We present simulations of binary black-hole mergers in which, after the common outer horizon has formed, the marginally outer trapped surfaces (MOTSs) corresponding to the individual black holes continue to approach and eventually penetrate each other. This has very interesting consequences according to recent results in the theory of MOTSs. Uniqueness and stability theorems imply that two MOTSs which touch with a common outer normal must be identical. This suggests a possible dramatic consequence of the collision between a small and large black hole. If the penetration were to continue to completion, then the two MOTSs would have to coalesce, by some combination of the small one growing and the big one shrinking. Here we explore the relati...
International audienceRecent advances in numerical relativity have revealed how marginally trapped s...
International audienceRecent advances in numerical relativity have revealed how marginally trapped s...
Recent advances in numerical relativity have revealed how marginally trapped surfaces behave when bl...
We present simulations of binary black holes mergers in which, after the common outer horizon has fo...
We present simulations of binary black holes mergers in which, after the common outer horizon has fo...
We find strong numerical evidence for a new phenomenon in a binary black hole spacetime, namely the ...
We have shown previously that a merger of marginally outer trapped surfaces (MOTSs) occurs in a bina...
In this second part of a two-part paper, we discuss numerical simulations of a head-on merger of two...
In classical numerical relativity, marginally outer trapped surfaces (MOTSs) are the main tool to lo...
Marginally outer trapped surfaces (MOTSs) are the main tool in numerical relativity to infer propert...
Recent advances in numerical relativity have revealed how marginally trapped surfaces behave when bl...
A marginally outer trapped surface (MOTS) is a quasi-local alternative to the event horizon that ca...
In binary black hole mergers and other highly dynamical spacetimes, the surface of most obvious int...
We resolve the fate of the two original apparent horizons during the head-on merger of two non-spinn...
Recent advances in numerical relativity have revealed how marginally trapped surfaces behave when bl...
International audienceRecent advances in numerical relativity have revealed how marginally trapped s...
International audienceRecent advances in numerical relativity have revealed how marginally trapped s...
Recent advances in numerical relativity have revealed how marginally trapped surfaces behave when bl...
We present simulations of binary black holes mergers in which, after the common outer horizon has fo...
We present simulations of binary black holes mergers in which, after the common outer horizon has fo...
We find strong numerical evidence for a new phenomenon in a binary black hole spacetime, namely the ...
We have shown previously that a merger of marginally outer trapped surfaces (MOTSs) occurs in a bina...
In this second part of a two-part paper, we discuss numerical simulations of a head-on merger of two...
In classical numerical relativity, marginally outer trapped surfaces (MOTSs) are the main tool to lo...
Marginally outer trapped surfaces (MOTSs) are the main tool in numerical relativity to infer propert...
Recent advances in numerical relativity have revealed how marginally trapped surfaces behave when bl...
A marginally outer trapped surface (MOTS) is a quasi-local alternative to the event horizon that ca...
In binary black hole mergers and other highly dynamical spacetimes, the surface of most obvious int...
We resolve the fate of the two original apparent horizons during the head-on merger of two non-spinn...
Recent advances in numerical relativity have revealed how marginally trapped surfaces behave when bl...
International audienceRecent advances in numerical relativity have revealed how marginally trapped s...
International audienceRecent advances in numerical relativity have revealed how marginally trapped s...
Recent advances in numerical relativity have revealed how marginally trapped surfaces behave when bl...
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