We present data from a 9-month series of ground-based measurements of stratospheric nitric acid, made over the South Pole from mid-April 1993 to mid-January 1994. Observations were typically made at 3- to 6-day intervals. Both profiles and column densities have been retrieved from pressure-broadened millimeter-wave emission spectra. These measurements provide the first quasi-continuous series of vertical mixing ratio profiles for this species in the heart of the south polar vortex. Conversion of NOx to nitric acid by heterogeneous reactions, and its incorporation into polar stratospheric cloud (PSC) particles, along with subsequent gravitational settling, is considered to be the main denitrifying mechanism in the Antarctic stratosphere, setting up conditions for ozone destruction at the end of winter. In our observations, a small increase in HNO3 was seen between April and the end of May, after which a rapid loss took place below 25 km. Column density above ~15 km decreased to ≤1/4 its maximum within 30 days, and depletion continued until middle to late July, by which time the nitric acid column above 15 km had diminished by more than a factor of 10. The initial depletion was coincident with the onset of a rapid increase in lidar backscatter from polar stratospheric cloud formation at the same altitude range. Gas-phase depletion was tracked as a function of altitude and temperature and found to be consistent with the temperature and partial pressure relationship for formation of ternary mixtures of HNO3, H2SO4, and H2O. Depletion occurred ~3 weeks earlier in 1993 than was seen in 1992 column density measurements by Van Allen et al. <1995>. In late June a new layer of HNO3 was generated in the vicinity of 40-km altitude and, subsequently, appeared to be carried downward with general vertical transport of air within the vortex. In spring, as temperatures increased, no rapid increase of gas-phase HNO3 was seen, indicating that gravitational settling had carried PSC-accreted nitric acid to low altitudes. By the end of observations in January 1994, mixing ratios and column densities above ~15 km had not yet reached more than about half the values seen the previous April, indicating that a rather large increase in stratospheric HNO3 occurs in the early austral fall over the south polar region.¿ 1997 American Geophysical Union