Contact fracture behavior of ice

The formation of an intermediate layer under hydrostatic compression at a shear appearing due to the action of converging and diverging fronts of stress momentums (pulses) is considered. Continuous monitoring of deformational changes in the structure of ice was carried out using acoustic methods. The features of contact ice breaking in the diverging fronts of stress pulses are considered by the example of the slow impact of a rigid spherical indenter on an ice plate simulating half-space. Using the piezoelectric accelerometer, an oscillogram of the impact was recorded and a generalized dependence of the reduced stress on the reduced instantaneous velocity of the impact (semi-cubic parabola) was obtained. It is established that under conditions of the experiment (smooth convex indenter surface and icy half-space) a thin intermediate layer is formed, the properties of which determine the physical similarity in the family of curves «instantaneous force-instantaneous velocity». A rheological model with due regard for the change in the microstructure of ice during the impact is proposed. Quantitative determinations of the deformation changes in structure of solid ice samples were performed under intensive plastic deformation in a matrix with a profile similar to the Laval nozzle. The deformations created by the piston caused forced vibrations in the ice. The working surface of the piston in the form of an ellipsoid together with the smooth walls of the matrix and the reverse cone created conditions for parametric resonance and the formation of fronts of highfrequency stress pulses. Under influence of these pulses, zones with a superplastic fine-crystalline structure of ice (cumulative effect) were formed in ice. In the outlet cylindrical channel, a flow around an obstacle of the ice with the structure of an intermediate layer (dynamic viscosity 20 MPa s) and the distribution of velocities of motion over the channel cross section were studied. The obtained results can be used to simulate the processes of contact destruction of deep rocks by a support or an ice-resistant platform loaded with an ice field.

1. Bogorodskiy V.V., Gavrilo V.P. Led. Fizicheskiye svoystva. Sovremennye metody glyatsiologii. Ice. Physical properties. Modern methods of glaciology. Leningrad: Hydrometeoizdat, 1980: 384 p. [In Russian].

2. Epifanov V. P. Tectonic structure and velocity distribution in the bottom layers of glaciers. Vestnik Kol'skogo nauch- nogo tsentra RAN. Herald of the Kola Science Centre of the RAS. 2018, 3 (10): 141–147. doi: 10.25702/KSC.2307-5228.2018.10.3.141-146. [In Russian].

3. Pettit E.C., Whorton E.N., Waddington E.D., Sletten R.S. Influence of debris-rich basal ice on flow of a polar glacier. Journ. of Glaciology. 2014, 60 (223): 909– 1006. doi: 10.3189/2014JoG13J161.

4. Iverson N.R. A theory of glacial quarrying for landscape evolution models. Geology. 2012, 40 (8): 679–682.

5. Makkonen L., Tikanmaki M. Modelling the friction of ice. Cold Regions Science and Technology. 2014: 84– 93. doi: 10.1016/j.coldregions.2014.03.002.

6. Zaretsky Yu.K., Chumichev B.D. Kratkovremennaya pol- zuchest' l'da. Short-term creep of ice. Novosibirsk: Nauka, 1982: 120 p. [In Russian].

7. Durham W.B., Prieto-Ballestros O., Goldsby D.L., Kar- gel J.S. Rheological and thermal properties of ice materials. Space Science Reviews. 2010, 153 (1): 273–298. doi: 10.1007/s11214-009-9619-1.

8. Gillet-Chaulet F., Gagliardini O., Meyssonnier J., Zwing- er T., Ruokolainen J. Flow-induced anisotropy in polar ice and related ice-sheet flow modeling. Journ. Non- Newtonian Fluid Mechanics. 2006, 134: 33–43.

9. Gödert G., Hutter K. Material update procedure for planar transient flow of ice with evolving anisotropy // Annals of Glaciology. 2000, 30: 107–114.

10. Piazolo S., Wilson C.J.L., Luzin V., Brouzet C., Peternell M. Dynamics of ice mass deformation: Linking processes to rheology, texture, and microstructure. Geochemistry, Geophysics, Geosystems. 2013, 14 (10): 4185–41194.

11. Epifanov V.P. Destruction of polycrystalline ice. Dokla- dy Akademii Nauk. Proc. of the Academy of Sciences. 1982, 267 (6): 1364–1367. [In Russian].

12. Epifanov V.P., Glazovsky A.F. Acoustic characteristics as an indicator of the features of ice movement in glaciers. Kriosfera Zemli. Earth's Cryosphere. 2010, 14 (4): 42–55. [In Russian].

13. Epifanov V.P. Physical modeling of the motion regimes of glaciers. Led i Sneg. Ice and Snow. 2016, 56 (3): 333–344. [In Russian].

14. Valiev R.Z., Enikeev N.A., Murashkin M.Yu., Utya- shev F.Z. Use of intense plastic deformations to obtain bulk nanostructured metallic materials. Izvestiya Akademii Nauk. Mekhanika tverdogo tela. Proc. of the Academy of Sciences. Mechanics of solid body. 2012. 4: 109–122. [In Russian].

15. Georgievsky D.V. Shabaykin R.R. Quasistatic and dynamic compression of a flat round ideally plastic layer by rigid plates. Matematicheskoe modelirovanie i eksper- imentalnaya mehanika deformiruemogo tverdogo tela. Mathematical modeling and experimental mechanics of a deformable solid body. Tver: Tver State Technical University, 2017: 56–63. [In Russian].

16. Sazonov K.E. Determination of methods for correcting the results of model experiments to determine the ship’s ice resistance. Trudy TSNII imeni akad. A.N. Krylova. Proc. of the Krylov Central Research Institute. 2016, 92 (376): 93–108. [In Russian].

17. Goldstein R.V., Epifanov V.P., Osipenko N.M. Large-scale effect in the destruction of river ice under indentation conditions. Aktual'nyye problemy mekhaniki: Mekhanika de- formiruyemogo tverdogo tela. Actual problems of mechanics: the mechanics of a deformable solid. Ed. R.V. Goldstein. Moscow: Nauka, 2009: 35–55. [In Russian].

18. Epifanov V.P. Effect of an intermediate layer on the strength of an ice – substrate interface. Doklady Аkademii nauk. Proc. of the Academy of Sciences. 2017, 62 (1): 14–19.

19. Cherepanov N.V. Classification of ices of natural reservoirs. Nauchnyye trudy Instituta Arktiki i Antarktiki. Scientific works of the Institute of the Arctic and Antarctic. 1976, 331: 77–99. [In Russian].

20. Epifanov V.P. The effect of stress pulses on the structure of ice in an intermediate layer. Doklady Аkademii nauk. Proc. of the Academy of Sciences. 2018, 63 (4): 151–155.

21. Epifanov V.P. Simulation of recrystallization processes in the bottom layers of glaciers. Kriosfera Zemli. Earth's Cryosphere. 2015, 19 (3): 20–31. [In Russian].

22. Epifanov V.P. Ice destruction during shock interactions. Doklady Akademii Nauk. Proc. of the Academy of Sciences. 1985, 284 (3): 599–603. [In Russian].

23. Kolesnikov Yu.V., Morozov E.M. Mekhanika kontaktno- go razrusheniya. Contact damage mechanics. Moscow: Science, 1989: 224 р. [In Russian].

24. Heisin D.E., Likhomanov V.A. Experimental determination of the specific energy of the mechanical crushing of ice upon impact. Problemy Arktiki i Antarktiki. Problems of the Arctic and Antarctic. 1973, 41: 55–61. [In Russian].

25. Herz H. Über die Berührung fester elastischer Körper. Journ. für die reine und angewandte Mathematik. 1881, 92: 156–171.

26. Kilchevsky N.A. Dinamicheskoye kontaktnoye szhatiye tvordykh tel. Udar. Dynamic contact compression of solids. Hit. Kiev: Naukova Dumka, 1976: 320 p. [In Russian].

27. Timoshenko SL, Gudier J. Teoriya uprugosti. Theory of elasticity. Moscow: Nauka, 1975: 576 p. [In Russian].

28. Bogorodsky V.V., Gavrilo V.P., Nedoshivin S.A. Raz- rusheniye l'da. Metody, tekhnicheskiye sredstva. The destruction of the ice. Methods, technical means. Leningrad: Hydrometeoizdat, 198З: 232 p. [In Russian].

29. Saveliev B.A. Glyatsiologiya. Glaciology. Moscow: MSU, 1991: 288 p. [In Russian].