Examples of 'decoherence' in a sentence
Meaning of "decoherence"
Decoherence: a term used in quantum mechanics to describe the loss of coherence between components of a quantum system
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- Loss of quantum coherence (phase relation between the quantum states of particles) in a physical system as it interacts with its environment.
- The normal condition of sensitiveness in a coherer; reversion to such condition.
How to use "decoherence" in a sentence
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decoherence
This decoherence effect can be very fast.
Luthor has solved the decoherence problem.
Decoherence in the measuring device is enough.
The subspaces of such eigenstates are free of decoherence.
Modern methods of decoherence are relevant to an analysis of this limit.
This leads us to a brief overview of decoherence.
Decoherence does not generate actual wave function collapse.
It results from decoherence through observation.
Open quantum systems and decoherence.
Decoherence happens faster as more particles are added to the system.
Struggling with the decoherence equation.
One of the biggest challenges is to remove quantum decoherence.
Long relevant decoherence times.
Breakdown of that state is called decoherence.
The theory of decoherence goes beyond the idea of superposition of states.
See also
Researchers discover a way to avoid decoherence in a quantum system.
Decoherence is measured by the degree of entanglement with the environment.
The obtained decoherence time i.
Decoherence in qubit systems falls into two general categories.
This is because of quantum decoherence.
Decoherence keeps us separate.
State superposition and decoherence.
This reveals the decoherence which is not refocused by the π pulse.
This protocol can also be envisioned to probe decoherence mechanisms.
We will study the formalism of decoherence and look at several approaches to decoherence.
This is called quantum decoherence.
And the chances for decoherence increase with the density of the material.
There is a very interesting concept in quantum mechanics referred to as decoherence.
Such an approach allows to describe decoherence in perturbed entangled quantum systems.
The density matrix is also a crucial tool in quantum decoherence theory.
In this work we study the decoherence mechanisms between the levels in an atomic system.
The transition from a pure state to a mixed state is known as decoherence.
We study the control hampered by the decoherence and relaxation effects.
It is hoped that they can be used to make a quantum computer resistant to decoherence.
Decoherence is a potential limiting factor to the maximum effective range of an operational quantum radar.
This is known as decoherence.
Decoherence occurs when a system interacts with its environment in a thermodynamically irreversible way.
The ability to transmit the flying qubit without decoherence is major problem.
Quantum decoherence ensures that the different outcomes have no interaction with each other.
The latter formalism is useful to take into account dissipation and decoherence.
The presence of noise induces decoherence and degrades the quantum correlations of these states.
Quantum theory itself provides the means of correcting errors caused by decoherence.
They were able to verify empirically the theory of decoherence through entanglement with the environment.
The emphasis is on understanding the broader meaning of the consistency and decoherence.
Decoherence refers to mechanisms that cause transfer of information from a quantum system to its bath.
The claims of quantum biology therefore stand or fall on the precise decoherence timescale.
The decoherence effects are also discussed alongside with certain proposals to alleviate their effects.
The most severe factor limiting the implementation of larger systems of qubits is decoherence.
In a second part I study the decoherence of primordial density fluctuations.
Many closely related phenonema are treated such as response matrix analysis or beam decoherence.
