Abstract

A resonant circuit tuned to a particular frequency of the motion of charged particles stored in a Penning trap and connected to a low noise amplifier allows, at the same time, cooling and non destructive detection of the particles. Its use is widely diffused when single or few particles are stored near the centre of a hyperbolic Penning trap. We present a consistent model that predicts the shape of the induced signal when the tuned circuit is used to detect and cool the axial motion of a cold non neutral plasma stored in an open-ended cylindrical Penning trap. The model correctly accounts for the not negligible axial plasma size. We show that the power spectrum of the signal measured across the tuned circuit provides information about the particle number and insights about the plasma temperature. We report on the design of a HEMT-based cryogenic amplifier working at 14.4 MHz and 4.2 K and the results of the noise measurements. We have measured a drain current noise in the range from 6 to 17 pA/√Hz, which corresponds to an increase of the tuned circuit equivalent temperature of at maximum 0.35 K. The cryogenic amplifier has a very low power consumption from few tens to few hundreds of μW corresponding to a drain current in the range 100–800 μ A. An additional contribution due to the gate noise has been identified when the drain current is below 300 μA; above that value an upper limit of the increase of the equivalent tuned circuit temperature due to this contribution of 0.02 K has been obtained. These features make the tuned circuit connected to this amplifier a promising device for detecting and cooling the axial motion of an electron plasma when the Penning trap is mounted inside a dilution refrigerator.

Highlights

  • A resonant circuit tuned to a particular frequency of the motion of charged particles stored in a Penning trap and connected to a low noise amplifier allows, at the same time, cooling and non destructive detection of the particles

  • We present a consistent model that predicts the shape of the induced signal when the tuned circuit is used to detect and cool the axial motion of a cold non neutral plasma stored in an open-ended cylindrical Penning trap

  • These features make the tuned circuit connected to this amplifier a promising device for detecting and cooling the axial motion of an electron plasma when the Penning trap is mounted inside a dilution refrigerator

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Summary

Detection of low number of particles in a Penning trap

A particle confined in a Penning trap induces charges on the surrounding electrodes and its motion creates a time-varying current through a circuit connected to them. The capacitance Ct is usually dominated by the trap electrode capacitance and the cable connections In this way the on-resonance impedance of the circuit is purely resistive. We have a series rsLtCt circuit with an input current induced by the trapped particles The noise of this detection technique originates mainly from the amplifier chain and from the Johnson noise Vnt of the rs whose mean spectral power is v2nt = 4KT0rs∆ f , where K is the Boltzmann constant, T0 is the circuit temperature and ∆ f is the bandwidth.

Resistive cooling of particles
Non-neutral plasmas and the AEgIS anti-hydrogen production trap
Tuned circuit detection of cold non-neutral plasma in Penning trap
Cryogenic amplifier performance
50 W Coax
Gain and power consumption
Noise analysis model
Noise analysis results
Conclusions

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