101 research outputs found
Quantum control of hybrid nuclear-electronic qubits
Pulsed magnetic resonance is a wide-reaching technology allowing the quantum
state of electronic and nuclear spins to be controlled on the timescale of
nanoseconds and microseconds respectively. The time required to flip either
dilute electronic or nuclear spins is orders of magnitude shorter than their
decoherence times, leading to several schemes for quantum information
processing with spin qubits. We investigate instead the novel regime where the
eigenstates approximate 50:50 superpositions of the electronic and nuclear spin
states forming "hybrid nuclear-electronic" qubits. Here we demonstrate quantum
control of these states for the first time, using bismuth-doped silicon, in
just 32 ns: this is orders of magnitude faster than previous experiments where
pure nuclear states were used. The coherence times of our states are five
orders of magnitude longer, reaching 4 ms, and are limited by the
naturally-occurring 29Si nuclear spin impurities. There is quantitative
agreement between our experiments and no-free-parameter analytical theory for
the resonance positions, as well as their relative intensities and relative
Rabi oscillation frequencies. In experiments where the slow manipulation of
some of the qubits is the rate limiting step, quantum computations would
benefit from faster operation in the hybrid regime.Comment: 20 pages, 8 figures, new data and simulation
Which Fish Should I Eat? Perspectives Influencing Fish Consumption Choices
Background: Diverse perspectives have influenced fish consumption choices
Quantum simulation of the Hubbard model with dopant atoms in silicon
In quantum simulation, many-body phenomena are probed in controllable quantum
systems. Recently, simulation of Bose-Hubbard Hamiltonians using cold atoms
revealed previously hidden local correlations. However, fermionic many-body
Hubbard phenomena such as unconventional superconductivity and spin liquids are
more difficult to simulate using cold atoms. To date the required single-site
measurements and cooling remain problematic, while only ensemble measurements
have been achieved. Here we simulate a two-site Hubbard Hamiltonian at low
effective temperatures with single-site resolution using subsurface dopants in
silicon. We measure quasiparticle tunneling maps of spin-resolved states with
atomic resolution, finding interference processes from which the entanglement
entropy and Hubbard interactions are quantified. Entanglement, determined by
spin and orbital degrees of freedom, increases with increasing covalent bond
length. We find separation-tunable Hubbard interaction strengths that are
suitable for simulating strongly correlated phenomena in larger arrays of
dopants, establishing dopants as a platform for quantum simulation of the
Hubbard model.Comment: 6 pages, 5 figures. Supplementary: 13 pages, 7 figures. New version
with some additional discussion, accepted in Nature Communication
Relaxation of a strained quantum well at a cleaved surface
Scanning probe microscopy of a cleaved semiconductor surface provides a direct measurement of the elastic field of buried, strained structures such as quantum wells or dots, but allowance must be made for relaxation at the surface. We have calculated this relaxation analytically for the exposed edge of a strained quantum well within classical elastic theory for a linear, isotropic, homogeneous medium. The surface bulges outward if the quantum well has a larger natural lattice constant and the dilation changes sign near the surface, which may enhance recombination. Results are given for a well of constant composition or an arbitrary variation along the growth direction and compared with cross-sectional scanning tunneling microscopy of InGaAs quantum wells in GaAs. Consistent values for the composition of the wells were obtained from counting In atoms, X-ray diffraction, and photoluminescence. The lattice constant on the surface and the normal relaxation were compared with the calculation. Qualitative agreement is good but the theory gives only about 80% of the observed displacement. Some of this difference can be explained by the larger size of indium atoms compared with gallium, and the different surface reconstruction and buckling behavior of InAs and GaAs (110) surfaces upon cleavag
Simple and efficient scanning tunneling luminescence detection at low-temperature
We have designed and built an optical system to collect light that is generated in the tunneling region of a low-temperature scanning tunneling microscope. The optical system consists of an in situ lens placed approximately 1.5 cm from the tunneling region and an ex situ optical lens system to analyze the emitted light, for instance, by directing the light into a spectrometer. As a demonstration, we measured tip induced photoluminescence spectra of a gold surface. Furthermore, we demonstrate that we can simultaneously record scanning tunneling microscope induced luminescence and topography of the surface both with atomic resolution
High-field magnetotransport in a two-dimensional electron gas in quantizing magnetic fields and intense terahertz laser fields
We present a combined experimental and theoretical study of interactions between two-dimensional electron gases (2DEGs) and terahertz (THz) free-electron lasers in the presence of quantizing magnetic fields. It is found both experimentally and theoretically that when an intense THz field and a quantizing magnetic field are applied simultaneously to a GaAs-based 2DEG in the Faraday geometry, a strong cyclotron resonance (CR) effect on top of the magnetophonon resonances can be observed by transport measurements at relatively high temperatures. With increasing radiation intensity and/or decreasing temperature, the peaks of the CR are broadened and split due to magnetophoton-phonon scatterin
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