Why dynamics?
... 1. We are only beginning to understand the nature of quantum dynamics in some model systems: tip of the iceberg. 2. Many issues remain to settled: i) specific calculations a) dynamics of non-integrable systems b) correlation function and entanglement generation c) open systems: role of noise and dis ...
... 1. We are only beginning to understand the nature of quantum dynamics in some model systems: tip of the iceberg. 2. Many issues remain to settled: i) specific calculations a) dynamics of non-integrable systems b) correlation function and entanglement generation c) open systems: role of noise and dis ...
Three Interpretations for a Single Physical Reality
... mechanics established the mathematical formalism that would give rise to one of the most successful devices of experimental physics. It had been originally constructed in order to explain certain empirical inadequacies that the classical theory could not explain. The physicists of the time wanted to ...
... mechanics established the mathematical formalism that would give rise to one of the most successful devices of experimental physics. It had been originally constructed in order to explain certain empirical inadequacies that the classical theory could not explain. The physicists of the time wanted to ...
Quantum Probability Theory
... Finally, any atomic or molecular system, only two energy levels of which are of importance in the experiment, can be described by some (M2 , ϕ). ...
... Finally, any atomic or molecular system, only two energy levels of which are of importance in the experiment, can be described by some (M2 , ϕ). ...
Quantum dots
... In atoms the attractive forces are exerted by the nuclei, while in QDs – by background charges. The number of electrons in atoms can be tuned by ionization, while in QGs – by changing the confinement potential. This is similar by a replacement of nucleus by its neighbor in the periodic table. ...
... In atoms the attractive forces are exerted by the nuclei, while in QDs – by background charges. The number of electrons in atoms can be tuned by ionization, while in QGs – by changing the confinement potential. This is similar by a replacement of nucleus by its neighbor in the periodic table. ...
ADIABATIC QUANTUM COMPUTATION
... NPC problem can be adapted 13 to solve any other problem in NP. If P6=NP, then it follows that no NP-complete problem can be efficiently solved on classical computer. It is not known wheter quantum computers can be used to quickly solve all the problems in NP (although they can be used to solve some ...
... NPC problem can be adapted 13 to solve any other problem in NP. If P6=NP, then it follows that no NP-complete problem can be efficiently solved on classical computer. It is not known wheter quantum computers can be used to quickly solve all the problems in NP (although they can be used to solve some ...
Interaction- and measurement-free quantum Zeno gates for universal computation
... will immediately reveal the state information and collapse the system into either 兩1典 or 兩0典. For a decay rate ⌫, a single effective measurement duration is 4⌫−1. The effective number of measurements M eff during an interval t is therefore t / 4⌫−1 = ⌫t / 4. Equations 共5兲 and 共1兲 are in this sense e ...
... will immediately reveal the state information and collapse the system into either 兩1典 or 兩0典. For a decay rate ⌫, a single effective measurement duration is 4⌫−1. The effective number of measurements M eff during an interval t is therefore t / 4⌫−1 = ⌫t / 4. Equations 共5兲 and 共1兲 are in this sense e ...
