# | Title | Journal | Year | Citations |
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1 | High-temperature heat capacity and thermodynamic properties of Tb2Sn2O7 | Inorganic Materials | 2017 | 36 |
2 | Heat capacity of rare-earth stannates in the range 350–1000 K | Inorganic Materials | 2017 | 15 |
3 | Synthesis and High-Temperature Heat Capacity of Dy2Ge2O7 and Ho2Ge2O7 | Inorganic Materials | 2018 | 13 |
4 | Catalytic Sulfation of Betulin with Sulfamic Acid: Experiment and DFT Calculation | International Journal of Molecular Sciences | 2022 | 12 |
5 | Thermophysical properties of Bi12GeO20 single crystals | High Temperature | 2010 | 11 |
6 | Synthesis and High-Temperature Heat Capacity of Sm2Ge2O7 and Eu2Ge2O7 | Inorganic Materials | 2018 | 11 |
7 | High Temperature Heat Capacity and Thermodynamic Properties of Tm2Ge2O7 and TmInGe2O7 in the Region of 350–1000 K | Russian Journal of Physical Chemistry A | 2019 | 11 |
8 | Effect of the content of the α-phase and granulometric composition on the dissolution rate of alumina in cryolite-alumina melts | Russian Journal of Non-Ferrous Metals | 2009 | 9 |
9 | Heat Capacity of In2Ge2O7 and YInGe2O7 from 320 to 1000 K | Inorganic Materials | 2018 | 9 |
10 | High-temperature heat capacity and vibrational spectra of Eu2Sn2O7 | Inorganic Materials | 2016 | 8 |
11 | Plastic properties of pitch-coke compositions | Russian Journal of Non-Ferrous Metals | 2009 | 7 |
12 | High-temperature heat capacity of Sc2Cu2O5 | Inorganic Materials | 2014 | 7 |
13 | Synthesis of the CeVO4 orthovanadate and its heat capacity in the range 350–1000 K | Inorganic Materials | 2016 | 7 |
14 | High-temperature heat capacity of oxides of the CuO–V2O5 system | Physics of the Solid State | 2017 | 7 |
15 | Synthesis of Pr2CuO4 and its heat capacity in the range 364–1064 K | Inorganic Materials | 2014 | 6 |
16 | Synthesis and heat capacity of PrVO4 in the temperature interval of 396–1023 K | Russian Journal of Inorganic Chemistry | 2015 | 6 |
17 | High-temperature heat capacity of the oxide compounds in the Bi2O3–V2O5 system | Inorganic Materials | 2017 | 6 |
18 | High-temperature heat capacity of YBiGeO5 and GdBiGeO5 in the range 373–1000 K | Physics of the Solid State | 2017 | 6 |
19 | Plastic properties of homogenized coke-pitch compositions | Russian Journal of Non-Ferrous Metals | 2011 | 5 |
20 | Contact interaction of Bi2O3-SiO2 melts with gold | Inorganic Materials | 2012 | 5 |
21 | Influence of the activation time on parameters of a graphite structure | Russian Journal of Non-Ferrous Metals | 2016 | 5 |
22 | Synthesis and high-temperature heat capacity of Gd2Sn2O7 | Inorganic Materials | 2016 | 5 |
23 | Heat capacity of GdBiGeO5 in the temperature range 373–1000 K | Doklady Physical Chemistry | 2017 | 5 |
24 | Heat Capacity of the R2Ge2O7 (R = Pr–Lu, Y) Rare-Earth Germanates | Inorganic Materials | 2019 | 5 |
25 | Electrical conductivity of NaF-AlF3-CaF2-Al2O3 melts | Russian Metallurgy (Metally) | 2010 | 4 |
26 | Synthesis and investigation of the heat capacity of Sm2Sn2O7 in the 346–1050 K range | Russian Journal of Inorganic Chemistry | 2016 | 4 |
27 | High-temperature heat capacity of CdO–V2O5 oxides | Physics of the Solid State | 2017 | 4 |
28 | Heat Capacity of the Gd2Ti2O7 and Lu2Ti2O7 Pyrochlores in the Range 350–1000 K | Inorganic Materials | 2019 | 4 |
29 | Specific Heat of the Er2Ge2O7–Er2Sn2O7 Solid Solutions in the Temperature Range of 350–1000 K | Physics of the Solid State | 2019 | 4 |
30 | Solubility of aluminum in cryolite-alumina electrolytes | Russian Journal of Non-Ferrous Metals | 2011 | 3 |
31 | High-temperature heat capacity of YbAl3(BO3)4 | Russian Journal of Physical Chemistry A | 2014 | 3 |
32 | Ground state of a periodic elastic atomic chain in an arbitrary periodic potential | Physics of the Solid State | 2016 | 3 |
33 | High-temperature heat capacity of orthovanadates Ce1–x Bi x VO4 | Physics of the Solid State | 2016 | 3 |
34 | Ion-exchange sorption of silver(I) chloride complexes from aqueous HCl solutions | Russian Journal of Physical Chemistry A | 2017 | 3 |
35 | High-temperature heat capacity of stannates Er2Sn2O7 and Tm2Sn2O7 | Doklady Physical Chemistry | 2017 | 3 |
36 | Synthesis and High-Temperature Heat Capacity of Pb8La2(GeO4)4(VO4)2 and Pb8Nd2(GeO4)4(VO4)2 with the Apatite Structure | Inorganic Materials | 2018 | 3 |
37 | Ion-Exchange Sorption of Palladium(II) from Hydrochloric Acid Solutions in the Presence of Silver(I) | Russian Journal of Physical Chemistry A | 2018 | 3 |
38 | Heat Capacity of Pb10 –xLax(GeO4)2 +x(VO4)4 –x (x = 0, 1, 2, 3) Apatites in the Range 320–1000 K | Inorganic Materials | 2019 | 3 |
39 | Heat Capacity of Compounds in the Bi2O3–TiO2 System | Inorganic Materials | 2020 | 3 |
40 | Heat Capacity and Thermodynamic Properties of Gd2Ge2O7 from 350 to 1000 K | Inorganic Materials | 2020 | 3 |
41 | Behavior of secondary alumina during heating | Russian Journal of Non-Ferrous Metals | 2010 | 2 |
42 | High-temperature heat capacity of Pb2SnO4 | Inorganic Materials | 2012 | 2 |
43 | Heat capacity and thermodynamic properties of GaFeO3 in the range 330–900 K | Inorganic Materials | 2013 | 2 |
44 | Heat capacity and thermodynamic properties of europium orthovanadate EuVO4 in the temperature range of 400–1010 K | Russian Journal of Physical Chemistry A | 2015 | 2 |
45 | High-temperature specific heat of thulium orthovanadate TmVO4 within the range 379–1026 K | Doklady Physical Chemistry | 2015 | 2 |
46 | Ion-exchange extraction of platinum(II,IV) from chloride solutions in the presence of iron(III) | Russian Journal of Physical Chemistry A | 2015 | 2 |
47 | High-temperature heat capacity and thermodynamic properties of TbBiGeO5 and DyBiGeO5 | Inorganic Materials | 2017 | 2 |
48 | Increase in Electrolyzer Energy Efficiency with a Self-Baking Anode | Metallurgist | 2019 | 2 |
49 | Heat Capacity of Pb10 –xPrx(GeO4)2 +x(VO4)4– x (x = 0, 1, 2, 3) Apatites in the Range 350–1050 K | Inorganic Materials | 2020 | 2 |
50 | Synthesis, Structure, and Thermophysical Properties of EuGaGe2O7 | Inorganic Materials | 2020 | 2 |