Surface Code Quantum Computation on a Defective
... small scale quantum computers with only a few qubits cannot process large programs. For example, processing Shor’s algorithm to factor a number represented with 2048 bits needs 105 near-perfect qubits [5]. Many architectures have been proposed for a scalable quantum computer. Their feasibility depen ...
... small scale quantum computers with only a few qubits cannot process large programs. For example, processing Shor’s algorithm to factor a number represented with 2048 bits needs 105 near-perfect qubits [5]. Many architectures have been proposed for a scalable quantum computer. Their feasibility depen ...
Synchronization and Sensing with Steady State
... behavior of the two oscillators in response to the introduction of controllable phase errors between them in both transient and steady state experiments. This work may stimulate future studies of quantum phase transitions in open quantum systems. Finally, I discuss progress in another related experi ...
... behavior of the two oscillators in response to the introduction of controllable phase errors between them in both transient and steady state experiments. This work may stimulate future studies of quantum phase transitions in open quantum systems. Finally, I discuss progress in another related experi ...
Phy CH 06 momentum - Milton-Union Exempted Village Schools
... 1. A 0.50 kg football is thrown with a velocity of 15 m/s to the right. A stationary receiver catches the ball and brings it to rest in 0.020 s. What is the force exerted on the ball by the receiver? 2. An 82 kg man drops from rest on a diving board 3.0 m above the surface of the water and comes to ...
... 1. A 0.50 kg football is thrown with a velocity of 15 m/s to the right. A stationary receiver catches the ball and brings it to rest in 0.020 s. What is the force exerted on the ball by the receiver? 2. An 82 kg man drops from rest on a diving board 3.0 m above the surface of the water and comes to ...
MOMENTUM
... isolated: There is a net external force on the system—the friction force of the floor on your feet—to keep you from moving backward that changes the momentum of the system. If the ball-you system is isolated (say you are on frictionless ice), then you do move backward when you pass the ball. Assess: ...
... isolated: There is a net external force on the system—the friction force of the floor on your feet—to keep you from moving backward that changes the momentum of the system. If the ball-you system is isolated (say you are on frictionless ice), then you do move backward when you pass the ball. Assess: ...
Quantum Information Processing with
... Yale University in Candidacy for the Degree of Doctor of Philosophy ...
... Yale University in Candidacy for the Degree of Doctor of Philosophy ...
Quantum Physics of Atoms, Molecules, Solids, Nuclei, and Particles
... courses (and also from some that we knew were not, in order to determine their objections to the book). The wide acceptance of the first edition made it possible for us to obtain a broad sampling of thought concerning ways to make the second edition more useful. We were not able to act on all the su ...
... courses (and also from some that we knew were not, in order to determine their objections to the book). The wide acceptance of the first edition made it possible for us to obtain a broad sampling of thought concerning ways to make the second edition more useful. We were not able to act on all the su ...
Lectures on the Geometry of Quantization
... Ĥ. As soon as we wish to “quantize” a more complicated energy function, such as (1 + q 2 )p2 , we run in to the problem that the operators q̂ and p̂ do not commute with one another, so that we are forced to choose between (1 + q̂ 2 )p̂2 and p̂2 (1 + q̂ 2 ), among a number of other possibilities. Th ...
... Ĥ. As soon as we wish to “quantize” a more complicated energy function, such as (1 + q 2 )p2 , we run in to the problem that the operators q̂ and p̂ do not commute with one another, so that we are forced to choose between (1 + q̂ 2 )p̂2 and p̂2 (1 + q̂ 2 ), among a number of other possibilities. Th ...
Chapter 19 Angular Momentum
... 19.5 Angular Impulse and Change in Angular Momentum ................................... 12 19.6 Angular Momentum of a System of Particles .................................................. 13 Example 19.5 Angular Momentum of Two Particles undergoing Circular ...
... 19.5 Angular Impulse and Change in Angular Momentum ................................... 12 19.6 Angular Momentum of a System of Particles .................................................. 13 Example 19.5 Angular Momentum of Two Particles undergoing Circular ...
Ultrafast Electron and Molecular Dynamics in Photoinduced and
... Among the three classes of PIPTs, those in class II in particular show a variety of electron, spin, and lattice dynamics. A prototypical example of this category of PIPTs is a photoinduced transition between the neutral phase and the ionic phase observed in TTF-CA (tetrathiafluvalene-p-chloranil). T ...
... Among the three classes of PIPTs, those in class II in particular show a variety of electron, spin, and lattice dynamics. A prototypical example of this category of PIPTs is a photoinduced transition between the neutral phase and the ionic phase observed in TTF-CA (tetrathiafluvalene-p-chloranil). T ...
Coupling ultracold atoms to mechanical oscillators
... resulting in a strong reduction of the coupling rate. Next, g0 scales with the resonance frequency, which is limited by the experimentally achievable curvature of the atomic trapping potential. While magnetic microtraps and optical lattices can reach ωa /2π ∼ 1 MHz [87, 88], ion traps have reached u ...
... resulting in a strong reduction of the coupling rate. Next, g0 scales with the resonance frequency, which is limited by the experimentally achievable curvature of the atomic trapping potential. While magnetic microtraps and optical lattices can reach ωa /2π ∼ 1 MHz [87, 88], ion traps have reached u ...