Research Article
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Rotational Self-Shrinkers in Euclidean Spaces

Year 2024, , 34 - 43, 23.04.2024
https://doi.org/10.36890/iejg.1330887

Abstract

The rotational embedded submanifold of $\mathbb{E}^{n+d}$ first studied by
N. Kuiper. The special examples of this type are generalized Beltrami
submanifolds and toroidals submanifold. The second named authour and at. all
recently have considered $3-$dimensional rotational embedded submanifolds in
$\mathbb{E}^{5}$. They gave some basic curvature properties of this type of
submaifolds. Self-similar flows emerge as a special solution to the mean
curvature flow that preserves the shape of the evolving submanifold. In
this article we consider self-similar submanifolds in Euclidean spaces. We
obtained some results related with self-shrinking rotational submanifolds in
Euclidean $5-$space $\mathbb{E}^{5}$. Moreover, we give the necessary and
sufficient conditions for these type of submanifolds to be homothetic
solitons for their mean curvature flows.

References

  • [1] Abresch, U., Langer, J.: The normalized curve shortening flow and homothetic solutions. J. Differential Geom. 23, 175-196 (1986).
  • [2] Andrews, B.: Classification of limiting shapes for isotropic curve flows. J. Amer. Math. Soc. 16, 443-459 (2003).
  • [3] Arezzo, C., Sun, J.: Self-shrinkers for the mean curvature flow in arbitrary codimension. Math. Z. 274, 993-1027 (2013).
  • [4] Arslan, K., Bayram (Kılıç), B., Bulca, B., Öztürk, G.: Rotation submanifolds in Euclidean spaces. Int. J. Geom. Meth. Mod. Phy. 16, 1-12 (2019).
  • [5] Cao, H.D., Li, H.: A gap theorem for self-shrinkers of the mean curvature flow in arbitrary codimension. Calc. Var. 46, 879-889 (2013).
  • [6] Castro I., Lerma A.M.: The Clifford torus as a self-shrinker for the Lagrangian mean curvature flow. Int. Math. Res. Not. 16, 1515-1152 (2014).
  • [7] Castro, I., Lerma A.M.: Homothetic solitons for the inverse mean curvature flow. Results in Math. 71, 1109-1125 (2017).
  • [8] Chen, B. Y.: Geometry of Submanifolds. Dekker, New York (1973).
  • [9] Chen, B. Y.: Topics in differential geometry associated with position vector fields on Euclidean submanifolds. Arab J. Math. Sci. 23, 1-17 (2017).
  • [10] Chen, B.Y., Deshmukd, S.: Classification of Ricci solitons on Euclidean hypersurfaces. Int. J. Math. 25, 1-22 (2014).
  • [11] Cheng, Q.M., Li, Z., Wei, G.: Complete self-shrinkers with constant norm of the second fundamental form. Mathematische Zeitschrift. 300,995-1018 (2022).
  • [12] Cheng, Q.M., Peng, Y.: Complete self-shrinkers of the mean curvature flow. Calc. Var. 52, 497-506 (2015).
  • [13] Cooper, A.A.: Mean Curvature Flow in Higher Codimension. Ph.D. Thesis. Michigan State University, Graduate Program in Mathematics, USA.(2011).
  • [14] Drugan, G., Lee, H., Nguyen, X.H.: A survey of closed self-shrinkers with symmetry. Results in Math. 32, 73-32 (2018).
  • [15] Drugan, G., Lee, H., Wheeler, G.: Solitons for the inverse mean curvature flow. Pasific J. Math. 284, 309-326 (2016).
  • [16] Ecker, K.: Regularity theory for mean curvature flow. Birkhäuser Inc., Boston, (2004).
  • [17] Ecker, K., Huisken, G.: Mean curvature evolution of entire gaphs. Annals of Math. 130, 453-471 (1989).
  • [18] Etemoğlu, E., Arslan, K., Bulca, B.: Self similar surfaces in Euclidean spaces. Selçuk J. Appl. Math. 14, 71-81 (2013).
  • [19] Gorkavyy G., Nevmerzhytska, O.: Pseudo-spherical submanifolds with degenerate Bianchi transformation. Results. Math. 60, 103-116 (2011).
  • [20] Guan Z., Li, F.: Self-shrinker type submanifolds in the Euclidean space. Bul. Iranian Math. Soc. 47, 101-110 (2021).
  • [21] Guo, S. H.: Self shrinkers and singularity models of the main curvature flow. Ph.D. Thesis, The State University of New Jersey, Graduate Program in Mathematics, USA, (2017).
  • [22] Halldorsson, P.H.: Self-similar solutions to the mean curvature flow in Euclidean and Minkowski space. Ph.D. Thesis. Masschusetts Institute of Technology, Department of Mathematics, USA, (2013).
  • [23] Huisken, G., Ilmanen, T.: The inverse mean curvature flow and the Riemannian Penrose inequality. J. Differential Geom. 59, 353-437 (2001).
  • [24] Huisken, G., Ilmanen, T.: Higher regularity of the inverse mean curvature flow. J. Differential Geom. 80, 433-451 (2008).
  • [25] Hussey, C.: Classification and analysis of low index mean curvature flow self-shrinkers. Ph.D. Thesis. The Johns Hopkins University,Department of Mathematics, USA, (2012).
  • [26] Joyse, D., Lee, Y., Tsui M.P.: Self-similar solutions and translating solutions for Lagrangian mean curvature flow. J. Differential Geom. 84, 127-161 (2010).
  • [27] Kuiper, N.H.: Minimal total absolute curvature for immersions. Invent. Math. 10, 209-238 (1970).
  • [28] Montegazza, C.: Lecture notes on mean curvature flow, Birkhauser (2011).
  • [29] Peng, Y.: Complete self-shrinkers of mean curvature flow. Ph.D. Thesis. Saga University, Graduate School of Science and Engineering, Department of Science and Advanced Technology, Japan (2013).
  • [30] Schulze, F.: Introduction to mean curvature flow. Lecture Notes, University College London, (2017).
  • [31] Sigal, I. M.: Lectures on mean curvature flow and stability. Lecture Notes, Dept. of Mathematics, Univ. of Toronto, (2014).
  • [32] Smoczyk, K.: Mean curvature flow in higher codimension: Introduction and survey. Global Differential Geometry, Springer Verlag, Berlin,Heidelberg, (2012).
Year 2024, , 34 - 43, 23.04.2024
https://doi.org/10.36890/iejg.1330887

Abstract

References

  • [1] Abresch, U., Langer, J.: The normalized curve shortening flow and homothetic solutions. J. Differential Geom. 23, 175-196 (1986).
  • [2] Andrews, B.: Classification of limiting shapes for isotropic curve flows. J. Amer. Math. Soc. 16, 443-459 (2003).
  • [3] Arezzo, C., Sun, J.: Self-shrinkers for the mean curvature flow in arbitrary codimension. Math. Z. 274, 993-1027 (2013).
  • [4] Arslan, K., Bayram (Kılıç), B., Bulca, B., Öztürk, G.: Rotation submanifolds in Euclidean spaces. Int. J. Geom. Meth. Mod. Phy. 16, 1-12 (2019).
  • [5] Cao, H.D., Li, H.: A gap theorem for self-shrinkers of the mean curvature flow in arbitrary codimension. Calc. Var. 46, 879-889 (2013).
  • [6] Castro I., Lerma A.M.: The Clifford torus as a self-shrinker for the Lagrangian mean curvature flow. Int. Math. Res. Not. 16, 1515-1152 (2014).
  • [7] Castro, I., Lerma A.M.: Homothetic solitons for the inverse mean curvature flow. Results in Math. 71, 1109-1125 (2017).
  • [8] Chen, B. Y.: Geometry of Submanifolds. Dekker, New York (1973).
  • [9] Chen, B. Y.: Topics in differential geometry associated with position vector fields on Euclidean submanifolds. Arab J. Math. Sci. 23, 1-17 (2017).
  • [10] Chen, B.Y., Deshmukd, S.: Classification of Ricci solitons on Euclidean hypersurfaces. Int. J. Math. 25, 1-22 (2014).
  • [11] Cheng, Q.M., Li, Z., Wei, G.: Complete self-shrinkers with constant norm of the second fundamental form. Mathematische Zeitschrift. 300,995-1018 (2022).
  • [12] Cheng, Q.M., Peng, Y.: Complete self-shrinkers of the mean curvature flow. Calc. Var. 52, 497-506 (2015).
  • [13] Cooper, A.A.: Mean Curvature Flow in Higher Codimension. Ph.D. Thesis. Michigan State University, Graduate Program in Mathematics, USA.(2011).
  • [14] Drugan, G., Lee, H., Nguyen, X.H.: A survey of closed self-shrinkers with symmetry. Results in Math. 32, 73-32 (2018).
  • [15] Drugan, G., Lee, H., Wheeler, G.: Solitons for the inverse mean curvature flow. Pasific J. Math. 284, 309-326 (2016).
  • [16] Ecker, K.: Regularity theory for mean curvature flow. Birkhäuser Inc., Boston, (2004).
  • [17] Ecker, K., Huisken, G.: Mean curvature evolution of entire gaphs. Annals of Math. 130, 453-471 (1989).
  • [18] Etemoğlu, E., Arslan, K., Bulca, B.: Self similar surfaces in Euclidean spaces. Selçuk J. Appl. Math. 14, 71-81 (2013).
  • [19] Gorkavyy G., Nevmerzhytska, O.: Pseudo-spherical submanifolds with degenerate Bianchi transformation. Results. Math. 60, 103-116 (2011).
  • [20] Guan Z., Li, F.: Self-shrinker type submanifolds in the Euclidean space. Bul. Iranian Math. Soc. 47, 101-110 (2021).
  • [21] Guo, S. H.: Self shrinkers and singularity models of the main curvature flow. Ph.D. Thesis, The State University of New Jersey, Graduate Program in Mathematics, USA, (2017).
  • [22] Halldorsson, P.H.: Self-similar solutions to the mean curvature flow in Euclidean and Minkowski space. Ph.D. Thesis. Masschusetts Institute of Technology, Department of Mathematics, USA, (2013).
  • [23] Huisken, G., Ilmanen, T.: The inverse mean curvature flow and the Riemannian Penrose inequality. J. Differential Geom. 59, 353-437 (2001).
  • [24] Huisken, G., Ilmanen, T.: Higher regularity of the inverse mean curvature flow. J. Differential Geom. 80, 433-451 (2008).
  • [25] Hussey, C.: Classification and analysis of low index mean curvature flow self-shrinkers. Ph.D. Thesis. The Johns Hopkins University,Department of Mathematics, USA, (2012).
  • [26] Joyse, D., Lee, Y., Tsui M.P.: Self-similar solutions and translating solutions for Lagrangian mean curvature flow. J. Differential Geom. 84, 127-161 (2010).
  • [27] Kuiper, N.H.: Minimal total absolute curvature for immersions. Invent. Math. 10, 209-238 (1970).
  • [28] Montegazza, C.: Lecture notes on mean curvature flow, Birkhauser (2011).
  • [29] Peng, Y.: Complete self-shrinkers of mean curvature flow. Ph.D. Thesis. Saga University, Graduate School of Science and Engineering, Department of Science and Advanced Technology, Japan (2013).
  • [30] Schulze, F.: Introduction to mean curvature flow. Lecture Notes, University College London, (2017).
  • [31] Sigal, I. M.: Lectures on mean curvature flow and stability. Lecture Notes, Dept. of Mathematics, Univ. of Toronto, (2014).
  • [32] Smoczyk, K.: Mean curvature flow in higher codimension: Introduction and survey. Global Differential Geometry, Springer Verlag, Berlin,Heidelberg, (2012).
There are 32 citations in total.

Details

Primary Language English
Subjects Algebraic and Differential Geometry
Journal Section Research Article
Authors

Kadri Arslan 0000-0002-1440-7050

Yılmaz Aydın 0000-0003-4292-5880

Betül Bulca Sokur 0000-0001-5861-0184

Early Pub Date April 5, 2024
Publication Date April 23, 2024
Acceptance Date March 24, 2024
Published in Issue Year 2024

Cite

APA Arslan, K., Aydın, Y., & Bulca Sokur, B. (2024). Rotational Self-Shrinkers in Euclidean Spaces. International Electronic Journal of Geometry, 17(1), 34-43. https://doi.org/10.36890/iejg.1330887
AMA Arslan K, Aydın Y, Bulca Sokur B. Rotational Self-Shrinkers in Euclidean Spaces. Int. Electron. J. Geom. April 2024;17(1):34-43. doi:10.36890/iejg.1330887
Chicago Arslan, Kadri, Yılmaz Aydın, and Betül Bulca Sokur. “Rotational Self-Shrinkers in Euclidean Spaces”. International Electronic Journal of Geometry 17, no. 1 (April 2024): 34-43. https://doi.org/10.36890/iejg.1330887.
EndNote Arslan K, Aydın Y, Bulca Sokur B (April 1, 2024) Rotational Self-Shrinkers in Euclidean Spaces. International Electronic Journal of Geometry 17 1 34–43.
IEEE K. Arslan, Y. Aydın, and B. Bulca Sokur, “Rotational Self-Shrinkers in Euclidean Spaces”, Int. Electron. J. Geom., vol. 17, no. 1, pp. 34–43, 2024, doi: 10.36890/iejg.1330887.
ISNAD Arslan, Kadri et al. “Rotational Self-Shrinkers in Euclidean Spaces”. International Electronic Journal of Geometry 17/1 (April 2024), 34-43. https://doi.org/10.36890/iejg.1330887.
JAMA Arslan K, Aydın Y, Bulca Sokur B. Rotational Self-Shrinkers in Euclidean Spaces. Int. Electron. J. Geom. 2024;17:34–43.
MLA Arslan, Kadri et al. “Rotational Self-Shrinkers in Euclidean Spaces”. International Electronic Journal of Geometry, vol. 17, no. 1, 2024, pp. 34-43, doi:10.36890/iejg.1330887.
Vancouver Arslan K, Aydın Y, Bulca Sokur B. Rotational Self-Shrinkers in Euclidean Spaces. Int. Electron. J. Geom. 2024;17(1):34-43.