Electron beam and magnetic field mapping techniques used to determine field errors in the ATF torsatron

R. J. Colchin; F. S.B. Anderson; A. C. England; R. F. Gandy; J. H. Harris; M. A. Henderson; D. L. Hillis; R. R. Kindsfather; D. K. Lee; D. L. Million; M. Murakami; G. H. Neilson; M. J. Saltmarsh; C. M. Simpson

doi:10.1063/1.1141082

Electron beam and magnetic field mapping techniques used to determine field errors in the ATF torsatron

R. J. Colchin, F. S.B. Anderson, A. C. England, R. F. Gandy, J. H. Harris, M. A. Henderson, D. L. Hillis, R. R. Kindsfather, D. K. Lee, D. L. Million, M. Murakami, G. H. Neilson, M. J. Saltmarsh, C. M. Simpson

Power Exhaust and Particle Control

Research output: Contribution to journal › Article › peer-review

30 Scopus citations

Abstract

The beam from an electron gun was used to trace flux surfaces in the Advanced Toroidal Facility (ATF) torsatron. The ATF magnetic field was run steady state at 0.1 T, and the electron beam was detected optically with an image-intensified, solid-state camera when it impinged on a phosphor-coated screen. Closed flux surfaces and islands at several low-order resonances were observed. The largest island, located at the τ = 1/2 surface, was from 5 to 6 cm in width, and its presence implied the existence of magnetic field errors. To determine if these error fields could be traced to small misalignments of the magnetic coils, a device capable of accurately measuring the radial and vertical magnetic field components of individual coil sets was placed in the center of ATF. This device allowed for a determination of the precise location of each of the coils that make up the ATF coil set. No significant coil misalignments were found. A further investigation of the coil configuration led to the identification of dipole fields in the helical field coil leads as the source of the field errors. The techniques developed in making these measurements are described in the text.

Original language	English
Pages (from-to)	2680-2689
Number of pages	10
Journal	Review of Scientific Instruments
Volume	60
Issue number	8
DOIs	https://doi.org/10.1063/1.1141082
State	Published - 1989

Access to Document

10.1063/1.1141082

Cite this

Colchin, R. J., Anderson, F. S. B., England, A. C., Gandy, R. F., Harris, J. H., Henderson, M. A., Hillis, D. L., Kindsfather, R. R., Lee, D. K., Million, D. L., Murakami, M., Neilson, G. H., Saltmarsh, M. J., & Simpson, C. M. (1989). Electron beam and magnetic field mapping techniques used to determine field errors in the ATF torsatron. Review of Scientific Instruments, 60(8), 2680-2689. https://doi.org/10.1063/1.1141082

@article{f229d2d730824d868ab0109926ffcf8d,

title = "Electron beam and magnetic field mapping techniques used to determine field errors in the ATF torsatron",

abstract = "The beam from an electron gun was used to trace flux surfaces in the Advanced Toroidal Facility (ATF) torsatron. The ATF magnetic field was run steady state at 0.1 T, and the electron beam was detected optically with an image-intensified, solid-state camera when it impinged on a phosphor-coated screen. Closed flux surfaces and islands at several low-order resonances were observed. The largest island, located at the τ = 1/2 surface, was from 5 to 6 cm in width, and its presence implied the existence of magnetic field errors. To determine if these error fields could be traced to small misalignments of the magnetic coils, a device capable of accurately measuring the radial and vertical magnetic field components of individual coil sets was placed in the center of ATF. This device allowed for a determination of the precise location of each of the coils that make up the ATF coil set. No significant coil misalignments were found. A further investigation of the coil configuration led to the identification of dipole fields in the helical field coil leads as the source of the field errors. The techniques developed in making these measurements are described in the text.",

author = "Colchin, {R. J.} and Anderson, {F. S.B.} and England, {A. C.} and Gandy, {R. F.} and Harris, {J. H.} and Henderson, {M. A.} and Hillis, {D. L.} and Kindsfather, {R. R.} and Lee, {D. K.} and Million, {D. L.} and M. Murakami and Neilson, {G. H.} and Saltmarsh, {M. J.} and Simpson, {C. M.}",

year = "1989",

doi = "10.1063/1.1141082",

language = "English",

volume = "60",

pages = "2680--2689",

journal = "Review of Scientific Instruments",

issn = "0034-6748",

publisher = "American Institute of Physics",

number = "8",

}

Colchin, RJ, Anderson, FSB, England, AC, Gandy, RF, Harris, JH, Henderson, MA, Hillis, DL, Kindsfather, RR, Lee, DK, Million, DL, Murakami, M, Neilson, GH, Saltmarsh, MJ & Simpson, CM 1989, 'Electron beam and magnetic field mapping techniques used to determine field errors in the ATF torsatron', Review of Scientific Instruments, vol. 60, no. 8, pp. 2680-2689. https://doi.org/10.1063/1.1141082

TY - JOUR

T1 - Electron beam and magnetic field mapping techniques used to determine field errors in the ATF torsatron

AU - Colchin, R. J.

AU - Anderson, F. S.B.

AU - England, A. C.

AU - Gandy, R. F.

AU - Harris, J. H.

AU - Henderson, M. A.

AU - Hillis, D. L.

AU - Kindsfather, R. R.

AU - Lee, D. K.

AU - Million, D. L.

AU - Murakami, M.

AU - Neilson, G. H.

AU - Saltmarsh, M. J.

AU - Simpson, C. M.

PY - 1989

Y1 - 1989

N2 - The beam from an electron gun was used to trace flux surfaces in the Advanced Toroidal Facility (ATF) torsatron. The ATF magnetic field was run steady state at 0.1 T, and the electron beam was detected optically with an image-intensified, solid-state camera when it impinged on a phosphor-coated screen. Closed flux surfaces and islands at several low-order resonances were observed. The largest island, located at the τ = 1/2 surface, was from 5 to 6 cm in width, and its presence implied the existence of magnetic field errors. To determine if these error fields could be traced to small misalignments of the magnetic coils, a device capable of accurately measuring the radial and vertical magnetic field components of individual coil sets was placed in the center of ATF. This device allowed for a determination of the precise location of each of the coils that make up the ATF coil set. No significant coil misalignments were found. A further investigation of the coil configuration led to the identification of dipole fields in the helical field coil leads as the source of the field errors. The techniques developed in making these measurements are described in the text.

AB - The beam from an electron gun was used to trace flux surfaces in the Advanced Toroidal Facility (ATF) torsatron. The ATF magnetic field was run steady state at 0.1 T, and the electron beam was detected optically with an image-intensified, solid-state camera when it impinged on a phosphor-coated screen. Closed flux surfaces and islands at several low-order resonances were observed. The largest island, located at the τ = 1/2 surface, was from 5 to 6 cm in width, and its presence implied the existence of magnetic field errors. To determine if these error fields could be traced to small misalignments of the magnetic coils, a device capable of accurately measuring the radial and vertical magnetic field components of individual coil sets was placed in the center of ATF. This device allowed for a determination of the precise location of each of the coils that make up the ATF coil set. No significant coil misalignments were found. A further investigation of the coil configuration led to the identification of dipole fields in the helical field coil leads as the source of the field errors. The techniques developed in making these measurements are described in the text.

UR - http://www.scopus.com/inward/record.url?scp=5844357541&partnerID=8YFLogxK

U2 - 10.1063/1.1141082

DO - 10.1063/1.1141082

M3 - Article

AN - SCOPUS:5844357541

SN - 0034-6748

VL - 60

SP - 2680

EP - 2689

JO - Review of Scientific Instruments

JF - Review of Scientific Instruments

IS - 8

ER -

Electron beam and magnetic field mapping techniques used to determine field errors in the ATF torsatron

Abstract

Access to Document

Other files and links

Fingerprint

Cite this