Measurement of the Sensitivity Function in a Time-Domain

... levels of the alkali atom. Three laser pulses, of durations τR , 2τR , and τR , separated in time by T , respectively split, redirect, and recombine the atomic wave packets, creating an atomic interferometer [12]. Finally, a fluorescence detection gives a measurement of the transition probability fr ...

Unraveling the Atomistic Sodiation Mechanism of

No. 1-fn.p65 - Department of Atomic Energy

Cooling and Trapping Neutral Atoms W. Ketterle, D. E. Pritchard

... Introduction and overview The observation of Bose-Einstein condensation (BEC) in dilute atomic gases in 1995 was the realization of many long-standing goals: (1) to cool neutral atoms into the ground state of the system, thus exerting ultimate control over the motion and position of atoms limited on ...

Entangling Dipole-Dipole Interactions and Quantum Logic in Optical

... natural choices: the atomic and molecular bases. In the atomic case we consider product states of internal dynamics and center of mass motion. In the molecular case we consider eigenstates of the dipole-coupled two atom Hamiltonian H = HA 1 + HA 2 + Vdd in the Born-Oppenheimer approximation. Both ba ...

Midgap states of a two-dimensional antiferromagnetic Mott

The evolution of free wave packets

Wave Mechanics - dfcd.net: Articles

... By comparing the theoretical predictions of the wave equation to the experimental data on Hydrogen’s spectrum, Schrödinger was able to further justify his hypothesis about the interpretation of the wave function ψ. However, by the end of the year this interpretation of the wave function would be ov ...

The Kitaev chain: theoretical model and experiments

Discussion with Einstein on epistemological problems in atomic

Spin-1=2 Optical Lattice Clock

... between 1 S0 atoms as the dominant shift mechanism. Founded in the Pauli exclusion principle, as two ground (1 S0 ) state atoms in the same spin state comprise a pair of identical fermions, s-wave interactions are prohibited. The atomic temperature is not sufficiently cold to rule out by itself the ...

Unifying Model for Several Classes of Two-Dimensional Phase Transition Yonatan Dubi,

... magnetic fields, electrons with Fermi energy F perform small oscillations around equipotential lines. When F is small, their trajectories are trapped inside potential valleys, with weak tunneling occurring between adjacent valleys. We associate each such potential valley with a site in a lattice. ...

IOSR Journal of Electronics and Communication Engineering (IOSR-JECE)

... By decreasing oxide layer thickness (tox) the threshold voltage is reduced in a mass MOSFET that cause leakage from the gate oxide. Therefore the connection between power utilization and operational pace is significant to obtain most favorable scaled tool. Second a MOSFET feature degrades with the l ...

The EPR Paradox

... pay back the energy in an arbitrarily short time. This suggests the tunneling velocity can be as large as you like! Blaylock - UMass HEP Seminar 2/12/10 ...

Time-Reversal-Symmetry-Broken Quantum Spin Hall Effect

Emergence of exponentially small reflected waves

Quantum Chemistry for Spectroscopy – A Tale of Three Spins (S = 0

Kondo-model for quantum-dots with spin

Department of Physics, Chemistry and Biology Master’s Thesis Cavities

... distributions of density (intensity) [6], wave transport [6][5] and stress tensor components [4]. In particular, we want to investigate the effect of net wave transport that was found experimentally, and see if a higher energy (or frequency) dampens this effect. The same kind of cavity was used in a ...

Chemistry 1 and Lab for Majors KRSN CHM1010 – Chemistry I for

... Properties of solids, liquids, and gases a. Describe the origins and relative magnitudes of intermolecular forces. b. Relate phase behavior to nature of intermolecular forces. c. Compare general properties of solids, liquids and gases; including density, compressibility, heat capacity, and randomnes ...

Advance Chemistry Outline First Semester Unit 1 (10 days) – Getting

... Ionic and covalent bonding Lewis structures for molecules Exceptions to the octet rule Molecular geometry Bond angles Resonance Hybrid orbitals Sigma and Pi bonds Polarity Intermolecular forces [Complex ions] Lab – Molecular Shapes and Polarity (ASIM) Lab – Evaporation and Intermolecular forces (ASI ...

Can Wavefunction Collapse Conserve Energy? - Philsci

test 3 practice

Mixed quantum–classical dynamics

Dynamics of a charged particle in a magnetic

... tional perturbation, since the nondegeneracy condition required by the theory is violated.5 In the presence of the magnetic field @Eqs. ~2! and ~3!# the Hamiltonian is not integrable, but for small values of B 1 the phase space motion is almost entirely on tori. Figure 1~a! shows the surface of a se ...

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Tight binding

In solid-state physics, the tight-binding model (or TB model) is an approach to the calculation of electronic band structure using an approximate set of wave functions based upon superposition of wave functions for isolated atoms located at each atomic site. The method is closely related to the LCAO method used in chemistry. Tight-binding models are applied to a wide variety of solids. The model gives good qualitative results in many cases and can be combined with other models that give better results where the tight-binding model fails. Though the tight-binding model is a one-electron model, the model also provides a basis for more advanced calculations like the calculation of surface states and application to various kinds of many-body problem and quasiparticle calculations.

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Tight binding