Silicon is more than the dominant material in the conventional microelectronics industry: it also has potential as a host material for emerging quantum information technologies. Standard fabrication techniques already allow the isolation of single electron spins in silicon transistor-like devices. Although this is also possible in other materials, silicon-based systems have the advantage of interacting more weakly with nuclear spins. Reducing such interactions is important for the control of spin quantum bits because nuclear fluctuations limit quantum phase coherence, as seen in recent experiments in GaAs-based quantum dots. Advances in reducing nuclear decoherence effects by means of complex control still result in coherence times much shorter than those seen in experiments on large ensembles of impurity-bound electrons in bulk silicon crystals. Here we report coherent control of electron spins in two coupled quantum dots in an undoped Si/SiGe heterostructure and show that this system has a nuclei-induced dephasing time of 360 nanoseconds, which is an increase by nearly two orders of magnitude over similar measurements in GaAs-based quantum dots. The degree of phase coherence observed, combined with fast, gated electrical initialization, read-out and control, should motivate future development of silicon-based quantum information processors.
Abstract:Silicon is vital to the computing industry due to the high quality of its native oxide and well-established doping technologies. Isotopic purification has enabled quantum coherence times on the order of seconds, thereby placing silicon at the forefront of efforts to create a solid state quantum processor. We demonstrate strong coupling of a single electron in a silicon double quantum dot to the photonic field of a microwave cavity, as shown by the observation of vacuum Rabi splitting. Strong coupling of a quantum dot electron to a cavity photon would allow for long-range qubit coupling and the long-range entanglement of electrons in semiconductor quantum dots.
We demonstrate double quantum dots fabricated in undoped Si/SiGe
heterostructures relying on a double top-gated design. Charge sensing shows
that we can reliably deplete these devices to zero charge occupancy.
Measurements and simulations confirm that the energetics are determined by the
gate-induced electrostatic potentials. Pauli spin blockade has been observed
via transport through the double dot in the two electron configuration, a
critical step in performing coherent spin manipulations in Si.Comment: 4 pages, 4 figure
We have demonstrated few-electron quantum dots in Si/SiGe and InGaAs, with
occupation number controllable from N = 0. These display a high degree of
spatial symmetry and identifiable shell structure. Magnetospectroscopy
measurements show that two Si-based devices possess a singlet N =2 ground state
at low magnetic field and therefore the two-fold valley degeneracy is lifted.
The valley splittings in these two devices were 120 and 270 {\mu}eV, suggesting
the presence of atomically sharp interfaces in our heterostructures.Comment: 3 pages, 3 figure
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