R.A. Todd scite author profile

The PHENIX detector is designed to perform a broad study of A-A, p-A, and p-p collisions to investigate nuclear matter under extreme conditions. A wide variety of probes, sensitive to all timescales, are used to study systematic variations with species and energy as well as to measure the spin structure of the nucleon. Designing for the needs of the heavy-ion and polarized-proton programs has produced a detector with unparalleled capabilities. PHENIX measures electron and muon pairs, photons, and hadrons with excellent energy and momentum resolution. The detector consists of a large number of subsystems that are discussed in other papers in this volume. The overall design parameters of the detector are presented. The PHENIX detector is designed to perform a broad study of A-A, p-A, and p-p collisions to investigate nuclear matter under extreme conditions. A wide variety of probes, sensitive to all timescales, are used to study systematic variations with species and energy as well as to measure the spin structure of the nucleon. Designing for the needs of the heavy-ion and polarized-proton programs has produced a detector with unparalleled capabilities. PHENIX measures electron and muon pairs, photons, and hadrons with excellent energy and momentum resolution. The detector consists of a large number of subsystems that are discussed in other papers in this volume. The overall design parameters of the detector are presented. Disciplines Engineering Physics | Physics Comments This is a manuscript of an article from Nuclear Instruments and Methods in Physics Research

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PHENIX on-line systems

Adler

Allen

Alley

et al. 2003

Nuclear Instruments and Methods in Physics Research Section A:

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The southwestern surgical congress multi-center trial on suspected common duct stones

Frazee

Regner

Truitt

et al. 2019

The American Journal of Surgery

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R&D ERL: Photocathode Deposition and Transport System

Pate¹,

Ben‐Zvi²,

Rao³

et al. 2010

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The Polarized SRF Gun Experiment

Kewisch¹,

Ben‐Zvi²,

Rao³

et al. 2008

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Abstract. RF electron guns are capable of producing electron bunches with high brightness, which outperform DC electron guns and may even be able to provide electron beams for the ILC without the need for a damping ring. However, all successful existing guns for polarized electrons are DC guns because the environment inside an RF gun is hostile to the GaAs cathode material necessary for polarization. While the typical vacuum pressure in a DC gun is better than lo-" torr the vacuum in an RF gun is in the order of lo-' torr. Experiments at BINP Novosibirsk show that this leads to strong ion back-bombardment and generation of dark currents, which destroy the GaAs cathode in a short time. The situation might be much more favorable in a (super-conducting) SRF gun. The cryogenic pumping of the gun cavity walls may make it possible to maintain a vacuum close to 10.' ' torr, solving the problem of ion bombardment and dark currents. Of concern would be Contamination of the gun cavity by evaporating cathode material. This report describes an experiment that Brookhaven National Laboratory (BNL) in collaboration with Advanced Energy Systems (AES) is conducting to answer these questions.

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R.A. Todd

PHENIX detector overview

PHENIX on-line systems

The southwestern surgical congress multi-center trial on suspected common duct stones

R&D ERL: Photocathode Deposition and Transport System

The Polarized SRF Gun Experiment

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