Experiments on the Self-Organized Critical State of 4He

Experiments on the Self-Organized Critical State of 4He

When a heat flux Q is applied downward through a sample of 4He near the lambda transition, the helium self organizes such that the gradient in temperature matches the gravity-induced gradient in Tλ. All the helium in the sample is then at the same reduced temperature and the helium is said to be in...

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Veröffentlicht in:Journal of low temperature physics 2007-09, Vol.148 (5-6), p.519-526
Hauptverfasser: Chatto, A. R., Lee, R. A. M., Duncan, R. V., Goodstein, D. L.
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Sprache:eng
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Heat
Heat flux
Heat transfer
Helium
Low temperature physics
Propagation modes
Specific heat
Temperature
Temperature dependence
Thermal conductivity
Weightlessness
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container_end_page 526
container_issue 5-6
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container_title Journal of low temperature physics
container_volume 148
creator Chatto, A. R.
Lee, R. A. M.
Duncan, R. V.
Goodstein, D. L.
description When a heat flux Q is applied downward through a sample of 4He near the lambda transition, the helium self organizes such that the gradient in temperature matches the gravity-induced gradient in Tλ. All the helium in the sample is then at the same reduced temperature and the helium is said to be in the Self-Organized Critical (SOC) state. We have made the first measurements of the 4He SOC state specific heat, C∇T(T(Q)). There is no measurable difference between C∇T and the static zero-gravity 4He specific heat for temperatures between 650 and 250 nK below Tλ. Closer to Tλ, the specific heat is depressed and reaches a maximum value at 50 nK below Tλ. This depression is similar to that predicted theoretically as reported by R. Haussmann (Phys. Rev. B 60, 12349, 1999). Contrary to the expectations of theory, however, we see another depression far below Tλ. In addition, over the heat flux range of 30 nW/cm2 to 13 μW/cm2, we have made improved measurements of the speed of a recently discovered propagating thermal mode, which travels only upstream against the nominal heat flux of the SOC state. We are able to accurately predict the speed of this wave by treating the helium of SOC state as a traditional fluid with a temperature dependent thermal conductivity.
doi_str_mv 10.1007/s10909-007-9484-9
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subjects Heat
Heat flux
Heat transfer
Helium
Low temperature physics
Propagation modes
Specific heat
Temperature
Temperature dependence
Thermal conductivity
Weightlessness
title Experiments on the Self-Organized Critical State of 4He
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