Huizhong Xu

Decoherence in a Josephson-junction qubit

The zero-voltage state of a Josephson junction biased with constant current consists of a set of metastable quantum energy levels. We probe the spacings of these levels by using microwaves to induce transitions and thereby enhance the escape rate to the voltage state. The widths of the resonances give a measurement of the spectroscopic coherence time of the two metastable states involved in the transitions. We observe a decoherence time shorter than that expected from dissipation alone in resonantly isolated 20×5 μm 2 area Al/AlOx/Al junctions at 60 mK. The data are well fit by a model that includes the dephasing effects of both low-frequency current noise and the escape rate to the voltage state. We discuss implications for quantum computation using current-biased Josephson-junction qubits, including limits on the minimum number of levels needed in the well.

Spectroscopy of three-particle entanglement in a macroscopic superconducting circuit.

We study the quantum mechanical behavior of a macroscopic, three-body, superconducting circuit. Microwave spectroscopy on our system, a resonator coupling two large Josephson junctions, produced complex energy spectra well explained by quantum theory over a large frequency range. By tuning each junction separately into resonance with the resonator, we first observe strong coupling between each junction and the resonator. Bringing both junctions together into resonance with the resonator, we find spectroscopic evidence for entanglement between all 3 degrees of freedom and suggest a new method for controllable coupling of distant qubits, a key step toward quantum computation.

Capacitively coupled Josephson junctions: A two-qubit system

We describe how single Josephson junctions can be connected together capacitively to form a two-qubit system. We discuss the general behavior of this system show the energy level dependence on various junction parameters and choice of coupling strengths. We also discuss measurement techniques for reading out both qubits which are relevant to our ongoing experiments.

Cooper-pair box as a variable capacitor

We calculate the effective capacitance of a Cooper-pair box and demonstrate that the Cooper-pair box can be used as a variable capacitor. The gate voltage modulates the charge transfer through the small junction in the Cooper-pair box, leading to a gate-dependent capacitance. We describe ongoing experiments to use an Al/AlO/sub x//Al Cooper-pair box as a tunable circuit element at milli-Kelvin temperatures and discuss possible applications to quantum computing as a variable coupling element between two Josephson junction qubits.

Characterization of an LC-isolated Josephson junction qubit

The energy states of a well-isolated hysteretic Josephson junction in the phase regime can be used as a qubit. The state of the junction can be determined by measuring when the junction switches from the zero-voltage (qubit) state to the running voltage state, since different levels have different switching rates. The experimental challenge is to provide sufficient electrical isolation of the junction from wires that must be attached to provide bias current and to measure switching events. This isolation must be effective at frequencies around the energy level spacing, in our case from 3-8 GHz. We report on the design and measurement of isolated moderate-to-high-Q junctions using a resonant isolation scheme of a series inductance and capacitive shunt. Microwave activation measurements of the Al-AlO/sub x/-Al junctions at 70 mK were used to gauge the isolation effectiveness and to show the effect of current noise from the isolation resonance on the junction coherence.

Modulation of transmission through isolated subwavelength apertures by dielectric filling and its implications for use in biophysical research

Use of finite element method to study transmission through dielectric-filled subwavelength apertures shows that a small change in the filling refractive index can induce a large change in light transmission for certain subwavelength aperture radii.

Analysis of energy level quantization and tunneling from the zero-voltage state of a current-biased Josephson junction

We examine resonant activation from the zero-voltage state of a current-biased Josephson junction in the limit of low damping. In this limit, the quantum dynamics of a Josephson junction can be described by a master equation. Our finite temperature analysis includes transitions between any two levels in the potential well and accounts for escape near the top of the well. Our results show that energy level quantization in lightly damped junctions should be observable even for temperatures in the thermal regime, where only classical behavior is observed for junctions with moderate damping. Finally we discuss implications for ongoing experiments in quantum computation.

Energy Properties of Single Helium Atom in Metals by Effective-Medium Theory

A simpler and refined version of effective-medium theory is adopted to calculate the fundamental energy properties of single helium atom in some metals. In this version, the relaxation effects of lattice have been taken into account. The calculated results of some typical energy values agree well with available experimental and other theoretical values.