Collisional equipartition rate for a magnetized pure electron plasma

Glinsky, Michael E.; O’Neil, T. M.; Rosenbluth, M. N.; Tsuruta, Kenji; Ichimaru, Setsuo

doi:10.1063/1.860124

Cited by 93 publications

(83 citation statements)

References 10 publications

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“…For B ¼ 0, a classic treatment [18] gives a p À e À collision rate 10 6 times larger than p for our plasmas. The rate for collisions that couple radial and axial energy is suppressed when a strong B is added along the trap axis [19]. Even with the predicted suppression by a factor of 10 3 , the axial-radial collision rate is much faster than p , with a time constant shorter than 0.01 s for even our lowest temperatures.…”

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confidence: 89%

Adiabatic Cooling of Antiprotons

et al. 2011

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confidence: 89%

Adiabatic Cooling of Antiprotons

et al. 2011

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“…This is because for a strongly magnetized plasma the perpendicular kinetic energy is constrained by a many-particle adiabatic invariant [23]. This modifies the particle distribution function (which is what we measure in Fig.…”

Section: Positron Temperature Estimatementioning

confidence: 99%

A laser-cooled, high density positron plasma

Jelenković¹,

Newbury²,

Bollinger³

et al. 2002

AIP Conference Proceedings

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Abstract. We present results on trapping and cooling of positrons in a Penning trap. Up to a few thousand positrons are trapped and sympathetically cooled through Coulomb collisions (sympathetic cooling) with laser-cooled 9 Be+ ions. By imaging the 9Be+ laser-induced fluorescence, we observe centrifugal separation of the 9Be+ ions and the positrons, with the positrons coalescing into a column along the trap axis. This indicates the positrons have the same rotation frequency and comparable density (-4 x 109 cm-3 ) as the 9 Be+ ions, and places an upper limit of approximately 5 K on the positron temperature of motion parallel to the magnetic field. The measured positron lifetime is > 8 days in our room temperature vacuum of 10-8 Pa.

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“…Second, an increase of a few dB in the applied microwave power above this threshold was sufficient to rapidly annihilate the positrons, presumably through excitation of the positrons to a least a few volts energy where positronium formation with background gas atoms could take place. The significant excitation of the positron cyclotron motion was probably necessary because of the weak coupling between the positron cyclotron and 9 Be + ion motions, and the low rate of energy transfer between the positron cyclotron and axial energies in the high magnetic field of our trap [29]. Other potential sources of broadening include the relativistic mass shift (∼10 kHz for each 300 K in energy), first-order Doppler broadening from positron motion within the trap, and magnetic field instability and inhomogeneity.…”

Section: Positron Cyclotron Excitationmentioning

confidence: 99%

“…In addition the positron cyclotron motion is collisionally coupled to the positron axial motion, but this coupling becomes exponentially weak when the Larmor radius is less than the distance of closest approach (the strongly magnetized regime). This energy transfer rate has been carefully studied [29] and for a 10 9 cm −3 positron plasma is ∼10 Hz for T ∼10 K. Therefore we expect T ⊥ to be greater than 10 K and to be greater than T which is cooled by Coulomb collisions with the laser-cooled 9 Be + ions.…”

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A Laser-cooled Positron Plasma

Jelenković

Bollinger

Newbury

et al.

New Directions in Antimatter Chemistry and Physics

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We present results on trapping and cooling of positrons in a Penning trap. Positrons from a 2 mCi 22 Na source travel along the axis of a 6 T magnet and through the trap after which they strike a Cu reflection moderator crystal. Up to a few thousand positrons are trapped and lose energy through Coulomb collisions (sympathetic cooling) with laser-cooled 9 Be + . By imaging the 9 Be + laser-induced fluorescence, we observe centrifugal separation of the 9 Be + ions and positrons, with the positrons coalescing into a column along the trap axis. This indicates the positrons have the same rotation frequency and comparable density ( 4 × 10 9 cm −3 ) as the 9 Be + ions, and places an upper limit of approximately 5 K on the positron temperature of motion parallel to the magnetic field. We estimate the number of trapped positrons from the volume of this column and from the annihilation radiation when the positrons are ejected from the trap. The measured positron lifetime is > 8 days in our room temperature vacuum of 10 −8 Pa.

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Collisional equipartition rate for a magnetized pure electron plasma

Cited by 93 publications

References 10 publications

Adiabatic Cooling of Antiprotons

Adiabatic Cooling of Antiprotons

A laser-cooled, high density positron plasma

A Laser-cooled Positron Plasma

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