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Poster - 34 Catalysis: Catalysis
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Presentations | |
ID: 1961
/ Poster - 34 Catalysis: 1
Poster session abstracts Poster Poster session abstracts ID: 1547
/ Poster - 34 Catalysis: 2
Materials and minerals Poster MS: Catalysis: functionalized materials studied by XRD and XAFS Posters only: Structure and phase transitions in advanced materials Keywords: cobalt molybdenum nitrides, ammonolysis, catalyst, XRPD in-situ In-situ XRPD analysis of active carbon supported Co-Mo ammonia synthesis catalysts activation West Pomeranian University of Technology in Szczecin, ul. Pułaskiego 10, Szczecin, Poland External Resource: https://www.xray.cz/iucrp/P_475
ID: 1545
/ Poster - 34 Catalysis: 3
Materials and minerals Poster MS: Catalysis: functionalized materials studied by XRD and XAFS Posters only: Structure and phase transitions in advanced materials, Crystallography in industry and applied sciences Keywords: Ammonia synthesis; wustite; XRPD in-situ; crystallite size Dependence of wustite based iron catalyst crystallite size on ammonia synthesis reaction analysed by in-situ XRPD West Pomeranian University of Technology in Szczecin, ul. Pułaskiego 10, Szczecin, Poland External Resource: https://www.xray.cz/iucrp/P_474
ID: 1544
/ Poster - 34 Catalysis: 4
Materials and minerals Poster MS: Catalysis: functionalized materials studied by XRD and XAFS Posters only: Structure and phase transitions in advanced materials Keywords: In-situ; XRPD; catalyst; cobalt molybdenum nitrides, pH How does precipitation pH affect structural transformations during activation of Co-Mo catalyst? In situ XPRD study West Pomeranian University of Technology in Szczecin, Pulaskiego 10, 70-322 Szczecin, Poland External Resource: https://www.xray.cz/iucrp/P_472
ID: 1543
/ Poster - 34 Catalysis: 5
Materials and minerals Poster MS: Catalysis: functionalized materials studied by XRD and XAFS Posters only: Structure and phase transitions in advanced materials Keywords: cobalt molybdenum nitrides, ammonolysis, XRPD in-situ In-situ XRPD study of ammonolysis of cobalt-molybdenum ammonia synthesis catalysts with defined Co to Mo ratio West Pomeranian University of Technology in Szczecin, ul. Pułaskiego 10, Szczecin, Poland External Resource: https://www.xray.cz/iucrp/P_471
ID: 565
/ Poster - 34 Catalysis: 6
Bursary application Poster MS: Catalysis: functionalized materials studied by XRD and XAFS Keywords: tungsten trioxide, tungstite, photocatalysis, sulfamethazine Immobilization of tungsten trioxide on the surface of mesoporous silica: structural investigation of the role of crystalline water on photocatalyst stability. Materials Nano-Materilas Unit, Energy Research Center, Mohammed V University in Rabat,Morocco Bibliography
I don't have a publication yet External Resource: https://www.xray.cz/iucrp/P_477
ID: 539
/ Poster - 34 Catalysis: 7
Materials and minerals Oral/poster MS: Catalysis: functionalized materials studied by XRD and XAFS Keywords: XANES, EXAFS, catalysis, palladium Detailed information about the core/shell/surface structure of palladium nanoparticles by combined in situ and operando X-ray absorption and diffraction data 1Southern Federal University, Rostov-on-Don, Russia; 2Southern Scientific Center, Russian Academy of Science, Rostov-on-Don, Russia; 3European Synchrotron Radiation Facility, Grenoble, France External Resource: https://www.xray.cz/iucrp/P_473
ID: 483
/ Poster - 34 Catalysis: 8
Bursary application Oral/poster MS: Materials for energy conversion and storage, Catalysis: functionalized materials studied by XRD and XAFS, Energy Materials Posters only: Methods, instrumentation (if it does not fit to any specific topics), General (if it does not fit to any specific topics nor areas) Keywords: palladium; nanoparticles; CO probing molecules; FTIR; adsorption; Evolution of Pd/CeO2 surface morphology in situ monitored by FTIR spectroscopy The Smart Materials Research Institute, Southern Federal University, 344090 Rostov-on-Don, Russia Bibliography
Publications 1.V. G. Vlasenko, A. A. Guda, A. G. Starikov, M. G. Chegerev, A. V. Piskunov, I. V. Ershova, A. L. Trigub, A. A. Tereshchenko, Y. V. Rusalev and S. P. Kubrin, Structural changes in five‐coordinate bromido‐bis (o‐iminobenzo‐semiquinonato) iron (III) complex: spin‐crossover or ligand‐metal antiferromagnetic interactions? Eur. J. Inorg. Chem. (2021) in press DOI: 10.1002/ejic.202001033 2.V. A. Polyakov, V. V. Butova, E. A. Erofeeva, A. A. Tereshchenko and A. V. Soldatov, MW Synthesis of ZIF-7. The Effect of Solvent on Particle Size and Hydrogen Sorption Properties. 13 Energies (2020) 6306. 3.Y. V. Rusalev, A. Tereshchenko, A. Guda and A. Soldatov, Theoretical Simulation of the Binding Energies and Stretching Frequencies of CO Molecules on PtSn Bimetallic Nanoparticles. 14 Journal of Surface Investigation: X-ray, Synchrotron and Neutron Techniques (2020) 440. 4.G. Smolentsev, C. J. Milne, A. Guda, K. Haldrup, J. Szlachetko, N. Azzaroli, C. Cirelli, G. Knopp, S. Menzi and G. Pamfilidis, Taking a snapshot of the triplet excited state of an OLED organometallic luminophore using X-rays. 11 Nat. Commun. (2020) 1. 5.Tereshchenko, A. Guda, V. Polyakov, Y. Rusalev, V. Butova and A. Soldatov, Pd nanoparticle growth monitored by DRIFT spectroscopy of adsorbed CO. Analyst 23 (2020) 7534. 6.Tereshchenko, V. Polyakov, A. Guda, A. Bulgakov, A. Tarasov, L. Kustov, V. Butova, A. Trigub and A. Soldatov, Synthesis and Description of Small Gold and Palladium Nanoparticles on CeO2 Substrate: FT-IR Spectroscopy Data. 14 Journal of Surface Investigation: X-ray, Synchrotron and Neutron Techniques (2020) 447. 7.O. A. Usoltsev, A. Y. Pnevskaya, E. G. Kamyshova, A. A. Tereshchenko, A. A. Skorynina, W. Zhang, T. Yao, A. L. Bugaev and A. V. Soldatov, Dehydrogenation of Ethylene on Supported Palladium Nanoparticles: A Double View from Metal and Hydrocarbon Sides. 10 Nanomaterials (2020) 1643. 8.Tereshchenko, V. Polyakov, A. Guda, T. Lastovina, Y. Pimonova, A. Bulgakov, A. Tarasov, L. Kustov, V. Butova and A. Trigub, Ultra-Small Pd Nanoparticles on Ceria as an Advanced Catalyst for CO Oxidation. 9 Catalysts (2019) 385. 9.Skorynina, A. Tereshchenko, O. Usoltsev, A. Bugaev, K. Lomachenko, A. Guda, E. Groppo, R. Pellegrini, C. Lamberti and A. Soldatov, Time-dependent carbide phase formation in palladium nanoparticles. Radiat. Phys. Chem. (2018) 10.M. Kirichkov, V. Polyakov, A. Tereshchenko, V. Shapovalov, A. Guda and A. Soldatov, Synthesis of Palladium Nanoparticles on the Surface of Cerium (IV) Oxide under the Action of Ultraviolet Radiation and Their Characterization. 14 Nanotechnologies in Russia (2019) 435. 11.L. Bugaev, V. A. Polyakov, A. A. Tereshchenko, A. N. Isaeva, A. A. Skorynina, E. G. Kamyshova, A. P. Budnyk, T. A. Lastovina and A. V. Soldatov, Chemical synthesis and characterization of Pd/SiO2: the effect of chemical reagent. 8 Metals (2018) 135. 12.P. V. Medvedev, M. A. Soldatov, V. V. e. Shapovalov, A. A. Tereshchenko, A. Fedorenko and A. Soldatov, Analysis of the Local Atomic Structure of the MIL-88а Metal–Organic Framework by Computer Simulation Using XANES Data. 108 JETP Letters (2018) 318. Patents 1.A.A. Tereshchenko, A.A. Guda, Yu.V. Rusalev, A.L. Bugaev, A.V. Soldatov, Method for determining oxygen storage capacity in oxide materials. RU 2708899 C1, application № 2019114145, 10.05.2019, published 12.12.2019 2.A.A. Skorynina, Yu.V. Rusalev, A.A. Guda, A.V. Soldatov, A.L. Bugaev, A.A. Tereshchenko, Cell for spectral diagnostics. RU 190702 U1, application № 2019112413, published 23.04.2019 3.A.A. Tereshchenko, A.A. Guda, A.P. Bydnyk, A.V. Soldatov, C. Lamberti, Cell for laboratory FTIR- and X-ray absorption spectral diagnostics. RU 180097 U1, application № 2017145634, 25.12.2017, published 04.06.2018 Conferences 1. A.A. Tereshchenko, A.A. Guda, V.A. Polyakov, A.V. Soldatov, In situ monitoring of Pd/CeO2 nanoparticles growth by means of FTIR spectroscopy // VI International scientific school-conference for young scientists Catalysis: from science to industry, October 6-10 2020, Tomsk, Russia, book of abstracts, p. 33. 2. A. Tereshchenko, V. Polyakov, A. Guda, L. Kustov, A. Tarasov, A. Trigub, A. Sodatov, Low-temperature catalysts based on ceria supported ultra-small Pd, Au and PdAu nanoparticles: synthesis and characterization // Emerging synchrotron techniques for characterization of energy materials and devices, September 23-25 2019, Grenoble, France, book of abstracts, p. 67 3. A. A. Tereshchenko, A. A. Guda, A. P. Budnyk, Palladium nanoparticles on different supports revealed by adsorption of probe molecules using infrared spectroscopy // International Workshop for Young Researchers «Smart Materials & Mega-Scale Research Facilities», April 23 2018, Rostov-on-Don, Russia, book of abstracts, p. 28 4.A. Bugaev, A. Skorynina, A. Tereshchenko, et al Surface-Core-Shall Structure of Palladium Nanoparticles // International Workshop for Young Researchers «Smart Materials & Mega-Scale Research Facilities», April 23, 2018, Rostov-on-Don, Russia, book of abstracts, p. 21. 5. A. A. Guda, O.V. Safonova, A.A. Tereshchenko et al, In situ characterization of ceria based nanocatalysts// Design of polyfunctional structures: theory and synthesis, October 23-36 2018, Rostov-on-Don, Russia, book of abstracts, p. 35 6. A. A. Tereshchenko, A. A. Guda, V A. Polyakov, The in situ FTIR study of the noble nanoparticles supported by ceria using CO probing molecules// Design of polyfunctional structures: theory and synthesis, October 23-36 2018, Rostov-on-Don, Russia, book of abstracts, p. 84 7. A. A. Tereshchenko, X-ray structural studies of the ferroelectric phase transition in thin strontium-barium niobate films // XXII Russian science conference of students physicists and young scientists, April, 21-28 2016, Taganrog, Russia, book of abstracts, p. 523 External Resource: https://www.xray.cz/iucrp/P_478
ID: 1562
/ Poster - 34 Catalysis: 9
Chemical crystallography, crystal structures Poster Posters only: Chemical crystallography, crystal structures (if it does not fit to any specific topics) Keywords: Spinel, crystal growth, MEM, neutron, synchrotron Crystal growth and structural studies of spinel ferrites Department of Chemistry & Interdisplinary Nanoscience Center (iNANO), Aarhus University, Denmark External Resource: https://www.xray.cz/iucrp/P_476
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