Comisso-Asenjo Mechanism in Rotating N=2,U(1)2 Gauged Supergravity Black Holes: Extended Comparison With Kerr Black Hole

Abstract

In this paper, we investigate energy extraction via the Comisso-Asenjo (CA) magnetic reconnection process near a coupled N=2,\,U(1)2 gauged supergravity Black Hole (BH). Our study focuses on the combined impact of the independent parameter set pi∈(Ng,g,v,e) with the spin parameter a on the extracted energy (ε), efficiency (η), and extracted power (PCA), aiming to identify optimal combinations where energy can be extracted with higher efficiency in certain cases at lower spin (a0.39) than the Kerr extremal case (a1). Using the spacetime parameters, we explore various cases leading to distinct spacetimes and provide an extended comparison with the Kerr Black Hole (KBH). We also examine the influence of the orientation angle (ξ) and magnetization parameter (σ0) on both efficiency and extracted power. Investigating low [\,∀ pi<0.2 Ng<0.08\,], mid [\,∃ pi0.5 Ng∈(0.08,0.15)\,], high [\,∃ pi>0.7 Ng∈(0.16,0.23)\,], and mixed [\,∀ pi∈(0,1) Ng∈(0,0.23)\,] parameter combinations, we explore only extremal cases for all spacetime parameters and demonstrate that the extremal Kerr efficiency limit (η>1.495) can be exceeded. The statistical Kendall's Tau approach allows us to identify the key independent parameters acting as boosters or dampers in the energy extraction process and to visualize the relationship between (Ng,g,v,e) and the physical outputs (a ext,rE,r ergo,ε,η,PCA,Rη,RP). Furthermore, we show that the observable Lundquist number S obs in rotating BH spacetimes acquires an observer-dependent angular dependence through the lapse function (α). This leads to deviations from the standard Sweet-Parker scaling when expressed in terms of observable quantities.