Add to ORKGThe motion of a charged particle is influenced by the self-force arising from the particle\u27s interaction with its own field. In a curved spacetime, this self-force depends on the entire past history of the particle and is difficult to evaluate. As a result, all existing self-force evaluations in curved spacetime are for particles moving along a fixed trajectory. Here, for the first time, we overcome this long-standing limitation and present fully self-consistent orbits and waveforms of a scalar charged particle around a Schwarzschild black hole. © 2012 American Physical Society
The foundations are laid for the numerical computation of the actual worldline for a particle orbiti...
In an accompanying paper, we formulate two types of regularization methods to calcu-late the scalar ...
We present a practical method for calculating the local gravitational self-force (often called "radi...
We revisit the problem of computing the self-force on a scalar charge moving along an eccentric geod...
We revisit the problem of computing the self-force on a scalar charge moving along an eccentric geod...
We revisit the problem of computing the self-force on a scalar charge moving along an eccentric geod...
We study the self-force acting on a scalar charge in uniform circular motion around a Schwarzschild ...
We study the self force acting on a scalar charge in uniform circular motion around a Schwarzschild ...
We calculate the gravitational self force acting on a pointlike test particle of mass $\mu$, set in ...
We derive the explicit values of all regularization parameters (RP) for a scalar particle in an arbi...
We provide expansions of the Detweiler-Whiting singular field for a particle with a scalar field mov...
We calculate the self-force acting on a scalar particle which is falling radially into a Schwarzschi...
In an accompanying paper, we have formulated two types of regulariz_ation methods to calculate the s...
We present a practical method for calculating the local gravitational self-force (often called “radi...
The foundations are laid for the numerical computation of the actual worldline for a particle orbiti...
The foundations are laid for the numerical computation of the actual worldline for a particle orbiti...
In an accompanying paper, we formulate two types of regularization methods to calcu-late the scalar ...
We present a practical method for calculating the local gravitational self-force (often called "radi...
We revisit the problem of computing the self-force on a scalar charge moving along an eccentric geod...
We revisit the problem of computing the self-force on a scalar charge moving along an eccentric geod...
We revisit the problem of computing the self-force on a scalar charge moving along an eccentric geod...
We study the self-force acting on a scalar charge in uniform circular motion around a Schwarzschild ...
We study the self force acting on a scalar charge in uniform circular motion around a Schwarzschild ...
We calculate the gravitational self force acting on a pointlike test particle of mass $\mu$, set in ...
We derive the explicit values of all regularization parameters (RP) for a scalar particle in an arbi...
We provide expansions of the Detweiler-Whiting singular field for a particle with a scalar field mov...
We calculate the self-force acting on a scalar particle which is falling radially into a Schwarzschi...
In an accompanying paper, we have formulated two types of regulariz_ation methods to calculate the s...
We present a practical method for calculating the local gravitational self-force (often called “radi...
The foundations are laid for the numerical computation of the actual worldline for a particle orbiti...
The foundations are laid for the numerical computation of the actual worldline for a particle orbiti...
In an accompanying paper, we formulate two types of regularization methods to calcu-late the scalar ...
We present a practical method for calculating the local gravitational self-force (often called "radi...