Fluctuations in dc SQUIDs: Quantum Noise Effects, Low Frequency Noise, and Single Electron Trapping

Wakai, Ronald Tatsuya

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https://hdl.handle.net/2142/77409 Copy

Description

Title

Fluctuations in dc SQUIDs: Quantum Noise Effects, Low Frequency Noise, and Single Electron Trapping

Author(s)

Wakai, Ronald Tatsuya

Issue Date

1987

Department of Study

Physics

Discipline

Physics

Degree Granting Institution

University of Illinois at Urbana-Champaign

Degree Name

Ph.D.

Degree Level

Dissertation

Date of Ingest

2015-05-13T15:41:57Z

Keyword(s)

Physics, Condensed Matter

Language

eng

Abstract

We have studied the signal and noise properties of extremely sensitive dc SQUIDs composed of submicron area tunnel junctions. At high frequencies, the flux resolution is expected to be limited by intrinsic quantum fluctuations, making these devices prime candidates for ideal quantum-limited detectors. The observed signal properties are excellent and a minimum for energy resolution of 1.6$\hbar$ was measured at 1.5K, the lowest value reported to date. At low frequencies, we observe broad, Lorentzian features superimposed on a background which is always much flatter than 1/f ($\sim {\rm f}\sp{-2/3}$). When these features are strongest, the real-time voltage noise displays discrete switching behavior which results from the trapping and untrapping of single electrons into localized defect states residing within the tunneling barrier. The weak temperature of the trap lifetimes reveals that the trapping process displays tunneling kinetics. In contrast, the voltage bias dependence of the lifetimes is consistent with a simple nonequilibrium model in which the bias strongly enhances the rate for electrons to tunnel in from one side of the barrier and exit out the other side. Some junctions show clear evidence of interactions between traps, and for certain bias conditions, the noise displays predominantly series kinetics. These observations show that the low frequency noise in this system cannot always be described by a simple parallel kinetics model composed of independent fluctuators.

Graduation Semester

1987

Type of Resource

text

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http://hdl.handle.net/2142/77409

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