32 citations as recorded by crossref.

1. Hydroxyl layer: Mean state and trends at midlatitudes M. Grygalashvyly et al.
2. Long‐term trends and the effect of solar cycle variations on mesospheric winter temperatures over Longyearbyen, Svalbard (78°N) S. Holmen et al.
3. Variability of the mesopause temperature and concentrations of reactive components of the mid-latitude atmosphere during sudden stratospheric warmings I. Medvedeva & A. Semenov
4. Gravity wave mixing effects on the OH*-layer E. Becker et al.
5. Analysis of 24 years of mesopause region OH rotational temperature observations at Davis, Antarctica – Part 1: long-term trends W. French et al.
6. Analytical Approximations of the Characteristics of Nighttime Hydroxyl on Mars and Intra-Annual Variations D. Shaposhnikov et al.
7. Variability of the Brunt–Väisälä frequency at the OH∗-airglow layer height at low and midlatitudes S. Wüst et al.
8. The airglow layer emission altitude cannot be determined unambiguously from temperature comparison with lidars T. Dunker
9. Mesospheric temperature and atomic oxygen response during the January 2009 major stratospheric warming M. Shepherd et al.
10. Variability of the Brunt–Väisälä frequency at the OH* layer height S. Wüst et al.
11. Effective Emission Heights of Various OH Lines From X‐Shooter and SABER Observations of a Passing Quasi‐2‐Day Wave S. Noll et al.
12. Neutral temperatures at 90 km altitude over Svalbard (78°N 16°E), 2002–2019, derived from meteor radar observations C. Hall & M. Tsutsumi
13. Simplified Relations for the Martian Night-Time OH* Suitable for the Interpretation of Observations M. Grygalashvyly et al.
14. Hydroxyl layer: trend of number density and intra-annual variability G. Sonnemann et al.
15. Hydroxyl airglow observations for investigating atmospheric dynamics: results and challenges S. Wüst et al.
16. Long-term development of short-period gravity waves in middle Europe D. Offermann et al.
17. Influence of sudden stratospheric warming on the mesosphere/lower thermosphere from the hydroxyl emission observations and numerical simulations I. Medvedeva et al.
18. Analytical Approximations of the Characteristics of Nighttime Hydroxyl on Mars and Intra-Annual Variations D. Shaposhnikov et al.
19. Degradation of near infrared and shortwave infrared imager performance due to atmospheric scattering of diffuse night illumination R. Vollmerhausen
20. Large‐Amplitude Mountain Waves in the Mesosphere Observed on 21 June 2014 During DEEPWAVE: 1. Wave Development, Scales, Momentum Fluxes, and Environmental Sensitivity M. Taylor et al.
21. Improved estimates for neutral air temperatures at 90 km and 78°N using satellite and meteor radar data M. Dyrland et al.
22. On the relationship of energetic particle precipitation and mesopause temperature F. Enengl et al.
23. Temperature trends at 90 km over Svalbard, Norway (78°N 16°E), seen in one decade of meteor radar observations C. Hall et al.
24. Mesospheric OH layer altitude at midlatitudes: variability over the Sierra Nevada Observatory in Granada, Spain (37° N, 3° W) M. García-Comas et al.
25. Analytical Approximations of the Characteristics of Nighttime Hydroxyl on Mars and Intra-Annual Variations D. Shaposhnikov et al.
26. Several notes on the OH* layer M. Grygalashvyly
27. Mesospheric temperatures derived from three decades of hydroxyl airglow measurements from Longyearbyen, Svalbard (78°N) S. Holmen et al.
28. Variability of OH(3–1) emission altitude from 2003 to 2011: Long-term stability and universality of the emission rate–altitude relationship C. von Savigny
29. Observations of OH airglow from ground, aircraft, and satellite: investigation of wave-like structures before a minor stratospheric warming S. Wüst et al.
30. Morphology of the Excited Hydroxyl in the Martian Atmosphere: A Model Study—Where to Search for Airglow on Mars? D. Shaposhnikov et al.
31. Multi-instrument study of the mesosphere-lower thermosphere dynamics at 80°N during the major SSW in January 2019 M. Shepherd et al.
32. Longitudinal variations of the hydroxyl emission. 2. Height of the emitting layer, vibrational temperature, and intensity A. Semenov et al.