Eadon D.G.
Journal of the Chemical Society Faraday Transactions, 1991
9.
Pd3 cluster catalysis: Compelling evidence from in operando spectroscopic, kinetic, and density functional theory studies
Lv C., Cheng H., He W., Shah M.I., Xu C., Meng X., Jiao L., Wei S., Li J., Liu L., Li Y.
Nano Research, 2016
10.
Operando NMR spectroscopic analysis of proton transfer in heterogeneous photocatalytic reactions
Wang X.L., Liu W., Yu Y., Song Y., Fang W.Q., Wei D., Gong X., Yao Y., Yang H.G.
Nature Communications, 2016
13.
Insights into the physical chemistry of materials from advances in HAADF-STEM
Sohlberg K., Pennycook T.J., Zhou W., Pennycook S.J.
Physical Chemistry Chemical Physics, 2015
15.
Introduction to Special Issue on Operando and In Situ Studies of Catalysis
Jones C.W., Tao F.(., Garland M.V.
ACS Catalysis, 2012
16.
Operando IV
Sievers C., Bare S.R., Stavitski E.
Catalysis Today, 2013
20.
Visualization of oscillatory behaviour of Pt nanoparticles catalysing CO oxidation
Vendelbo S.B., Elkjær C.F., Falsig H., Puspitasari I., Dona P., Mele L., Morana B., Nelissen B.J., van Rijn R., Creemer J.F., Kooyman P.J., Helveg S.
Nature Materials, 2014
21.
In situ Transmission Electron Microscopy of catalyst sintering
DeLaRiva A.T., Hansen T.W., Challa S.R., Datye A.K.
Journal of Catalysis, 2013
22.
Operando magnetic resonance: monitoring the evolution of conversion and product distribution during the heterogeneous catalytic ethene oligomerisation reaction
Roberts S.T., Renshaw M.P., Lutecki M., McGregor J., Sederman A.J., Mantle M.D., Gladden L.F.
Chemical Communications, 2013
23.
Complex structural dynamics of nanocatalysts revealed in Operando conditions by correlated imaging and spectroscopy probes
Li Y., Zakharov D., Zhao S., Tappero R., Jung U., Elsen A., Baumann P., Nuzzo R.G., Stach E.A., Frenkel A.I.
Nature Communications, 2015
24.
Operando Characterization of Catalysts through use of a Portable Microreactor
Zhao S., Li Y., Stavitski E., Tappero R., Crowley S., Castaldi M.J., Zakharov D.N., Nuzzo R.G., Frenkel A.I., Stach E.A.
ChemCatChem, 2015
25.
Tracing Active Sites in Supported Ni Catalysts during Butene Oligomerization by Operando Spectroscopy under Pressure
Rabeah J., Radnik J., Briois V., Maschmeyer D., Stochniol G., Peitz S., Reeker H., La Fontaine C., Brückner A.
ACS Catalysis, 2016
26.
Transition-Metal-Free Suzuki-Type Coupling Reactions
Leadbeater N.E., Marco M.
Angewandte Chemie - International Edition, 2003
27.
A Reassessment of the Transition-Metal Free Suzuki-Type Coupling Methodology
Arvela R.K., Leadbeater N.E., Sangi M.S., Williams V.A., Granados P., Singer R.D.
Journal of Organic Chemistry, 2004
28.
Ligand-free Heck reactions using low Pd-loading
Reetz M.T., de Vries J.G.
Chemical Communications, 2004
29.
Trends and advances in Operando methodology
Urakawa A.
Current Opinion in Chemical Engineering, 2016
30.
An Operando View of the Nanoscale
Morris J.R., Russell J.N., Karwacki C.J.
Journal of Physical Chemistry Letters, 2015
31.
Belyakov P.A., Kadentsev V.I., Chizhov A.O., Kolotyrkina N.G., Shashkov A.S., Ananikov V.P.
Mendeleev Communications, 2010
32.
10.1016/j.mencom.2017.05.001_bib0160
Shmidt
Kinet. Catal., 1998
34.
Mechanistic and kinetic studies of palladium catalytic systems
Amatore C., Jutand A.
Journal of Organometallic Chemistry, 1999
36.
Homeopathic Ligand-Free Palladium as a Catalyst in the Heck Reaction. A Comparison with a Palladacycle
de Vries A.H., Mulders J.M., Mommers J.H., Henderickx H.J., de Vries J.G.
Organic Letters, 2003
38.
Alkane Transformations on Supported Platinum Catalysts
Bond G.C., Cunningham R.H.
Journal of Catalysis, 1997
40.
Direct arylation and heterogeneous catalysis; ever the twain shall meet
Cano R., Schmidt A.F., McGlacken G.P.
Chemical Science, 2015
41.
A Pt-Cluster-Based Heterogeneous Catalyst for Homogeneous Catalytic Reactions: X-ray Absorption Spectroscopy and Reaction Kinetic Studies of Their Activity and Stability against Leaching
Li Y., Liu J.H., Witham C.A., Huang W., Marcus M.A., Fakra S.C., Alayoglu P., Zhu Z., Thompson C.M., Arjun A., Lee K., Gross E., Toste F.D., Somorjai G.A.
Journal of the American Chemical Society, 2011
42.
In Situ IR and X-ray High Spatial-Resolution Microspectroscopy Measurements of Multistep Organic Transformation in Flow Microreactor Catalyzed by Au Nanoclusters
Gross E., Shu X., Alayoglu S., Bechtel H.A., Martin M.C., Toste F.D., Somorjai G.A.
Journal of the American Chemical Society, 2014
44.
Small Gold Clusters Formed in Solution Give Reaction Turnover Numbers of 10 7 at Room Temperature
Oliver-Meseguer J., Cabrero-Antonino J.R., Domínguez I., Leyva-Pérez A., Corma A.
Science, 2012
45.
Is it homogeneous or heterogeneous catalysis derived from [RhCp*Cl2]2? In operando XAFS, kinetic, and crucial kinetic poisoning evidence for subnanometer Rh4 cluster-based benzene hydrogenation catalysis.
Bayram E., Linehan J.C., Fulton J.L., Roberts J.A., Szymczak N.K., Smurthwaite T.D., Özkar S., Balasubramanian M., Finke R.G.
Journal of the American Chemical Society, 2011
46.
Evidence for the Surface-Catalyzed Suzuki-Miyaura Reaction over Palladium Nanoparticles: An Operando XAS Study
Ellis P., Fairlamb I. ., Hackett S. ., Wilson K., Lee A.
Angewandte Chemie - International Edition, 2010
47.
Surface catalysed Suzuki–Miyaura cross-coupling by Pd nanoparticles: an operando XAS study
Lee A.F., Ellis P.J., Fairlamb I.J., Wilson K.
Dalton Transactions, 2010
48.
Identification of the Active Species Generated from Supported Pd Catalysts in Heck Reactions: An in situ Quick Scanning EXAFS Investigation
Reimann S., Stötzel J., Frahm R., Kleist W., Grunwaldt J., Baiker A.
Journal of the American Chemical Society, 2011
51.
High-Pressure In Situ NMR Methods for the Study of Reaction Kinetics in Homogeneous Catalysis
Torres A., Molina Perez N., Overend G., Hodge N., Heaton B.T., Iggo J.A., Satherley J., Whyman R., Eastham G.R., Gobby D.
ACS Catalysis, 2012
57.
Ex Situ and Operando Studies on the Role of Copper in Cu-Promoted SiO2–MgO Catalysts for the Lebedev Ethanol-to-Butadiene Process
Angelici C., Meirer F., van der Eerden A.M., Schaink H.L., Goryachev A., Hofmann J.P., Hensen E.J., Weckhuysen B.M., Bruijnincx P.C.
ACS Catalysis, 2015
58.
Operando Attenuated Total Reflectance FTIR Spectroscopy: Studies on the Different Selectivity Observed in Benzyl Alcohol Oxidation
Villa A., Ferri D., Campisi S., Chan-Thaw C.E., Lu Y., Kröcher O., Prati L.
ChemCatChem, 2015
60.
10.1016/j.mencom.2017.05.001_bib0300
Mendes
Comput. Appl. Biosci., 1993
63.
State of palladium in ligandless catalytic systems for the Heck reaction of nonactivated bromobenzene
Schmidt A.F., Al-Halaiqa A., Smirnov V.V., Kurokhtina A.A.
Kinetics and Catalysis, 2008
66.
Heck reactions catalyzed by oxide-supported palladium – structure–activity relationships
Wagner M., Köhler K., Djakovitch L., Weinkauf S., Hagen V., Muhler M.
Topics in Catalysis, 2000
67.
Role of the base and endogenous anions in “ligand-free” catalytic systems for the Suzuki–Miyaura reaction
Kurokhtina A.A., Larina E.V., Yarosh E.V., Schmidt A.F.
Kinetics and Catalysis, 2016