Quantum Graph Analysis with Trapped Yb Ion Qubits
Abstract not provided.
Publications
Adiabatic quantum computing with neutral atoms
Abstract not provided.
Quantum information processing with Rydbergdressed atoms
Abstract not provided.
Adiabatic Quantum Computing with Neutral Atoms
Abstract not provided.
Adiabatic Quantum Computing with Neutral Atoms
Abstract not provided.
Neutral atoms for 2-qubit QUBO
Abstract not provided.
Biological Application of Magnetic Relaxometry with Atomic Magnetomer and SQUID Sensors
Physics in Medicine and Biology
Abstract not provided.
Atomic Magnetometer for Magnetoencephalography
Abstract not provided.
Neutral atoms for 2-qubit QUBO
Abstract not provided.
Magnetoencephalography with fiber-coupled atomic magnetometers
Abstract not provided.
Atomic magnetometer for human magnetoencephalograpy
We have developed a high sensitivity (<5 fTesla/{radical}Hz), fiber-optically coupled magnetometer to detect magnetic fields produced by the human brain. This is the first demonstration of a noncryogenic sensor that could replace cryogenic superconducting quantum interference device (SQUID) magnetometers in magnetoencephalography (MEG) and is an important advance in realizing cost-effective MEG. Within the sensor, a rubidium vapor is optically pumped with 795 laser light while field-induced optical rotations are measured with 780 nm laser light. Both beams share a single optical axis to maximize simplicity and compactness. In collaboration with neuroscientists at The Mind Research Network in Albuquerque, NM, the evoked responses resulting from median nerve and auditory stimulation were recorded with the atomic magnetometer and a commercial SQUID-based MEG system with signals comparing favorably. Multi-sensor operation has been demonstrated with two AMs placed on opposite sides of the head. Straightforward miniaturization would enable high-density sensor arrays for whole-head magnetoencephalography.
Magnetoencephalography with a two-color pump probe atomic magnetometer
The authors have detected magnetic fields from the human brain with a compact, fiber-coupled rubidium spin-exchange-relaxation-free magnetometer. Optical pumping is performed on the D1 transition and Faraday rotation is measured on the D2 transition. The beams share an optical axis, with dichroic optics preparing beam polarizations appropriately. A sensitivity of <5 fT/{radical}Hz is achieved. Evoked responses resulting from median nerve and auditory stimulation were recorded with the atomic magnetometer. Recordings were validated by comparison with those taken by a commercial magnetoencephalography system. The design is amenable to arraying sensors around the head, providing a framework for noncryogenic, whole-head magnetoencephalography.
A two-color pump probe atomic magnetometer for magnetoencephalography
Abstract not provided.
Magnetoencephalography with a two color pump-probe fiber-coupled atomic magnetometer
Applied Physics Letters
Abstract not provided.
A Microfabricated Tunable Cavity Atomic Magnetometer
Abstract not provided.
15 Results