New James Webb Space Telescope (JWST) observations are revealing the first galaxies to be prolific producers of ionizing photons, which we argue gives rise to a tension between different probes of reionization. For hydrogen reionization to proceed there must be enough ionizing photons for all of the hydrogen atoms, including their recombinations. Over the last two decades a consensus has emerged where star-forming galaxies are able to generate these photons, given reasonable values for their number densities, ionizing efficiencies $\xi_{\rm ion}$ (per unit UV luminosity), and escape fractions $f_{\rm esc}$. However, new JWST observations infer high values of $\xi_{\rm ion}$ during reionization and an enhanced abundance of earlier ($z\gtrsim 9$) galaxies, dramatically increasing the number of ionizing photons produced at high $z$. Simultaneously, recent low-$z$ studies predict significant escape fractions for faint reionization-era galaxies. Put together, we show that the galaxies we have directly observed ($M_{\rm UV} < -15$) not only can drive reionization, but would end it too early. That is, our current galaxy observations, taken at face value, imply an excess of ionizing photons and thus a process of reionization in tension with the cosmic microwave background (CMB) and Lyman-$\alpha$ forest. Considering galaxies down to $M_{\rm UV}\approx -11$, below current observational limits, only worsens this tension, requiring on average $f_{\rm esc}\approx 3\%$, far lower than expected for early galaxies from post-reionization studies. We discuss possible avenues to resolve this photon budget crisis, including missing astrophysical or observational selection effects, as well as enhanced recombinations.
Comment: 6+3 pages, 3+2 figures, comments welcome