We present measurements of [SIII]λλ9069,9531 for a sample of
z∼1.5 star-forming galaxies, the first sample with measurements of these
lines at z>0.1. We employ the line ratio
S32​≡[SIII]λλ9069,9531/[SII]λλ6716,6731
as a novel probe of evolving ISM conditions. Since this ratio includes the
low-ionization line [SII], it is crucial that the effects of diffuse ionized
gas (DIG) on emission-line ratios be accounted for in z∼0 integrated
galaxy spectra, or else that comparisons be made to samples of local HII
regions in which DIG emission is not present. We find that S32​ decreases
with increasing stellar mass at both z∼1.5 and z∼0, but that the
dependence is weak suggesting S32​ has a very shallow anticorrelation with
metallicity, in contrast with O32​ that displays a strong metallicity
dependence. As a result, S32​ only mildly evolves with redshift at fixed
stellar mass. The z∼1.5 sample is systematicallty offset towards lower
S32​ and higher [SII]/Hα at fixed [OIII]/Hβ relative to z=0
HII regions. By comparing to photoionization model grids, we find that such
trends can be explained by a scenario in which the ionizing spectrum is harder
at fixed O/H with increasing redshift, but are inconsistent with an increase in
ionization parameter at fixed O/H. This analysis demonstrates the advantages of
expanding beyond the strongest rest-optical lines for evolutionary studies, and
the particular utility of [SIII] for characterizing evolving ISM conditions and
stellar compositions. These measurements provide a basis for estimating [SIII]
line strengths for high-redshift galaxies, a line that the James Webb Space
Telescope will measure out to z~5.5