
Entanglement in a solid-state spin ensemble
... interest as they possess excellent decoherence characteristics (both the electron and the nuclear coherence times, T2, exceed seconds11,12), can be controlled with high fidelity using microwave and radiofrequency pulses13,14, and are promising for integrating quantum technologies into conventional s ...
... interest as they possess excellent decoherence characteristics (both the electron and the nuclear coherence times, T2, exceed seconds11,12), can be controlled with high fidelity using microwave and radiofrequency pulses13,14, and are promising for integrating quantum technologies into conventional s ...
151c19
... wound with a total of 200 turns of wire. The solenoid is to be used to exactly cancel the Earth's magnetic field where it is 3.0x10-5 T in magnitude. What should the current in the solenoid be for its field to exactly cancel the earth’s field inside the solenoid? ...
... wound with a total of 200 turns of wire. The solenoid is to be used to exactly cancel the Earth's magnetic field where it is 3.0x10-5 T in magnitude. What should the current in the solenoid be for its field to exactly cancel the earth’s field inside the solenoid? ...
Magnetism Vocabulary Terms
... An area of magnetic attraction in the southern hemisphere near the geographic south pole. Compasses are designed to use this magnetic attraction in the south to point toward north. ...
... An area of magnetic attraction in the southern hemisphere near the geographic south pole. Compasses are designed to use this magnetic attraction in the south to point toward north. ...
Solid state quantum memory using the 31P nuclear spin
... purity using experimentally accessible magnetic fields and temperatures, the small nuclear Zeeman energy results in the nuclear spin being initially in a highly mixed thermal state. However, for the purposes of this quantum memory scheme it is not necessary to perform any pre-cooling of the nuclear- ...
... purity using experimentally accessible magnetic fields and temperatures, the small nuclear Zeeman energy results in the nuclear spin being initially in a highly mixed thermal state. However, for the purposes of this quantum memory scheme it is not necessary to perform any pre-cooling of the nuclear- ...
Introduction to Spintronics
... current in the same manner that conventional transistors can switch charge currents Using arrays of these spin transistors, MRAM will combine storage, detection, logic and communication capabilities on a single chip This will remove the distinction between working memory and storage, combining f ...
... current in the same manner that conventional transistors can switch charge currents Using arrays of these spin transistors, MRAM will combine storage, detection, logic and communication capabilities on a single chip This will remove the distinction between working memory and storage, combining f ...
A >200 meV Uphill Thermodynamic Landscape for Radical
... samples were frozen in liquid isopentane (−140 °C) at 20 s (or 1 min) and analyzed by X-band EPR spectroscopy The EPR parameters were as follows: microwave frequency 9.45 GHz; power 30 μW; modulation amplitude 1.50 G; modulation frequency 100 kHz; time constant 40.96 ms; and conversion time 20.48 ms ...
... samples were frozen in liquid isopentane (−140 °C) at 20 s (or 1 min) and analyzed by X-band EPR spectroscopy The EPR parameters were as follows: microwave frequency 9.45 GHz; power 30 μW; modulation amplitude 1.50 G; modulation frequency 100 kHz; time constant 40.96 ms; and conversion time 20.48 ms ...
NMR Slides 2.1
... n is the number of nuclear spins being observed γe is the gyromagnetic ratio of the spin being excited γd is the gyromagnetic ratio of the spin being detected B0 is the magnetic field strength t is the experiment acquisition time. Also involved in S/N are the probe filling factor (the fraction of th ...
... n is the number of nuclear spins being observed γe is the gyromagnetic ratio of the spin being excited γd is the gyromagnetic ratio of the spin being detected B0 is the magnetic field strength t is the experiment acquisition time. Also involved in S/N are the probe filling factor (the fraction of th ...
dina maizana - UniMAP Portal
... A moving electron is accompanied by a line magnetic force. Forming a complete circle ellipse. Direction of this force is parallel to the axis of spin . An electron spinning in a counter-clockwise direction. Its magnetic force clockwise when observed from the right. This direction of spin may be term ...
... A moving electron is accompanied by a line magnetic force. Forming a complete circle ellipse. Direction of this force is parallel to the axis of spin . An electron spinning in a counter-clockwise direction. Its magnetic force clockwise when observed from the right. This direction of spin may be term ...
What is a Magnetic Monopole?
... - first to suggest the existence of isolated magnetic monopoles Paul Dirac - firm theoretical grounding of magnetic monopoles in 1931 paper - quantization of electric charge is the result of the existence of isolated electric and magnetic charges. DIRAC MONOPOLE: A magnetic monopole is an isolated p ...
... - first to suggest the existence of isolated magnetic monopoles Paul Dirac - firm theoretical grounding of magnetic monopoles in 1931 paper - quantization of electric charge is the result of the existence of isolated electric and magnetic charges. DIRAC MONOPOLE: A magnetic monopole is an isolated p ...
Instructions for use Title Coulomb staircase and total spin
... those for an electron in state k in lead l (l⫽e for the emitter and l⫽c for the collector兲. The spin splitting produced by the in-plane magnetic field is reflected in the dependence of energy levels n and lk . H int is the interaction term whose explicit form is not necessary in the follow ...
... those for an electron in state k in lead l (l⫽e for the emitter and l⫽c for the collector兲. The spin splitting produced by the in-plane magnetic field is reflected in the dependence of energy levels n and lk . H int is the interaction term whose explicit form is not necessary in the follow ...
electron spin and the pauli principle
... assignments of electrons to orbitals: 1) At ground state the electrons fill the lowest energy orbitals available. 2) No orbitals can have more than two electrons. The total number of electrons at any sublevel is shown by a superscript number. Using these rules we can find the electron configuration ...
... assignments of electrons to orbitals: 1) At ground state the electrons fill the lowest energy orbitals available. 2) No orbitals can have more than two electrons. The total number of electrons at any sublevel is shown by a superscript number. Using these rules we can find the electron configuration ...
Electron paramagnetic resonance
Electron paramagnetic resonance (EPR) or electron spin resonance (ESR) spectroscopy is a technique for studying materials with unpaired electrons. The basic concepts of EPR are analogous to those of nuclear magnetic resonance (NMR), but it is electron spins that are excited instead of the spins of atomic nuclei. EPR spectroscopy is particularly useful for studying metal complexes or organic radicals. EPR was first observed in Kazan State University by Soviet physicist Yevgeny Zavoisky in 1944, and was developed independently at the same time by Brebis Bleaney at the University of Oxford.