Abstract

The adjustable-waveform, high-voltage spark source has found application in several production situations in the alloy industry. Commercial versions of this source have appeared using an auxiliary air-gap, or a hydrogen thyratron, for controlling spark formation. It would appear that some of the practical utility of these sources is associated with increased precision and reduced Matrix effects, as compared to other forms of excitation, arising from use of the pulsating unidirectional spark current that they produce as one of a variety of readily-adjustable waveforms. It is not yet clear that a particular mode Of triggering is more critical to improved spectrochemistry than is the pulsating unidirectional waveform, which suggests that traditional air-gap or rotary-gap high-voltage spark sources that are already in production use could be modified to produce this, and other, waveforms with attendant analytical benefits.

An Air Interrupter for Use with the A.R.L. Spark Source

Emil Kaczor and Katherine Chamberlain
J. Opt. Soc. Am. 39(11) 917-919 (1949)

Spark Light Source of Short Duration*

J. W. Beams, A. R. Kuhlthau, A. C. Lapsley, J. H. McQueen, L. B. Snoddy, and W. D. Whitehead
J. Opt. Soc. Am. 37(10) 868-870 (1947)

Expansion of Initial High-Current Spark Channels

Heinz Fischer and C. C. Gallagher
Appl. Opt. 4(9) 1151-1154 (1965)

A Vacuum Spark Light Source for the Extreme Ultraviolet Region

N. Wainfan and J. E. Rudisill
Appl. Opt. 8(2) 345-349 (1969)

Electrode Phenomena in a High Current 20-Nanosecond Spark

Heinz Fischer and C. C. Gallagher
Appl. Opt. 6(12) 2176-2178 (1967)