A laser-based beam profile monitor for the SLC/SLD interaction region

被引：15

作者：

Alley, R ^{[1
]}

Arnett, D ^{[1
]}

Bong, E ^{[1
]}

Colocho, W ^{[1
]}

Frisch, J ^{[1
]}

HortonSmith, S ^{[1
]}

Inman, W ^{[1
]}

Jobe, K ^{[1
]}

Kotseroglou, T ^{[1
]}

McCormick, D ^{[1
]}

Nelson, J ^{[1
]}

Scheeff, M ^{[1
]}

Wagner, S ^{[1
]}

Ross, MC ^{[1
]}

机构：

[1] STANFORD UNIV,STANFORD LINEAR ACCELERATOR CTR,STANFORD,CA 94309

来源：

NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH SECTION A-ACCELERATORS SPECTROMETERS DETECTORS AND ASSOCIATED EQUIPMENT | 1996年 / 379卷 / 03期

关键词：

D O I：

10.1016/0168-9002(96)00556-6

中图分类号：

TH7 [仪器、仪表];

学科分类号：

0804 ; 080401 ; 081102 ;

摘要：

Beam size estimates made using beam-beam deflections are used for optimization of the Stanford Linear Collider (SLC) electron-positron beam sizes. Typical beam sizes and intensities expected for 1996 operations are 2.1 x 0.6 mu m (x,y) at 4.0 x 10(10) particles per pulse. Conventional profile monitors, such as scanning wires, fail at charge densities well below this. The laser-based profile monitor uses a finely-focused 350-nm wavelength tripled YLF laser pulse that traverses the particle beam path about 29 cm away from the e(+)/e(-) IF. Compton scattered photons and degraded e(+)/e(-) are detected as the beam is steered across the laser pulse. The laser pulse has a transverse size of 380 nm and a Rayleigh range of about 5 mu m.

引用

页码：363 / 365

页数：3

共 50 条

[21] Robust beam compensation for laser-based additive manufacturing
Moesen, Maarten
Craeghs, Tom
Kruth, Jean-Pierre
Schrooten, Jan
COMPUTER-AIDED DESIGN, 2011, 43 (08) : 876 - 888
[22] Beam shaping for laser-based adaptive optics in astronomy
Bechet, Clementine
Guesalaga, Andres
Neichel, Benoit
Fesquet, Vincent
Gonzalez-Nunez, Hector
Zuniga, Sebastian
Escarate, Pedro
Guzman, Dani
OPTICS EXPRESS, 2014, 22 (11): : 12994 - 13013
[23] A BEAM PROFILE MONITOR BASED ON THE APPLICATION OF INFRARED THERMOGRAPHY
BUTTIG, H
NUCLEAR INSTRUMENTS & METHODS IN PHYSICS RESEARCH, 1982, 203 (1-3): : 69 - 71
[24] Ultra-sensitive, diode laser-based monitor for singlet oxygen
Davis, SJ
Zhu, L
Minhaj, AM
Hinds, MF
Lee, S
Keating, PB
Rosen, DI
Hasan, T
OPTICAL METHODS FOR TUMOR TREATMENT AND DETECTION: MECHANISMS AND TECHNIQUES IN PHOTODYNAMIC THERAPY XII, 2003, 4952 : 140 - 148
[25] METAL TEMPERATURE IN INTERACTION REGION WITH A LASER BEAM
VEIKO, VP
IMAS, YA
KOKORA, AN
LIBENSON, MN
SOVIET PHYSICS TECHNICAL PHYSICS-USSR, 1968, 12 (10): : 1401 - &
[26] Measurement of a small vertical emittance with a laser wire beam profile monitor
Sakai, H
Honda, Y
Sasao, N
Araki, S
Hayano, H
Higashi, Y
Kubo, K
Okugi, T
Taniguchi, T
Terunuma, N
Urakawa, J
Takano, M
PHYSICAL REVIEW SPECIAL TOPICS-ACCELERATORS AND BEAMS, 2002, 5 (12): : 25 - 34
[27] LOW-COST CO2-LASER BEAM PROFILE MONITOR
WILDMANN, D
BRONNIMANN, R
SCHURCH, G
REVIEW OF SCIENTIFIC INSTRUMENTS, 1984, 55 (11): : 1777 - 1778
[28] Investigation of Plant–Pathogen Interaction by Laser-Based Photoacoustic Spectroscopy
A. Puiu
G. Giubileo
A. Lai
International Journal of Thermophysics, 2014, 35 : 2237 - 2245
[29] The splitted beam profile of laser beam in the interaction of intense lasers with overdense plasmas
Xia, Xiongping
Cai, Zebin
Yi, Lin
LASER AND PARTICLE BEAMS, 2011, 29 (02) : 161 - 168
[30] Development of a novel laser-based measuring system for the thread profile of ballscrew
Huang, Hsueh-Liang
Jywe, Wen-Yuh
Liu, Chien-Hung
Duan, Lili
Wang, Ming-Shi
OPTICS AND LASERS IN ENGINEERING, 2010, 48 (10) : 1012 - 1018

← 1 2 3 4 5 →