NASA Airborne Lidar Mission, 37°N-North Pole. The following is a report from M. P. McCormick. "An airborne lidar mission was flown 19-28 January on the NASA Electra aircraft from 37°N to the North Pole, via Goose Bay, Labrador, and Söndre Strömfjord and Thule airbases, Greenland. The primary objective of the mission was to provide correlative stratosperic aerosol measurements for the SAM II (Stratospheric Aerosol Measurement) satellite, successfully accomplished on 3 separate satellite underflights.

"The El Chichón cloud was very consistent from 37°N-76°N, generally as a single broad layer with very little structure. From Thule a flight was conducted 24 January to the North Pole along the 60° W meridian to determine the northerly extent of the El Chichón material and to search for polar stratospheric clouds (PSC's, see below). As the aircraft proceeded north from Thule, considerable structure and varied intensity were observed in the El Chichón cloud, with an increase in peak scattering ratio.

"First detected by the SAM II satellite, PSC's are thought to be ice clouds that form during the Arctic and Antarctic winter by freezing of diluted sulfuric acid-water aerosol droplets at temperatures less than about -80° to -85°C, followed by rapid growth by sublimation (McCormick et al., 1982, and Steele et al., 1983). Nacreous or mother-of-pearl clouds are thought to be subsets of PSC's. From 85°N to the Pole, PSC's were detected for the first time by a remote sensor other than SAM II. They occurred at 19-21 km altitude, above the main El Chichón layer.

"A second flight was conducted 25 January from Thule to 86°N and PSC's were again detected within the temperature region of -85°C from about 81°N - 86°N. A third mission was flown 27 January from Thule to 87°N over the same flight path (60° meridian) and somewhat to the east. The El Chichón layer decreased in intensity and was less structured. There were no indications of PSC's, correlating with stratospheric temperature data, which showed that the low-temperature region had moved over the north pole toward Siberia. Returning to Virginia on 28 January, the same consistency was observed in the stratospheric layer as on the earlier northbound flight, with a slight decrease in peak scattering ratio.

"In addition to the uplooking airborne lidar, a downlooking lidar was used to study the tropospheric aerosols. In-situ measurements of aerosol mass and number density, CO₂ and O₃ were made over the full flight range at various altitudes during the mission.

Lidar data. At Mauna Loa, Hawaii, a distinct double aerosol layer was observed 3 January, similar to the pattern observed in December. No strong upper peak was present a week later, but numerous small layers were detected above the main lower peak. On 19 January, enhanced higher-altitude layers were no longer detected. Two distinct layers were observed over Fukuoka, Japan on 10 February, in contrast to the broad monolayer present a month earlier.

Lidar at Garmisch-Partenkirchen, West Germany continued to detect aerosols from the March-April 1982 eruption of El Chichón. Altitude and values of peak backscattering were slightly lower than in the summer but secondary peaks at higher altitudes were sometimes detected. Integrated backscattering between 1 km above the tropopause and the top of the aerosol layer, about 20% below expected values in the second half of September and the first half of October, rose to 70% above expected values 14 November as the tropopause altitude dropped to 9.9 km in arctic air and backscattering was enhanced between 9 and 13 km.

Unusual sunrises and sunsets. Edward Brooks reported that dawns and dusks indicated a variable and often weak aerosol layer over Jeddah, Saudi Arabia in late December and early January. Morning and evening colors on 26 December suggested that few scattering particles were present at either low or high altitudes. Stronger sunrises and sunsets were observed 27-30 December, but only late dawn colors, illuminating low-altitude aerosols, were visible 31 December. Dawns were essentially colorless 3 and 7-9 January; only late dawn colors (aerosols at low altitude) were visible on the 4th, while only early dawn colors (high-altitude material) were seen 2 days later.

From Millville, New Jersey, Fred Schaaf reported that twilight colors were usually weak to moderate in December and early January. On 16 December, early twilight colors merged into a strong crimson glow at 12° altitude, suggesting that the top of the scattering layer was at 13-18 km altitude. Colors were strong again the following evening and included secondary illumination to a solar depression angle of about 12°. As in previous months, the arrival of arctic air 24 December weakened twilight colors. On 8 January, weak to moderate colors were replaced suddenly by a milky area at 12° altitude, indicating the top of the aerosol layer at 13-16 km. The same evening, a secondary glow remained visible to an SDA of 10°. On 12 January, the time that illumination ended suggested that highest aerosols were at 11-13 km. Only early twilight colors were visible 19 January. A week later, timing of the end of purplish illumination indicated that aerosols reached 16-19 km altitude and a deep-hued secondary glow persisted for much longer. However, colors were very weak the following night. On 1 February, moderate colors disappeared at a time indicating aerosols reached 11-16 km.

References. McCormick, M. P., Steele, H. M., Hamill, P., Chu, W. P., and Swissler, T. J., 1982, Polar stratospheric cloud sightings by SAM II: Journal of the Atmospheric Sciences, v. 39, no. 6, p. 1387-1397.

Steele, H. M., Hamill, P., McCormick, M. P., and Swissler, T. J., 1983, The formation of polar stratospheric clouds: Journal of the Atmospheric Sciences, v. 40, no. 8, p. 2055-2067.

Information Contacts: P. McCormick, NASA; R. Reiter, Garmisch-Partenkirchen, W. Germany; T. DeFoor, MLO; M. Fujiwara and M. Hirono, Kyushu Univ., Japan; E. Brooks, Saudi Arabia; F. Schaaf, Millville, NJ.