Progress in Applied Mathematics

In  this  paper, we  consider the dynamical behavior of the nonclassical diffusion equation when nonlinearity is critical for both two cases: the forcing term belongs to H −1 (Ω) and L2 (Ω). For the case the forcing term only belongs to H −1 (Ω), based on the asymptotic regularity in Dynamical Systems: An International  Journal, 26 (4), (2011), 391–400, we prove  the existence of exponential attractors in weak topological space H 1 (Ω). For the case the forcing term belongs to L2 (Ω), we prove the asymptotic regularity of the solutions and exponential attractors.

[1] Aifantis, E. C. (1980). On the problem of di_usion in solids. Acta Mech., 37, 265-296.

[2] Lions, J. L., & Magenes, E. (1972). Non-homogeneous boundary value problems and applications.

Spring-verlag: Berlin.

[3] Kuttler, K., & Aifantis, E. C. (1987). Existence and uniqueness in nonclassical diffusion. Quart. Appl.

Math., 45, 549-560.

[4] Kuttler, K., & Aifantis, E. C. (1988). Quasilinear evolution equations in nonclassical diffusion. SIAM J.

Math. Anal., 19, 110-120.

[5] Aifantis, E. C. (2011). Gradient nanomechanics: Applications to deformation, fracture, and diffusion in

nanopolycrystals. Metall. Mater. Trans., A42, 2985-2998.

[6] Kalantarov, V. K. (1986). On the attractors for some non-linear problems of mathematical physics. Zap.

Nauch. Sem. LOMI, 152, 50-54.

[7] Xiao, Y. L. (2002). Attractors for a nonclassical di_usion equation. Acta Math. Appl. Sinica., 18,

273-276.

[8] Sun, C. Y., Wang, S. Y., & Zhong, C. K. (2007). Global attractors for a nonclassical di_usion equation.

Acta Math. Sinica, English Series., 23, 1271-1280.

[9] Ma, Q. Z., & Zhong, C. K. (2004). Global attractors of strong solutions to nonclassical diffusion

equations. Journal of Lanzhou University, 40, 7-9.

[10] Wang, S. Y., Li, D. S., & Zhong, C. K. (2006). On the dynamics of a class of nonclassical parabolic

equations. J. Math. Anal. Appl., 317, 565-582.

[11] Temam, R. (1997). In_nite-dimensional dynamical systems in mechanics and physic. New York: Springer.

[12] Sun, C. Y., & Yang, M. H. (2008). Dynamics of the nonclassical di_usion equations. Asymptot. Anal., 59, 51-81.

[13] Liu, Y. F., & Ma, Q. Z. (2009). Exponential attractors for a nonclassical diffusion equation. Electronic Journal of

Differential Equations, 9, 1-9.

[14] Ma, Q. Z., Liu, Y. F., & Zhang, F. H. (2012). Global attractors in H1(RN) for nonclassical di_usion equations.

Discrete Dynamics in Nature and Society, 1-17. doi:10.1155/2012/672762.

[15] Wu, H. Q., & Zhang, Z. Y. (2011). Asymptotic regularity for the nonclassical diffusion equation with lower

regular forcing term. Dynamical Systems: An International Journal, 26 (4), 391-400.

[16] Zhao, T. G., Wu, Y. J., & Ma, H. P. (2012). Error analysis of Chebyshev-Legendre pseudo-spectral method for a

class of nonclassical parabolic equation. Journal of Scientiffic Computing, 52 (3), 588-602.

[17] Zhao, T. G., Wu, Y. J., & Ma, H. P. (2010). Chebyshev-Legendre pseudospectral method for nonclassical

parabolic equation. Journal of Information and Computational Science, 7 (8), 1809-1817.

[18] Sun, C. Y. (2010). Asymptotic regularity for some dissipative equations. Journal of Differential Equations, 248

(2), 342-362.

[19] Miranville, A., & Zelik, S. Attractors for dissipative partial differential equations in bounded and unbounded

domains (Handbook of Differential Equations, Evolutionary Partial Differential Equations, C. M. Dafermos &

M. Pokorny eds.). Amsterdam: Elsevier.

[20] Zelik, S. V. (2004). Asymptotic regularity of solutions of a nonautonomous damped wave equation with a critical

growth exponent. Comm. Pure Appl.Anal., 3, 921{934.

[21] Zhang, F. H., & Liu, Y. F. (2014). Pullback attractors in H1(RN) for nonautonomous nonclassical di_usion

equations. Dynamical Systems, 29 (1), 106-118.

[22] Pan, L. X., & Liu, Y. F. (2013). Robust exponential attractors for the nonautonomous nonclassical di_usion

equation with memory. Dynamical Systems, 28 (4), 501-517.