We present constraints on the spacetime variation of the fine-structure constant $\alpha$ at redshifts $35$. The [O III] doublet lines are arguably the best emission lines to probe the variation in $\alpha$. We divide our sample into 5 subsamples based on redshift and calculate the relative variation $\Delta\alpha/\alpha$ for the individual subsamples. The calculated $\Delta\alpha/\alpha$ values are consistent with zero within $1\sigma$ at all redshifts, suggesting no time variation in $\alpha$ above a level of $(1-2) \times10^{-4}$ ($1\sigma$) in the past 13.2 billion years. When the whole sample is combined, the constraint is improved to be $\Delta\alpha/\alpha = (0.4\pm0.7) \times10^{-4}$. We further test the spatial variation in $\alpha$ using four subsamples of galaxies in four different directions on the sky. The measured $\Delta\alpha/\alpha$ values are consistent with zero at a $1\sigma$ level of $\sim10^{-4}$. While the constraints in this work are not as stringent as those from lower-redshift quasar absorption lines in previous studies, this work uses an independent tracer and provides the first constraints on $\Delta\alpha/\alpha$ at the highest redshifts. Our analyses also indicate that the relative wavelength calibration of the JWST spectra is robust. With the growing number of emission-line galaxies from JWST, we expect to achieve stronger constraints in the future.
Comment: 9 pages, 6 figures, submitted to ApJ