Mukherjee Anirban, Tapader Dhiraj, Hazra Animesh, Pradhan Punyabrata
Department of Physics of Complex Systems, <a href="https://ror.org/00kz6qq24">S. N. Bose National Centre for Basic Sciences</a>, Block JD, Sector III, Salt Lake, Kolkata 700106, India.
<a href="https://ror.org/01tpvdq80">Institute of Physics, Academia Sinica</a>, Taipei 11529, Taiwan.
Phys Rev E. 2024 Aug;110(2-1):024119. doi: 10.1103/PhysRevE.110.024119.
We study the Oslo model, a paradigm for absorbing-phase transition, on a one-dimensional ring of L sites with a fixed global density ρ[over ¯]; we consider the system strictly above critical density ρ_{c}. Notably, microscopic dynamics conserve both mass and center of mass (CoM), but lack time-reversal symmetry. We show that, despite having highly constrained dynamics due to CoM conservation, the system exhibits diffusive relaxation away from criticality and superdiffusive relaxation near criticality. Furthermore, the CoM conservation severely restricts particle movement, causing the mobility-a transport coefficient analogous to the conductivity for charged particles-to vanish exactly. Indeed, the steady-state temporal growth of current fluctuation is qualitatively different from that observed in diffusive systems with a single conservation law. Remarkably, far from criticality where the relative density Δ=ρ[over ¯]-ρ_{c}≫ρ_{c}, the second cumulant, or the variance, 〈Q_{i}^{2}(T,Δ)〉{c}, of current Q{i} across the ith bond up to time T in the steady-state saturates as 〈Q_{i}^{2}〉{c}≃Σ{Q}^{2}(Δ)-constT^{-1/2}; near criticality, it grows subdiffusively as 〈Q_{i}^{2}〉{c}∼T^{α}, with 0<α<1/2, and eventually saturates to Σ_{Q}^{2}(Δ). Interestingly, the asymptotic current fluctuation Σ_{Q}^{2}(Δ) is a nonmonotonic function of Δ: It diverges as Σ_{Q}^{2}(Δ)∼Δ^{2} for Δ≫ρ_{c} and Σ_{Q}^{2}(Δ)∼Δ^{-δ}, with δ>0, for Δ→0^{+}. Using a mass-conservation principle, we exactly determine the exponents δ=2(1-1/ν{⊥})/ν_{⊥} and α=δ/zν_{⊥} via the correlation-length and dynamic exponents, ν_{⊥} and z, respectively. Finally, we show that in the steady state the self-diffusion coefficient D_{s}(ρ[over ¯]) of tagged particles is connected to activity through the relation D_{s}(ρ[over ¯])=a(ρ[over ¯])/ρ[over ¯].
我们研究了奥斯陆模型,这是一种吸收相变的范例,研究对象是一个具有固定全局密度(\overline{\rho})的(L)个格点的一维环;我们考虑的系统严格高于临界密度(\rho_{c})。值得注意的是,微观动力学既守恒质量又守恒质心(CoM),但缺乏时间反演对称性。我们表明,尽管由于质心守恒导致动力学受到高度限制,但系统在远离临界点时表现出扩散弛豫,在临界点附近表现出超扩散弛豫。此外,质心守恒严重限制了粒子运动,导致迁移率——一个类似于带电粒子电导率的输运系数——精确地消失。实际上,电流涨落的稳态时间增长在定性上与具有单一守恒定律的扩散系统中观察到的不同。值得注意的是,在远离临界点处,相对密度(\Delta=\overline{\rho}-\rho_{c}\gg\rho_{c}),在稳态下直到时间(T)穿过第(i)个键的电流(Q_{i})的二阶累积量,即方差(\langle Q_{i}^{2}(T,\Delta)\rangle_{c}),饱和为(\langle Q_{i}^{2}\rangle_{c}\simeq\Sigma_{Q}^{2}(\Delta)-constT^{-1/2});在临界点附近,它以亚扩散方式增长,即(\langle Q_{i}^{2}\rangle_{c}\sim T^{\alpha}),其中(0\lt\alpha\lt1/2),并最终饱和到(\Sigma_{Q}^{2}(\Delta))。有趣的是,渐近电流涨落(\Sigma_{Q}^{2}(\Delta))是(\Delta)的非单调函数:当(\Delta\gg\rho_{c})时,它以(\Sigma_{Q}^{2}(\Delta)\sim\Delta^{2})发散,当(\Delta\rightarrow0^{+})时,(\Sigma_{Q}^{2}(\Delta)\sim\Delta^{-\delta}),其中(\delta\gt0)。利用质量守恒原理,我们分别通过关联长度和动力学指数(\nu_{\perp})和(z)精确确定了指数(\delta = 2(1 - 1/\nu_{\perp})/\nu_{\perp})和(\alpha=\delta/z\nu_{\perp})。最后,我们表明在稳态下,标记粒子的自扩散系数(D_{s}(\overline{\rho}))通过关系(D_{s}(\overline{\rho}) = a(\overline{\rho})/\overline{\rho})与活性相关联。
