1
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Zhuravlev D.
, Lisitsyn A.
, Gromov N.
, Medvedeva T.
, Ogorodnikova O.
, Svintsitskiy D.
, Stonkus O.
, Khairulin S.
, Podyacheva O.
Can the Direct Conversion of Biomass-Derived Formic Acid be Efficient for Hydrogen Generation?
Reaction Chemistry & Engineering. 2025.
DOI: 10.1039/d5re00157a
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2
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Gromov N.V.
, Medvedeva T.B.
, Lukoyanov I.A.
, Ogorodnikova O.L.
, Panchenko V.N.
, Parmon V.N.
, Timofeeva M.N.
Hydrolysis-Oxidation of Starch to Formic Acid in the Presence of Vanadium-Containing Molybdophosphoric Heteropoly Acid (H3+xPMo12-xVxO40): Effect of Acidity and Vanadium Content on the Yield of Formic Acid
Renewable Energy. 2024.
V.220. 119534
:1-12. DOI: 10.1016/j.renene.2023.119534
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3
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Perebeinos A.A.
, Mishchenko T.I.
, Gurovskii V.V.
, Medvedeva T.B.
, Yatsenko D.A.
, Gromov N.V.
Liquid Phase Peroxide Oxidation of Phenol in the Presence of Catalysts Based on Mixed Oxides of Transition Metals and Cellulose
Russian Journal of Applied Chemistry. 2024.
V.97. N5. P.486-499. DOI: 10.1134/S1070427224050021
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4
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Gromov N.V.
, Medvedeva T.B.
, Lukoyanov I.A.
, Panchenko V.N.
, Prikhod’ko S.A.
, Parmon V.N.
, Timofeeva M.N.
Hydrolysis-Oxidation of Cellulose to Formic Acid in the Presence of Micellar Vanadium-Containing Molybdophosphoric Heteropoly Acids
Results in Engineering. 2023.
V.17. 100913
:1-10. DOI: 10.1016/j.rineng.2023.100913
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РИНЦ
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5
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Korobova A.
, Gromov N.
, Medvedeva T.
, Lisitsyn A.
, Kibis L.
, Stonkus O.
, Sobolev V.
, Podyacheva O.
Ru Catalysts Supported on Bamboo-like N-Doped Carbon Nanotubes: Activity and Stability in Oxidizing and Reducing Environment
Materials. 2023.
V.16. N4. 1465
:1-19. DOI: 10.3390/ma16041465
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6
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Gromov N.V.
, Medvedeva T.B.
, Panchenko V.N.
, Taran O.P.
, Timofeeva M.N.
, Parmon V.N.
One-Pot Hydrolysis-Hydrogenation of Potato Starch to Sorbitol Using Bifunctional Catalyst Ru/Сs3HSiW12O40
Catalysis in Industry. 2023.
V.15. N1. P.87–98. DOI: 10.1134/S207005042301004X
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7
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Gromov N.V.
, Ogorodnikova O.L.
, Medvedeva T.B.
, Panchenko V.N.
, Yakovleva I.S.
, Isupova L.A.
, Timofeeva M.N.
, Taran O.P.
, Aymonier C.
, Parmon V.N.
Hydrolysis–Dehydration of Cellulose: Efficiency of NbZr Catalysts under Batch and Flow Conditions
Catalysts. 2023.
V.13. N9. 1298
:1-17. DOI: 10.3390/catal13091298
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8
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Gromov N.V.
, Medvedeva T.B.
, Lukoyanov I.A.
, Panchenko V.N.
, Timofeeva M.N.
, Taran O.P.
, Parmon V.N.
Formic Acid Production via One-Pot Hydrolysis-Oxidation of Starch over Quaternary Ammonium Salts of Vanadium-Containing Keggin-Type Heteropoly Acids
Catalysts. 2022.
V.12. N10. 1252
:1-13. DOI: 10.3390/catal12101252
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9
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Громов Н.В.
, Медведева Т.Б.
, Панченко В.Н.
, Таран О.П.
, Тимофеева М.Н.
, Пармон В.Н.
Одностадийный процесс гидролиза-восстановления картофельного крахмала в сорбит в присутствии бифункционального катализатора Ru/Cs3HSiW12O40
Катализ в промышленности. 2022.
Т.5. С.70-82. DOI: 10.18412/1816-0387-2022-5-70-82
РИНЦ
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10
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Gromov N.V.
, Medvedeva T.B.
, Rodikova Y.A.
, Timofeeva M.N.
, Panchenko V.N.
, Taran O.P.
, Kozhevnikov I.V.
, Parmon V.N.
One-Pot Synthesis of Sorbitol via Hydrolysis-Hydrogenation of Cellulose in the Presence of Ru-Containing Composites
Bioresource Technology. 2021.
V.319. 124122
:1-7. DOI: 10.1016/j.biortech.2020.124122
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11
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Kozlova E.A.
, Kurenkova A.Y.
, Gerasimov E.Y.
, Gromov N.V.
, Medvedeva T.B.
, Saraev A.A.
, Kaichev V.V.
Comparative Study of Photoreforming of Glycerol on Pt/TiO2 and CuOx/TiO2 Photocatalysts under UV Light
Materials Letters. 2021.
V.283. 128901
:1-13. DOI: 10.1016/j.matlet.2020.128901
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РИНЦ
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12
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Gromov N.V.
, Medvedeva T.B.
, Panchenko V.N.
, Timofeeva M.N.
, Parmon V.N.
Hydrolysis–Hydrogenation of Arabinogalactan Catalyzed by Ru/Cs3HSiW12O40
Catalysis in Industry. 2021.
V.13. N1. P.81-89. DOI: 10.1134/S2070050421010050
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13
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Gromov N.V.
, Medvedeva T.B.
, Taran O.P.
, Timofeeva M.N.
, Parmon V.N.
Hydrolysis of Cellulose in the Presence of Catalysts Based on Cesium Salts of Heteropoly Acids
Catalysis in Industry. 2021.
V.13. N1. P.73-80. DOI: 10.1134/S2070050421010049
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РИНЦ
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14
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Лукоянов И.А.
, Громов Н.В.
, Медведева Т.Б.
, Панченко В.Н.
, Тимофеева М.Н.
, Пармон В.Н.
, Jhung S.H.
Синтез эритрулозы из дигидроксиацетона и формальдегида в присутствии цеолитоподобных цинк-имидазолятных каркасов
Катализ в промышленности. 2021.
Т.21. №3. С.184-191. DOI: 10.18412/1816-0387-2021-1-3-184-191
РИНЦ
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15
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Kurenkova A.Y.
, Medvedeva T.B.
, Gromov N.V.
, Bukhtiyarov A.V.
, Gerasimov E.Y.
, Cherepanova S.V.
, Kozlova E.A.
Sustainable Hydrogen Production from Starch Aqueous Suspensions over a Cd0.7Zn0.3S-Based Photocatalyst
Catalysts. 2021.
V.11. N7. 870
:1-15. DOI: 10.3390/catal11070870
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РИНЦ
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16
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Lukoyanov I.A.
, Gromov N.V.
, Medvedeva T.B.
, Panchenko V.N.
, Timofeeva M.N.
, Parmon V.N.
, Jhung S.H.
Synthesis of Erythrulose from Dihydroxyacetone and Formaldehyde Using Zinc Zeolitic Imidazolate Frameworks
Catalysis in Industry. 2021.
V.13. N4. P.395–401. DOI: 10.1134/S2070050421040061
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17
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Medvedeva T.B.
, Ogorodnikova O.L.
, Yakovleva I.S.
, Isupova L.A.
, Taran O.P.
, Gromov N.V.
, Parmon V.N.
Impact of Design on the Activity of ZrO2 Catalysts in Cellulose Hydrolysis-Dehydration to Glucose and
5-Hydroxymethylfurfural
Catalysts. 2021.
V.11. N11. 1359
:1-14. DOI: 10.3390/catal11111359
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РИНЦ
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18
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Громов Н.В.
, Медведева Т.Б.
, Панченко В.Н.
, Тимофеева М.Н.
, Пармон В.Н.
Гидролиз-восстановление арабиногалактана в присутствии катализатора Ru/Cs3HSiW12O40
Катализ в промышленности. 2020.
Т.20. №4. С.303-312. DOI: 10.18412/1816-0387-2020-4-303-312RSCI
РИНЦ
CAPlus
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19
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Gromov N.V.
, Medvedeva T.B.
, Rodikova Y.A.
, Babushkin D.E.
, Panchenko V.N.
, Timofeeva M.N.
, Zhizhina E.G.
, Taran O.P.
, Parmon V.N.
One-Pot Synthesis of Formic Acid via Hydrolysis–Oxidation of Potato Starch in the Presence of Cesium Salts of Heteropoly Acid Catalysts
RSC Advances. 2020.
V.10. N48. P.28856-28864. DOI: 10.1039/d0ra05501H
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РИНЦ
CAPlusCA
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20
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Gromov N.V.
, Medvedeva T.B.
, Sorokina K.N.
, Samoylova Y.V.
, Rodikova Y.A.
, Parmon V.N.
Direct Conversion of Microalgae Biomass to Formic Acid under an Air Atmosphere with Soluble and Solid Mo-V-P Heteropoly Acid Catalysts
ACS Sustainable Chemistry & Engineering. 2020.
V.8. N51. P.18947-18956. DOI: 10.1021/acssuschemeng.0c06364
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РИНЦ
CAPlus
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