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Vernon P., Caron F. & Davies L. (1999). Annual activity of two endemic beetles (Carabidae) at the edge between fell-field and moorland on a sub-Antarctic island. Eur. J. Soil Biol., 35(1), 39–43.
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Vernon P., Cariou M.L. & Deunff J. (1997). Genetic variability in the wingless subantarctic genus Anatalanta (Diptera, Sphaeroceridae): a preliminary approach. Polar Biol., 18, 384–390.
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Vernon P. & Vannier G. (1996). Developmental patterns of supercooling capacity in a subantarctic wingless fly. Experientia, 52, 155–158.
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Vernon P. & Vannier G. (1994). Cold hardiness in Arctic, Antarctic and Subanractic Diptera:Physiological Ecology crosses Biography. Cryoletters, 15, 02/03/2006.
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Vernon P. & Vannier G. (2002). Evolution of freezing susceptibility and freezing tolerance in terrestrial arthropods. Comptes rendus de biologies, 325, 1185–1190.
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Vernon P. (1994). Introduction to the papers from the first European Workshop on Invertebrate Ecophysiology. Acta oecologica-international journal of ecology, 15(1).
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Vernon P. (2003). Supercooling activity in invertebrate eggs..
Abstract: International Symposium on
Animal and Plant Cold Hardiness, Ceske
Budejovice, Czech Republic, 10-14/08/2003
Programme: 136
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Vernon P. (2011). Body size along elevation gradients in alpine and sub-antarctic environments: a challenge for ectotherms..
Abstract: International Symposium of Environmental Physiology of Ectotherms and Plants (ISEPEP4), Rennes, France, 18-22/07/2011
Programme: 136
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Vernin, J.; Chadid, M.; Aristidi, E.; Agabi, A.;Trinquet, H.; van der Swaelmen, M. (2009). First single star scidar measurements at Dome C, Antarctica. ASTRONOMY & ASTROPHYSICS, 500(3), 1271–1276.
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Verhoeven, O.; Rivoldini, A.; Vacher, P.; Mocquet, A.; Choblet, G.; Menvielle, M.; Dehant, V.; Van Hoolst, T.; Sleewaegen, J.; Barriot, J.-P.; Lognonné, P. (2005). Interior structure of terrestrial planets: Modeling Mars' mantle and its electromagnetic, geodetic, and seismic properties. J. Geophys. Res., 110.
Abstract: We present a new procedure to describe the one-dimensional thermodynamical state and mineralogy of any Earth-like planetary mantle, with Mars as an example. The model parameters are directly related to expected results from a geophysical network mission, in this case electromagnetic, geodetic, and seismological processed observations supplemented with laboratory measurements. We describe the internal structure of the planet in terms of a one-dimensional model depending on a set of eight parameters: for the crust, the thickness and the mean density, for the mantle, the bulk volume fraction of iron, the olivine volume fraction, the pressure gradient, and the temperature profile, and for the core, its mass and radius. Currently, available geophysical and geochemical knowledge constrains the range of the parameter values. In the present paper, we develop the forward problem and present the governing equations from which synthetic data are computed using a set of parameter values. Among all Martian models fitting the currently available knowledge, we select eight candidate models for which we compute synthetic network science data sets. The synergy between the three geophysical experiments of electromagnetic sounding, geodesy, and seismology is emphasized. The stochastic inversion of the synthetic data sets will be presented in a companion paper.
Keywords: internal structure; Mars; network science; 5430 Planetary Sciences: Solid Surface Planets: Interiors; 6225 Planetary Sciences: Solar System Objects: Mars; 3672 Mineralogy and Petrology: Planetary mineralogy and petrology
Programme: 905;907
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