PUB20240118 18 января 2024 г. 
Topological Analysis and Structural Role of Silicon Motifs in Metal Silicides.

Inna V. Medrish, Maria A. Solodovnikova, Artem A. Kabanov, and Vladislav A. Blatov Topological Analysis and Structural Role of Silicon Motifs in Metal Silicides. Crystal Growth & Design, 2024, 24 (3), 1308–1318. doi: 10.1021/acs.cgd.3c01282 IF 3.8

 
PUB20230224 24 февраля 2023 г. 
Boron Substructures in Inorganic Borides: Network Topology and Free Space.

Inna V. Medrish and Vladislav A. Blatov Boron Substructures in Inorganic Borides: Network Topology and Free Space. Crystal Growth & Design, 2023, 23 (4), 2531–2539. doi: 10.1021/acs.cgd.2c01440 IF 4.010

 
20221004-01 1 октября 2022 г. 
Janus structures of SMoSe and SVSe compositions with low enthalpy and unusual crystal chemistry.

P. Gavryushkin, N. Sagatov, E. Sukhanova, I. Medrish and Z. Popov Janus structures of SMoSe and SVSe compositions with low enthalpy and unusual crystal chemistry. Journal of Applied Crystallography, 2022, 55 (5), 1324–1335. doi: 10.1107/S1600576722008202 IF 4.475

 
PUB20220607 7 июня 2022 г. 
Hybrid DFT/Data-Driven Approach for Searching for New Quasicrystal Approximants in Sc-X (X = Rh, Pd, Ir, Pt) Systems.

Roman A. Eremin, Innokentiy S. Humonen, Pavel N. Zolotarev, Inna V. Medrish, Leonid E. Zhukov, and Semen A. Budennyy Hybrid DFT/Data-Driven Approach for Searching for New Quasicrystal Approximants in Sc-X (X = Rh, Pd, Ir, Pt) Systems. Crystal Growth & Design, 2022, 22 (7), 4570–4581. doi: 10.1021/acs.cgd.2c00463 IF 4.076

 
PUB20211202 2 декабря 2021 г. 
The nyerereite crystal structure: a possible messenger from the deep Earth.

Azzurra Zucchin, Pavel N. Gavryushkin, Alexander V. Golovin, Nadezhda B. Bolotina, Paola Stabile, Michael Robert Carroll, Paola Comodi, Francesco Frondini, Daniele Morgavi, Diego Perugini, Fabio Arzilli, Marco Cherin, Emmanuel Kazimoto, Konstantin Kokh, Artem Kuznetsov, and Inna V. Medrish The nyerereite crystal structure: a possible messenger from the deep Earth. American Mineralogist, 2021, 2022, 107 (11), 2054–2064. doi: 10.2138/am-2022-8106 IF 3.003

 
PUB20201210 10 декабря 2020 г. 
Metastable structures of CaCO3 and their role in transformation of calcite to aragonite and postaragonite.

Pavel N. Gavryushkin, Anatoly B. Belonoshko, Nursultan Sagatov, Dinara Sagatova, Elena Zhitova, Maria G. Krzhizhanovskaya, Aleksander Rečnik, Eugeny V. Alexandrov, Inna V. Medrish, Zakhar I. Popov, and Konstantin D. Litasov Metastable structures of CaCO3 and their role in transformation of calcite to aragonite and postaragonite. Crystal Growth and Design, 2021, 21, 1, 65–74. doi: 10.1021/acs.cgd.0c00589 IF 4.089

 
20210107-05 1 декабря 2020 г. 
Phase Relations of Iron Carbides Fe2C, Fe3C, and Fe7C3 at the Earth’s Core Pressures and Temperatures.

N.E. Sagatov, P.N. Gavryushkin, I.V. Medrish, T.M. Inerbaev, K.D. Litasov Phase Relations of Iron Carbides Fe2C, Fe3C, and Fe7C3 at the Earth’s Core Pressures and Temperatures. Russian Geology and Geophysics, 2020, 61 (12), 1345–1353. doI: 10.15372/RGG2019146 IF 1.150

 
PUB2020090601 6 сентября 2020 г. 
From Simple to Complex: Design of Inorganic Crystal Structures with a Topologically Extended Zintl–Klemm Concept.

Inna V. Medrish, Roman A. Eremin, and Vladislav A. Blatov From Simple to Complex: Design of Inorganic Crystal Structures with a Topologically Extended Zintl–Klemm Concept. Journal of Physical Chemistry Letters, 2020, 11 (19), 8114–8120. doi:10.1021/acs.jpclett.0c02468 IF 6.71

 
untitled 18 апреля 2020 г. 
Phase Diagrams of Iron Hydrides at Pressures of 100–400 GPa and Temperatures of 0–5000 K.

D.N. Sagatova, P.N. Gavryushkin, N.E. Sagatov, I. V. Medrish, K.D. Litasov Phase Diagrams of Iron Hydrides at Pressures of 100–400 GPa and Temperatures of 0–5000 K. JETP Letters, 2020, 111, 145–150. doi: 10.1134/S0021364020030108 IF 1.412

 
A1_11224_Cover page 1.indd 17 октября 2019 г. 
From clusters to crystals: scale chemistry of intermetallics.

Vladimir Ya. Shevchenko, Inna V. Medrish, Gregory D. Ilyushin, Vladislav A. Blatov From clusters to crystals: scale chemistry of intermetallics. Structural Chemistry, 2019, 30 (6), 2015–2027. doi: 10.1007/s11224-019-01427-5 IF 1.624