Research output: Contribution to Journal/Magazine › Journal article › peer-review
Research output: Contribution to Journal/Magazine › Journal article › peer-review
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TY - JOUR
T1 - Field emission and field ionization in liquid 4He.
AU - Phillips, A.
AU - McClintock, Peter V. E.
PY - 1975/4/10
Y1 - 1975/4/10
N2 - Spacecharge limited field emission and field ionization currents in liquid 4He have been investigated for emitter potentials Vs, temperatures T, and pressures p in the ranges 0 < Vs < 3500 V, 0.3 < T < 5 K, 1 < P < 25 x 10^5 Pa, respectively. In each case, for constant p and Vs, the current i passes through a maximum at a temperature Tmax near 1.5K. For T> Tmax it is possible to account for the characteristics on the basis of a simple theory which does not require a detailed knowledge of the current generating mechanisms, and which enables values of the ionic mobilities P± to be deduced from the data. The rapid decrease in i below Tmax is ascribed to a process in which ions become trapped on quantized vortices and subsequently escape again. A model is developed to enable values of the ionic escape probabilities to be derived from the experimental results. It was found that the current becomes temperature independent below 0.4 K. The low temperature i(Vs) characteristics suggest that an effective mobility can be defined to describe ionic motion through a self generated vortex tangle. The negative ion current for T < 0.9 K showed a rapid increase with pressure for p > 106 Pa. This behaviour is ascribed to the presence of an increasing proportion of free ions travelling at the Landau velocity, owing to a decrease with p of the vortex nucleation probability nu; and a model is developed to enable values of nu to be deduced from the experimental data. The conduction mechanism below 0.7 K is discussed, but is not understood in detail. It is inferred that Vinen's F2 parameter becomes temperature independent below 0.4 K
AB - Spacecharge limited field emission and field ionization currents in liquid 4He have been investigated for emitter potentials Vs, temperatures T, and pressures p in the ranges 0 < Vs < 3500 V, 0.3 < T < 5 K, 1 < P < 25 x 10^5 Pa, respectively. In each case, for constant p and Vs, the current i passes through a maximum at a temperature Tmax near 1.5K. For T> Tmax it is possible to account for the characteristics on the basis of a simple theory which does not require a detailed knowledge of the current generating mechanisms, and which enables values of the ionic mobilities P± to be deduced from the data. The rapid decrease in i below Tmax is ascribed to a process in which ions become trapped on quantized vortices and subsequently escape again. A model is developed to enable values of the ionic escape probabilities to be derived from the experimental results. It was found that the current becomes temperature independent below 0.4 K. The low temperature i(Vs) characteristics suggest that an effective mobility can be defined to describe ionic motion through a self generated vortex tangle. The negative ion current for T < 0.9 K showed a rapid increase with pressure for p > 106 Pa. This behaviour is ascribed to the presence of an increasing proportion of free ions travelling at the Landau velocity, owing to a decrease with p of the vortex nucleation probability nu; and a model is developed to enable values of nu to be deduced from the experimental data. The conduction mechanism below 0.7 K is discussed, but is not understood in detail. It is inferred that Vinen's F2 parameter becomes temperature independent below 0.4 K
U2 - 10.1098/rsta.1975.0026
DO - 10.1098/rsta.1975.0026
M3 - Journal article
VL - 278
SP - 271
EP - 310
JO - Philosophical Transactions of the Royal Society of London A
JF - Philosophical Transactions of the Royal Society of London A
SN - 0264-3820
IS - 1281
ER -