Publications
2022, Perrin, A., L. Manceron, R. Armante, F. Kwabia-Tchana, P. Roy, D. Doizi & G.C. Toon, The 5.8 µm absorption bands for nitric acid (H14N16O3): line positions and intensities for the ν2 band at 1709.567 cm−1 and for its first associated hot bands (ν2+ν9−ν9, ν2+ν7−ν7, ν2+ν6−ν6), Molecular Physics, 120:15-16, https://doi.org/10.1080/00268976.2021.1998931
Tags: FTIR, Nitric Acid
2020, Steiner, A.K., et al., Observed Temperature Changes in the Troposphere and Stratosphere from 1979 to 2018, Journal of Climate, 33(19), 8165–8194, https://doi.org/10.1175/JCLI-D-19-0998.1
Tags: Lidar, Temperature
2018, Geddes, A., et al., Python-based dynamic scheduling assistant for atmospheric measurements by Bruker instruments using OPUS, Applied Optics, 57(4), 689-691
Tags: Algorithm, FTIR
2016, Sica, R.J., A. Haefele, Retrieval of water vapor mixing ratio from a multiple channel Raman-scatter lidar using an optimal estimation method, Applied Optics, 55, 763-777
Tags: H2O, Lidar
2015, Sica, R., Haefele, A., Retrieval of temperature from a multiple-channel Rayleigh-scatter lidar using an optimal estimation method, Applied Optics, 54, 1872–1889
Tags: Lidar, Temperature
2015, Pattantyús-Ábrahám, M., W. Steinbrecht, Temperature Trends over Germany from Homogenized Radiosonde Data, Journal of Climate, 28, 5699–5715, https://doi.org/10.1175/JCLI-D-14-00814.1
Tags: Sonde, Temperature, Trends
2013, Kuang, S., M. J. Newchurch, J. Burris, and X. Liu, Ground-based lidar for atmospheric boundary layer ozone measurements, Applied Optics, 52, 3557-3566
Tags: Lidar, Ozone
2008, Vogelmann, H., T. Trickl, Wide-range sounding of free-tropospheric water vapor with a differential-absorption lidar (DIAL) at a high-altitude station, Applied Optics, 47, 2116-2132
Tags: H2O, Lidar