DOI: 10.1515/zna-2025-0378 ISSN: 0932-0784

Polarization- and self-gravity-modulated nonlinear periodic waves in superthermal dusty plasmas

Laiba Iqbal, Arshad Majid Mirza, Bilal Ramzan, Muhammad S. Anjum

Abstract

This paper investigates dust-acoustic waves in a polarized, self-gravitating dusty plasma with kappa-distributed superthermal ions. We resolve the longstanding degeneracy in the common Ψ = ΓΦ assumption by demonstrating that polarization and self-gravity, though mathematically coupled, exert physically distinct influences on wave dynamics. Linear analysis reveals that polarization actively suppresses wave propagation, while self-gravity controls Jeans instability thresholds; their competition creates tunable stability boundaries scalable with plasma parameters. Through reductive perturbation theory, we derive a gravitationally modified Korteweg–de Vries equation whose coefficients explicitly depend on polarization strength R , self-gravity parameter (Γ), and ion superthermality κ i . Analytical solutions obtained via the ( g ′/ g ) expansion method yield a spectrum of coherent structures, including bright solitons, kinks, and singular waves. The joint modification of wave propagation arises from a scale-dependent competition: self-gravity acts as a long-range attractive force that reduces phase velocity and fosters clumping, while the polarization force provides a repulsive correction sensitive to plasma gradients. The physical mechanism is driven by ion superthermality; a lower spectral index κ i provides a more energetic ion population that more easily deforms the Debye shielding cloud around dust grains, thereby strengthening the polarization force and intensifying nonlinear steepening. Strong ion superthermality (lower κ i ) amplifies both mechanisms by increasing the polarization coefficients

c κ 1 ${c}_{{\kappa }_{1}}$
,
c κ 2 ${c}_{{\kappa }_{2}}$
and reducing the effective Jeans length, thereby promoting the formation of persistent, macroscopic structures. These results provide a unified mechanism to explain transient “spokes” in Saturn’s rings and initial dust clumping in protoplanetary disks, bridging grain-scale interactions to collective astrophysical phenomena.

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