Premium
Characteristics of ripple structures revealed in OH airglow images
Author(s) -
Li Jing,
Li Tao,
Dou Xiankang,
Fang Xin,
Cao Bing,
She ChiaoYao,
Nakamura Takuji,
Manson Alan,
Meek Chris,
Thorsen Denise
Publication year - 2017
Publication title -
journal of geophysical research: space physics
Language(s) - English
Resource type - Journals
eISSN - 2169-9402
pISSN - 2169-9380
DOI - 10.1002/2016ja023538
Subject(s) - mesopause , airglow , instability , geology , atmospheric sciences , lidar , wind shear , convection , convective instability , atmosphere (unit) , ridge , ripple , richardson number , mesosphere , climatology , wind speed , meteorology , physics , remote sensing , stratosphere , mechanics , turbulence , paleontology , oceanography , quantum mechanics , voltage
Abstract Small‐scale ripple structures observed in OH airglow images are most likely induced by either dynamic instability due to large wind shear or convective instability due to superadiabatic lapse rate. Using the data set taken in the mesopause region with an OH all‐sky imager at Yucca Ridge Field Station, Colorado (40.7°N, 104.9°W), from September 2003 to December 2005, we study the characteristics and seasonal variations of ripple structures. By analyzing the simultaneous background wind and temperature observed by the nearby sodium temperature/wind lidar at Fort Collins, Colorado (40.6°N, 105°W), and a nearby medium‐frequency radar at Platteville, Colorado (40.2°N, 105.8°W), we are able to statistically study the possible relation between ripples and the background atmosphere conditions. Characteristics and seasonal variations of ripples are presented in detail in this study. The occurrence frequency of ripples exhibits clear seasonal variability, with peak in autumn. The occurrence of ripples shows a local time dependence, which is most likely associated with the solar tides. The lifetime and spatial scale of these ripples are typically 5–20 min and 5–10 km, respectively, and most of the ripples move preferentially either southward or northward. However, more than half of the observed ripples do not advect with background flow; they have higher Richardson numbers than those ripples that advect with background flow. It is possible that they are not instability features but wave structures that are hard to be distinguished from the real instability features.