A. Shemyakin scite author profile

We report on an experimental demonstration of electron cooling of high-energy antiprotons circulating in a storage ring. In our experiments, electron cooling, a well-established method at low energies (< 500 MeV/nucleon), was carried out in a new region of beam parameters, requiring a multi-MeV dc electron beam and an unusual beam transport line. In this letter we present the results of the longitudinal cooling force measurements and compare them with theoretical predictions.

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Optical principles of beam transport for relativistic electron cooling

Burov

Nagaitsev

Shemyakin

et al. 2000

Phys. Rev. ST Accel. Beams

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In conventional low energy electron coolers, the electron beam is immersed in a continuous solenoid, which provides a calm and tightly focused beam in a cooling section. While suitable for low energies, the continuity of the accompanying magnetic field is hardly realizable at relativistic energies. We consider the possibility of using an extended solenoid in the gun and the cooling section only, applying lumped focusing for the rest of the electron transport line.

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Antiproton Cooling in the Fermilab Recycler Ring

Nagaitsev¹,

Bolshakov²,

Broemmelsiek³

et al. 2006

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Abstract. The 8.9-GeV/c Recycler antiproton storage ring is equipped with both stochastic and electron cooling systems. These cooling systems are designed to assist accumulation of antiprotons for the Tevatron collider operations. In this paper we report on an experimental demonstration of electron cooling of high-energy antiprotons. At the time of writing this report, the Recycler electron cooling system is routinely used in collider operations. It has helped to set recent peak luminosity records.

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Characterisation of the PXIE Allison-type emittance scanner

D’Arcy

Alvarez

Gaynier

et al. 2016

Nuclear Instruments and Methods in Physics Research Section A:

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An Allison-type emittance scanner has been designed for PXIE at FNAL with the goal of providing fast and accurate phase space reconstruction. The device has been modified from previous LBNL/SNS designs to operate in both pulsed and DC modes with the addition of water-cooled front slits. Extensive calibration techniques and error analysis allowed confinement of uncertainty to the <5% level (with known caveats). With a 16-bit, 1 MHz electronics scheme the device is able to analyse a pulse with a resolution of 1 µs, allowing for analysis of neutralisation effects. This paper describes a detailed breakdown of the R&D, as well as post-run analysis techniques.

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Electron gun and collector for the Fermilab high-energy electron cooling

Sharapa¹,

Shemyakin²,

Nagaitsev

1998

Nuclear Instruments and Methods in Physics Research Section A:

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Low emittance growth in a low energy beam transport line with un-neutralized section

Prost

Carneiro

Shemyakin

2018

Phys. Rev. Accel. Beams

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In a Low Energy Beam Transport line (LEBT), the emittance growth due to the beam's own space charge is typically suppressed by way of neutralization from either electrons or ions, which originate from ionization of the background gas. In cases where the beam is chopped, the neutralization pattern changes throughout the beginning of the pulse, causing the Twiss parameters to differ significantly from their steady state values, which, in turn, may result in beam losses downstream. For a modest beam perveance, there is an alternative solution, in which the beam is kept un-neutralized in the portion of the LEBT that contains the chopper. The emittance can be nearly preserved if the transition to the un-neutralized section occurs where the beam exhibits low transverse tails. This report discusses the experimental realization of such a scheme at Fermilab's PXIE, where low beam emittance dilution was demonstrated.

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Commissioning of Fermilab's Electron Cooling System for 8-GeV Antiprotons

Nagaitsev

Broemmelsiek

Burov

et al.

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A 4.3-MeV electron cooling system [1] has been installed at Fermilab in the Recycler antiproton storage ring and is currently being commissioned. The cooling system is designed to assist accumulation of 8.9-GeV/c antiprotons for the Tevatron collider operations. This paper reports on the progress of the electron beam commissioning effort as well as on detailed plans of demonstrating the cooling of antiprotons.

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FNAL R&D in medium energy electron cooling

Nagaitsev

Burov

Crawford

et al. 2000

Nuclear Instruments and Methods in Physics Research Section A:

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A. Shemyakin

Experimental Demonstration of Relativistic Electron Cooling

Optical principles of beam transport for relativistic electron cooling

Antiproton Cooling in the Fermilab Recycler Ring

Characterisation of the PXIE Allison-type emittance scanner

Electron gun and collector for the Fermilab high-energy electron cooling

Low emittance growth in a low energy beam transport line with un-neutralized section

Commissioning of Fermilab's Electron Cooling System for 8-GeV Antiprotons

FNAL R&D in medium energy electron cooling

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