46 citations as recorded by crossref.

1. Spectral Structure of Temperature Variations in the Midlatitude Mesopause Region V. Perminov et al.
2. Long-term trends in Antarctic winter hydroxyl temperatures W. French & A. Klekociuk
3. Morphology of the Excited Hydroxyl in the Martian Atmosphere: A Model Study—Where to Search for Airglow on Mars? D. Shaposhnikov et al.
4. Nighttime O(1D) and corresponding Atmospheric Band emission (762 nm) derived from rocket-borne experiment M. Grygalashvyly et al.
5. The Response of the Airglow of the Mesopause Region to Short-Term Changes in Solar Activity V. Perminov et al.
6. A novel infrared imager for studies of hydroxyl and oxygen nightglow emissions in the mesopause above northern Scandinavia P. Dalin et al.
7. OH airglow observations with two identical spectrometers: benefits of increased data homogeneity in the identification of variations induced by the 11-year solar cycle, the QBO, and other factors C. Schmidt et al.
8. Influence of solar cycle and chemistry on tropical (10°N–15°N) mesopause variabilities K. Ramesh et al.
9. Multiyear variations of time-correlated mesoscale OH temperature perturbations near the mesopause at Maymaga, Tory and Zvenigorod N. Gavrilov et al.
10. Variability of mesopause temperature from the hydroxyl airglow observations over mid-latitudinal sites, Zvenigorod and Tory, Russia V. Perminov et al.
11. The Response of the Airglow of the Mesopause Region to Short-Term Changes in Solar Activity V. Perminov et al.
12. Climatologies of Various OH Lines From About 90,000 X‐Shooter Spectra S. Noll et al.
13. Long-term temperature trend in the mesopause region according to observations of hydroxyl airglow in Zvenigorod V. Perminov et al.
14. Note on consistency between Kalogerakis–Sharma Mechanism (KSM) and two-step mechanism of atmospheric band emission (762 nm) M. Grygalashvyly & G. Sonnemann
15. Lunar Tides in the Mesopause Region Obtained from Summer Temperature of the Hydroxyl Emission Layer N. Pertsev et al.
16. Temperature variations in the mesopause region according to the hydroxyl-emission observations at midlatitudes V. Perminov et al.
17. Trends in the Airglow Temperatures in the MLT Region—Part 2: SABER Observations and Comparisons to Model Simulations T. Huang & M. Vanyo
18. Overview of the temperature response in the mesosphere and lower thermosphere to solar activity G. Beig et al.
19. Seasonal and nighttime behaviors of emissions of hydroxyl and the atmospheric system of molecular oxygen of the midlatitude mesopause V. Perminov & N. Pertsev
20. Simulations of airglow variations induced by the CO2 increase and solar cycle variation from 1980 to 1991 T. Huang
21. Analytical Approximations of the Characteristics of Nighttime Hydroxyl on Mars and Intra-Annual Variations D. Shaposhnikov et al.
22. 15 years of VLT/UVES OH intensities and temperatures in comparison with TIMED/SABER data S. Noll et al.
23. Seasonal variations of the nighttime O(1S) and OH (8‐3) airglow intensity at Adelaide, Australia I. Reid et al.
24. The regular nocturnal course of temperature in the midlatitude mesopause region according to hydroxyl airglow measurements V. Perminov & N. Pertsev
25. Long-Term Temperature Trend in the Mesopause Region from Observations of Hydroxyl Airglow in Zvenigorod V. Perminov et al.
26. Simplified Relations for the Martian Night-Time OH* Suitable for the Interpretation of Observations M. Grygalashvyly et al.
27. Where does Earth’s atmosphere get its energy? A. Kren et al.
28. Study of the mesosphere using wide-field twilight polarization measurements: Early results beyond the polar circle O. Ugolnikov & B. Kozelov
29. Multi-year behaviour of the midnight OH∗ temperature according to observations at Zvenigorod over 2000–2016 V. Perminov et al.
30. Traceability of the Network for Detection of the Mesospheric Change (NDMC) to radiometric standards via a Near Infrared Filter Radiometer S. van den Berg et al.
31. Updated Long‐Term Trends in Mesopause Temperature, Airglow Emissions, and Noctilucent Clouds P. Dalin et al.
32. Analytical Approximations of the Characteristics of Nighttime Hydroxyl on Mars and Intra-Annual Variations D. Shaposhnikov et al.
33. Seasonal temperature variations near the mesopause according to the hydroxyl emission measurements in Zvenigorod V. Perminov
34. Several notes on the OH* layer M. Grygalashvyly
35. Long-Term Changes in the Activity of Wave Disturbances in the Mesopause Region V. Perminov et al.
36. 11-year solar cycle influence on OH (3-1) nightglow observed by OSIRIS A. Li et al.
37. The role of the QBO in the inter-hemispheric coupling of summer mesospheric temperatures P. Espy et al.
38. The responses of the nightglow emissions observed by the TIMED/SABER satellite to solar radiation H. Gao et al.
39. Large- and small-scale periodicities in the mesosphere as obtained from variations in O<sub>2</sub> and OH nightglow emissions R. Singh & D. Pallamraju
40. Temporal evolutions of $$\text {N}_2^+$$ Meinel (1,2) band near $$1.5.\,\upmu \text {m}$$ associated with aurora breakup and their effects on mesopause temperature estimations from OH Meinel (3,1) band T. Nishiyama et al.
41. Gravity wave mixing effects on the OH*-layer E. Becker et al.
42. Analysis of 24 years of mesopause region OH rotational temperature observations at Davis, Antarctica – Part 1: long-term trends W. French et al.
43. Seasonal and Long-Term Changes in the Intensity of O2(b1Σ) and OH(X2Π) Airglow in the Mesopause Region V. Perminov et al.
44. Analytical Approximations of the Characteristics of Nighttime Hydroxyl on Mars and Intra-Annual Variations D. Shaposhnikov et al.
45. Influence of semidiurnal and semimonthly lunar tides on the mesopause as observed in hydroxyl layer and noctilucent clouds characteristics N. Pertsev et al.
46. Long-term trends in the temperature of the mesosphere/lower thermosphere region: 2. Solar response G. Beig