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**Harvard**

Tornberg, L. (2007) *Read-out of superconducting qubits - a quantum measurement process*. Göteborg : Chalmers University of Technology (Technical report MC2 - Department of Microtechnology and Nanoscience, Chalmers University of Technology, nr: 1652).

** BibTeX **

@book{

Tornberg2007,

author={Tornberg, Lars},

title={Read-out of superconducting qubits - a quantum measurement process},

abstract={In this work we consider measurements on quantum systems emphasizing
on read-out of superconducting qubits. The qubit is always coupled to an
environment, containing a macroscopic number of degrees of freedom. This
perturbs the qubit and destroys the phase coherence of the quantum state.
One tries to minimize this destructive effect by encoding the quantum information in quantum states which do not couple strongly to the dominant
noise sources. It is therefore necessary to design read-out methods that can
distinguish these states.
We focus primarily on the single Cooper-pair box (SCB) charge qubit, whose
properties are based on the Josephson effect and Coulumb blockade in superconducting electrical circuits. By encoding the information in the qubit
energy eigenstates, it is possible to protect it from the most dangerous decoherence source - charge fluctuations in the environment. We investigate
the measurement setup, where the SCB is coupled to a lumped element LCoscillator whose resonance frequency is orders of magnitude smaller than the qubit energy splitting. In this regime the SCB will act as an effective positive or negative capacitance, depending on the quantum state. This quantum capacitance then shifts the oscillator resonance frequency, which can be detected in a homodyne phase measurement.
We have found that reading out a charge qubit by measuring its quantum
capacitance in this manner is quantum limited, independently of the oscillator
quality factor Q. Moreover, we have found that the low-Q oscillator
is advantageous for the measurement in two ways: first, such an oscillator
better protects the qubit from thermal dephasing, and, second, it allows to
increase the speed of the read-out, making it possible to distinguish the qubit states in a single shot measurement.},

publisher={Institutionen för mikroteknologi och nanovetenskap, Chalmers tekniska högskola,},

place={Göteborg},

year={2007},

series={Technical report MC2 - Department of Microtechnology and Nanoscience, Chalmers University of Technology, no: 1652},

keywords={quatum computing, quantum measurements, superconducting qubits, quantum electrical circuits, single Cooper Pair box},

note={37},

}

** RefWorks **

RT Dissertation/Thesis

SR Print

ID 67283

A1 Tornberg, Lars

T1 Read-out of superconducting qubits - a quantum measurement process

YR 2007

AB In this work we consider measurements on quantum systems emphasizing
on read-out of superconducting qubits. The qubit is always coupled to an
environment, containing a macroscopic number of degrees of freedom. This
perturbs the qubit and destroys the phase coherence of the quantum state.
One tries to minimize this destructive effect by encoding the quantum information in quantum states which do not couple strongly to the dominant
noise sources. It is therefore necessary to design read-out methods that can
distinguish these states.
We focus primarily on the single Cooper-pair box (SCB) charge qubit, whose
properties are based on the Josephson effect and Coulumb blockade in superconducting electrical circuits. By encoding the information in the qubit
energy eigenstates, it is possible to protect it from the most dangerous decoherence source - charge fluctuations in the environment. We investigate
the measurement setup, where the SCB is coupled to a lumped element LCoscillator whose resonance frequency is orders of magnitude smaller than the qubit energy splitting. In this regime the SCB will act as an effective positive or negative capacitance, depending on the quantum state. This quantum capacitance then shifts the oscillator resonance frequency, which can be detected in a homodyne phase measurement.
We have found that reading out a charge qubit by measuring its quantum
capacitance in this manner is quantum limited, independently of the oscillator
quality factor Q. Moreover, we have found that the low-Q oscillator
is advantageous for the measurement in two ways: first, such an oscillator
better protects the qubit from thermal dephasing, and, second, it allows to
increase the speed of the read-out, making it possible to distinguish the qubit states in a single shot measurement.

PB Institutionen för mikroteknologi och nanovetenskap, Chalmers tekniska högskola,

T3 Technical report MC2 - Department of Microtechnology and Nanoscience, Chalmers University of Technology, no: 1652

LA eng

OL 30