Implementations of Quantum Information
... evolves according to |g+|e|g+eia|e. The parameter a is random and is due to varying magnetic field strength along the ion’s path, resulting in random fluctuations in the energy separation of|g and |e. Reduce this decoherence by encoding the logical qubit as |0=|ge and |1=|eg. The lo ...
... evolves according to |g+|e|g+eia|e. The parameter a is random and is due to varying magnetic field strength along the ion’s path, resulting in random fluctuations in the energy separation of|g and |e. Reduce this decoherence by encoding the logical qubit as |0=|ge and |1=|eg. The lo ...
Dissipative decoherence in the Grover algorithm
... by the random matrix theory [10]. The two former classes are related to unitary errors. However, there is also the third class which corresponds to the case of nonunitary errors typical to the case of dissipative decoherence. This type of errors has been studied recently for the quantum baker map [1 ...
... by the random matrix theory [10]. The two former classes are related to unitary errors. However, there is also the third class which corresponds to the case of nonunitary errors typical to the case of dissipative decoherence. This type of errors has been studied recently for the quantum baker map [1 ...
A Model of Time
... and an unrealized part or the corresponding past and future. Note that the past, defined as the set of realized events, has no ”depth” yet since temporal order has not been defined. Note also, that ∆tM is e Sρ 6= Sρ . Here enters configuration dependent since mutual entropy differs for different A a ...
... and an unrealized part or the corresponding past and future. Note that the past, defined as the set of realized events, has no ”depth” yet since temporal order has not been defined. Note also, that ∆tM is e Sρ 6= Sρ . Here enters configuration dependent since mutual entropy differs for different A a ...
Phys. Rev. Lett. 108, 100501 - APS Link Manager
... where E refers to the energy of the many-body state with the qubits in state jiA jiB (Fig. 1). Within the continuum limit of a classical crystal, Eint d2 =L for d aR , where d is the distance between the qubits and the ends of the quantum bus. Owing to quantum fluctuations, the classical cry ...
... where E refers to the energy of the many-body state with the qubits in state jiA jiB (Fig. 1). Within the continuum limit of a classical crystal, Eint d2 =L for d aR , where d is the distance between the qubits and the ends of the quantum bus. Owing to quantum fluctuations, the classical cry ...
QUANTUM COMPUTING WITH SUPERCONDUCTORS I: ARCHITECTURES Michael R. Geller Andrew T. Sornborger
... where ϕ and N are operators satisfying (1). Because U depends on s, which itself depends on time, HJJ is generally time-dependent. The low lying stationary states when s . 1 are shown in Fig. 4. The two lowest eigenstates |0i and |1i are used to make a qubit. ∆ǫ is the level spacing and ∆U is the he ...
... where ϕ and N are operators satisfying (1). Because U depends on s, which itself depends on time, HJJ is generally time-dependent. The low lying stationary states when s . 1 are shown in Fig. 4. The two lowest eigenstates |0i and |1i are used to make a qubit. ∆ǫ is the level spacing and ∆U is the he ...
Quantum phase transitions in atomic gases and
... For smaller J, there can be a confinementdeconfinement transition at which the S=1/2 spinons are liberated: these are neutral, S=1/2 quasiparticles The gap to all excitations with non-zero S remains finite across this transition, but the gap to spin singlet excitations vanishes. There is no local or ...
... For smaller J, there can be a confinementdeconfinement transition at which the S=1/2 spinons are liberated: these are neutral, S=1/2 quasiparticles The gap to all excitations with non-zero S remains finite across this transition, but the gap to spin singlet excitations vanishes. There is no local or ...
Document
... • (Error probability) x #(physical gate operations per logical gate) < 1 => reduce error by hierarchically concatenating error correction codes (i.e. using th l i l bit f l l th h i l bit f th the logical qubits of on level as the physical qubits of the next higher level). t hi h l l) ...
... • (Error probability) x #(physical gate operations per logical gate) < 1 => reduce error by hierarchically concatenating error correction codes (i.e. using th l i l bit f l l th h i l bit f th the logical qubits of on level as the physical qubits of the next higher level). t hi h l l) ...