Limits on quantum deletion from no signaling principle
Aditya Jain, Indranil Chakrabarty

TL;DR
This paper establishes fundamental limits on approximate quantum deletion processes by deriving bounds based on the no signaling principle, revealing a trade-off between deletion and preservation fidelities.
Contribution
It introduces a bound on the combined fidelity of deletion and preservation using the no signaling theorem, identifying the optimal deletion fidelity under no signaling constraints.
Findings
Derives a bound on the sum of deletion and preservation fidelities.
Reveals a complementary relation between deletion and preservation fidelities.
Predicts the maximum achievable deletion fidelity for a given preservation fidelity.
Abstract
One of the fundamental restrictions that quantum mechanics imposes is the "No deletion Theorem" which tells us that given two identical unknown quantum states, it is impossible to delete one of them. But nevertheless if not perfect, people have tried to delete it approximately. In these approximate deleting processes our basic target is to delete one of the two identical copies as much as possible while preserving the other copy. In this brief report, by using the No communication theorem (NCT) (impossibility of sending signal faster than light using a quantum resource) as a guiding principle, we obtain a bound on the sum of the fidelity of deletion and the fidelity of preservation. Our result not only brings out the complementary relation between these two fidelities but also predicts the optimal value of the fidelity of deletion achievable for a given fidelity of preservation under no…
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Taxonomy
TopicsQuantum Computing Algorithms and Architecture · Molecular Communication and Nanonetworks · Quantum Mechanics and Applications
