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I. I. Mokhov
170. Denisov S. N., Arzhanov M. V., Eliseev A. V., et al, 2013: Assessments of stabili‑
ty of methane hydrates in the Lake Baikal system. Doklady Earth Sci., 449(1), 346–348.
171. Denisov S. N., Eliseev A. V., Mokhov I. I., 2013: Climate change in IAP RAS
global model taking account of interaction with methane cycle under anthropogenic sce‑
narios of RCP family. Russ. Meteorol. Hydrol., 11, 741–749.
172. Eliseev A. V., 2011: Estimation of changes in characteristics of the climate and
carbon cycle in the 21st century accounting for the uncertainty of terrestrial biota param‑
eter values.
Izvestiya, Atmos. Oceanic Phys., 47(2), 131–153.
173. Eliseev A. V., Mokhov I. I., 2011: Effect of including land-use driven radiative
forcing of the surface albedo of land on climate response in the 16th-21st centuries. Iz‑
vestiya, Atmos. Oceanic Phys., 47(1), 15–30.
174. Eliseev A. V., Mokhov I. I., Muryshev K. E., 2011: Estimates of climate changes
in the 20th-21st centuries based on the version of the IAP RAS climate model including
the model of general ocean circulation. Russ. Meteorol. Hydrol., 36(2), 73–81.
175. Khon V. C., Mokhov I. I., Pogarsky F. A., 2013: Estimating changes of wind-
wave activity in the Arctic Ocean in the 21st century using the regional climate model.
Doklady Earth Sci., 452(2), 1027–1029.
176. Khon V. C., Mokhov I. I., Pogarsky F. A., Babanin A., Dethloff K., Rinke A.,
Matthes H., 2014: Wave heights in the 21st century Arctic Ocean simulated with a re‑
gional climate model. Geophys. Res. Lett., 41(8), 2956–2961.
177. Khon V. C., Park W., Latif M., Mokhov I. I., Schneider B., 2012: Tropical circu‑
lation and hydrological cycle response to orbital forcing. Geophys. Res. Lett., 39(15),
L15708.
178. Kislov A. V., Panin A. V., Toropov P. A., 2014: Present-day variations and paleo‑
dynamics of the Caspian Sea level as a standard for climate modeling data verification.
Russ. Meteorol. Hydrol., 39(5), 328–334.
179. Khon V. C., Mokhov I. I., 2012: The hydrological regime of large river basins in
Northern Eurasia in the XX–XXI centuries. Water
Resources, 39(1), 1–10.
180. Kuzin V. I., Platov G. A., Golubeva E. N., et al, 2012: Certain results of numerical
simulation of processes in the Arctic Ocean. Izvestiya, Atmos. Oceanic Phys., 48(1),
102–119.
181. Lehmann J., Coumou D., Frieler K., Eliseev A. V., Levermann A., 2014: Future
changes in extratropical storm tracks and baroclinicity under climate change. Environ.
Res. Lett., 9(8), 084002.
182. Mareev E. A., Volodin E. M., 2014: Variation of the global electric circuit and
ionospheric potential in a general circulation model. Geophys. Res. Lett., 41(24), 9009–
9016.
183. Mokhov I. I., Semenov V. A., Khon V. C., Pogarsky F. A., 2013: Change of sea ice
extent in the Arctic and the associated climatic effects: detection and simulation. Ice and
Snow, 2(122), 53–62. (in Russian)
184. Mokhov I. I., Timazhev A. V., Lupo A. R., 2014: Changes in atmospheric block‑
ing characteristics within Euro-Atlantic region and Northern Hemisphere as a whole in
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the 21st century from model simulations using RCP anthropogenic scenarios. Glob. Plan‑
et. Change, 122, 265–270.
185. Morozova P. A., 2014: Influence of the Scandinavian ice sheet on the climatic
conditions of the East European Plain evidenced from the numerical simulation project
PMIP II.
Ice and Snow, 1(125), 113–124. (in Russian)
186. Zickfeld K., Eby M., Weaver A. J. et al., 2013: Long-term climate change com‑
mitment and reversibility: An EMIC intercomparison. J. Clim., 26(16), 5782–5809.
187. Moshonkin S. N., Alekseev G. V., Diansky N. A., et al, 2011: Reproduction of the
large-scale state of water and sea ice in the arctic ocean in 1948–2002: Part I. Numerical
model. Izvestiya, Atmos. Oceanic Phys., 47(5), 628–641.
188. Nadezhina E. D., Mol’kentin E. K., Kiselev A. A., et al, 2011: Investigation of
parameterization effect on the methane flux estimation from the regional climate model
of the main geophysical observatory for the territory of Russia. Russ. Meteorol. Hydrol.,
6, 371–382.
189. Rybak O. O., Fürst J. J., Huybrechts P., 2013: Mathematical modeling of ice flow
in the north-western Greenland and interpretation of deep drilling data at the NEEM
camp. Ice and Snow, 1(121), 16–15. (in Russian)
190. Rybak O. O., Huybrects P., 2012: Mathematical modeling of ice flow in Queen
Maud Land, Antarctica, and its application to the Late Quaternary climate paleorecon‑
structions. . Ice and Snow, 3(119), 5–16. (in Russian)
191. Rybak O. O., Huybrects P., 2014: The Greenland ice sheet at the peak of warming
during the previous Interglacial. Ice and Snow, 2(126), 91–101. (in Russian)
192. Semenov V. A., 2011: Climate-related changes in hazardous and adverse hydro‑
logical events in the Russian rivers. Russ. Meteorol. Hydrol., 36(2), 124–129.
193. Semenov V. A., 2014: Role of sea ice in wintertime Arctic temperature anoma‑
lies. Izvestiya, Atmos. Oceanic Phys., 50(4), 343–349.
194. Semenov V. A., Mokhov I. I., Latif M., 2012: Influence of the ocean surface tem‑
perature and sea ice concentration on regional climate changes in Eurasia in recent dec‑
ades. Izvestiya, Atmos. Oceanic Phys., 48(4), 355–372.
195. Semenov V. A., Shelekhova E. A., Mokhov I. I. et al. Influence of the Atlantic
Multidecadal Oscillation on settling anomalous climate regimes in Northern Eurasia
based on model simulation. Doklady Earth Sci., 459(2), 1619–1622.
196. Overland J. E., Wang M. Y., Bond N. A. et al., 2011: Considerations in the selec‑
tion of global climate models for regional climate projections: The Arctic as a case study.
J. Clim., 24(6), 1583–1597.
197. Semenov V. A., Mokhov I. I., Polonsky A. B. Modeling of impact of natural
long-period variability in the North Atlantic upon formation of climate anomalies. Ma‑
rine Hydrophysical J., 4, 14–27. (in Russian)
198. Mokhov I. I., 2014: Hydrological anomalies and tendencies of change in the ba‑
sin of the Amur River under global warming. Doklady Earth Sci., 455(2), 459–462.
199. Mokhov I. I., Akperov M. G., Prokofyeva M. A. et al., 2013: Blockings in the
Northern hemisphere and Euro‑Atlantic region: Estimates of changes from reanalysis
data and model simulations. Doklady Earth Sci., 449(2), 430–433.