THE CORONAL ELECTRON-DENSITY DISTRIBUTION DETERMINED FROM DUAL-FREQUENCY RANGING MEASUREMENTS DURING THE 1991 SOLAR CONJUNCTION OF THE ULYSSES SPACECRAFT

Dual-frequency ranging and Doppler measurements were conducted in support of the Ulysses Solar Corona Experiment at and around the spacecraft's first solar conjunction in 1991 August. The differential group delay time between range codes on the two downlink carrier signals at the wavelengths 13.1 and 3.6 cm, a direct measure of the total electron content between spacecraft and ground station, was used to derive the electron density distribution in the solar corona. Linear power-law representations of the coronal electron density were derived for the range of solar distances from 4 R. to 40 R. on both sides of the Sun. The corona was found to be very nearly symmetric; the radial falloff exponent being 2.54 +/- 0.05 for occultation ingress (east solar limb) and 2.42 +/- 0.05 for egress (west limb), respectively. The departure of these exponents from the inverse square relation implies that significant solar wind acceleration is occurring within the radial range of the observations. The electron density level was found to be considerably lower than that observed during the 1988 December solar occultation of Voyager 2. Although the smoothed sunspot number R(Z) (a standard indicator of solar activity) was almost the same in 1988 December and 1991 August, the mean electron density at 20 R. was found to be 1.7 +/- 0.1 x 10(3) cm-3 during the Ulysses conjunction, a decline by almost a factor of 4 from the value obtained during the Voyager conjunction.