Your search keyword '"Criddle, Neal R."' showing total 9 results

1. THE DEEP PROPAGATING GRAVITY WAVE EXPERIMENT (DEEPWAVE) : An Airborne and Ground-Based Exploration of Gravity Wave Propagation and Effects from Their Sources throughout the Lower and Middle Atmosphere

Author

Fritts, David C., Smith, Ronald B., Taylor, Michael J., Doyle, James D., Eckermann, Stephen D., Dörnbrack, Andreas, Rapp, Markus, Williams, Bifford P., Pautet, P.-Dominique, Bossert, Katrina, Criddle, Neal R., Reynolds, Carolyn A., Reinecke, P. Alex, Uddstrom, Michael, Revell, Michael J., Turner, Richard, Kaifler, Bernd, Wagner, Johannes S., Mixa, Tyler, Kruse, Christopher G., Nugent, Alison D., Watson, Campbell D., Gisinger, Sonja, Smith, Steven M., Lieberman, Ruth S., Laughman, Brian, Moore, James J., Brown, William O., Haggerty, Julie A., Rockwell, Alison, Stossmeister, Gregory J., Williams, Steven F., Hernandez, Gonzalo, Murphy, Damian J., Klekociuk, Andrew R., Reid, Iain M., and Ma, Jun

Published

2016

2. Comparison of rayleigh-scatter and sodium resonance lidar temperatures

Author

Sox Leda, Wickwar Vincent B., Yuan Tao, and Criddle Neal R.

Subjects

Physics, QC1-999

Abstract

We present an unprecedented comparison of temperature measurements from the Rayleigh-scatter (RS) and sodium (Na) lidar techniques. The extension of the RS technique into the lower thermosphere that has been achieved by the group at Utah State University (USU), enables simultaneous, common-volume measurements by the two lidar systems hosted in the Atmospheric Lidar Observatory at USU. The two lidars’ nightly averaged temperatures from 80-105 km, based on 19 nights of observations, are explored.

Published

2018

3. Simultaneous Rayleigh-Scatter and Sodium Resonance Lidar Temperature Comparisons in the Mesosphere-Lower Thermosphere

Author

Sox, Leda, Wickwar, Vincent B., Yuan, Tao, Criddle, Neal R., and American Geophysical Union

Subjects

sodium lidar, atmospheric temperature, upper atmosphere, Physics, Rayleigh lidar, mesosphere, lower thermosphere

Abstract

The Utah State University (USU) campus (41.7°N, 111.8°W) hosts a unique upper atmospheric observatory that houses both a high-power, large-aperture Rayleigh lidar and a Na lidar. For the first time, we will present 19 nights of coordinated temperature measurements from the two lidars, overlapping in the 80–110 km observational range, over one annual cycle (summer 2014 to summer 2015). This overlap has been achieved through upgrades to the existing USU Rayleigh lidar that increased its observational altitude from 45–95 to 70–115 km and by relocating the Colorado State Na lidar to the USU campus. Previous climatological comparisons between Rayleigh and Na lidar temperatures have suggested that significant temperature differences exist between the two techniques. This new comparison aims to further these previous studies by using simultaneous, common-volume observations. The present comparison showed the best agreement between 85 and 95 km, with a temperature difference, averaged over the whole data set, of about 1.1 ± 0.5 K. Larger differences occurred above and below these altitudes with the Rayleigh temperatures being colder by about 3.5 ± 0.5 K at 82 km and warmer by up to 9.1 ± 3.5 K above 95 km.

Published

2018

4. Comparison of Coincident Rayleigh-Scatter and Sodium Resonance Lidar Temperature Measurements from the Mesosphere-Lower-Thermosphere Region

Author

Sox, Leda, Wickwar, Vincent B., Criddle, Neal R., Yuan, Tao, and American Geophysical Union

Subjects

Mesosphere-Lower-Thermosphere Region, Physics, Coincident Rayleigh-Scatter, Measurements, Optics, Sodium Resonance Lidar Temperature, Atmospheric Sciences

Abstract

There are relatively few instruments that have the capabilities to make near continuous measurements of the mesosphere-lower-thermosphere (MLT) region. Rayleigh scatter and resonance lidars, particularly sodium resonance lidar, have been the two dominant ground-based techniques for acquiring mesosphere and MLT vertical temperature profiles, respectively, for more than two decades. With these measurements, the dynamics (gravity waves, tides) and long-term temperature trends (upper atmosphere cooling) of the MLT region can be studied. The Utah State University (USU; 41.7º N, 111.8º W) campus hosts a unique upper atmospheric observatory which houses both a high-power, large-aperture Rayleigh lidar and a sodium resonance Doppler lidar. For the first time, we will present coordinated, night-time averaged temperatures, overlapping in observational range (80-110 km), from the two lidars. This overlap has been achieved through the relocation of the sodium lidar from Colorado State University to USU’s campus and through upgrades to the existing USU Rayleigh lidar which elevated its observational range from 45-90 km to 70-115 km. The comparison of the two sets of temperature measurements is important because the two lidar techniques derive temperature profiles using different scattering processes and analysis methods. Furthermore, previous climatological comparisons, between Rayleigh and sodium lidar, [Argall and Sica, 2007] have suggested that significant temperature differences can occur. This comparison aims to explore possible temperature effects from the differences in the two measurement techniques.

Published

2015

5. Coordinated investigation of mid-latitude upper mesospheric temperature inversion layers and the associated gravity wave forcing by Na lidar and Advanced Mesospheric Temperature Mapper at Logan, Utah (42°N)

Author

Yuan, Tao, Pautet, Pierre-Dominique, Zhao, Yucheng, Cai, Xuguang, Criddle, Neal R., Taylor, Michael J., Pendleton, William R., Jr., and American Geophysical Union

Subjects

Atmospheric Sciences

Abstract

Mesospheric inversion layers (MIL) are well studied in the literature but their relationship to the dynamic feature associated with the breaking of atmospheric waves in the mesosphere/lower thermosphere (MLT) region are not well understood. Two strong MIL events (ΔT ~30 K) were observed above 90 km during a 6 day full diurnal cycle Na lidar campaign conducted from 6 August to 13 August Logan, Utah (42°N, 112°W). Colocated Advanced Mesospheric Temperature Mapper observations provided key information on concurrent gravity wave (GW) events and their characteristics during the nighttime observations. The study found both MILs were well correlated with the development and presence of an unstable region ~2 km above the MIL peak altitudes and a highly stable region below, implicating the strengthening of MIL is likely due to the increase of downward heat flux by the enhanced saturation of gravity wave, when it propagates through a highly stable layer. Each MIL event also exhibited distinct features: one showed a downward progression most likely due to tidal-GW interaction, while the peak height of the other event remained constant. During further investigation of atmospheric stability surrounding the MIL structure, lidar measurements indicate a sharp enhancement of the convective stability below the peak altitude of each MIL. We postulate that the sources of these stable layers were different; one was potentially triggered by concurrent large tidal wave activity and the other during the passage of a strong mesospheric bore.

Published

2015

6. Coordinated investigation of midlatitude upper mesospheric temperature inversion layers and the associated gravity wave forcing by Na lidar and Advanced Mesospheric Temperature Mapper in Logan, Utah

Author

Yuan, Tao, Pautet, Pierre-Dominique, Zhao, Y., Cai, Xuguang, Taylor, Michael J., and Criddle, Neal R.

Subjects

Wave propagation, Physics, MIL, Na Lidar, AMTM, Mesospheric dynamics, Acoustic-gravity waves, Tides and planetary waves, Remote sensing, Atmospheric Sciences

Abstract

Mesospheric inversion layers (MIL) are well studied in the literature but their relationship to the dynamic feature associated with the breaking of atmospheric waves in the mesosphere/lower thermosphere (MLT) region are not well understood. Two strong MIL events (ΔT ~30 K) were observed above 90 km during a 6 day full diurnal cycle Na lidar campaign conducted from 6 August to 13 August Logan, Utah (42°N, 112°W). Colocated Advanced Mesospheric Temperature Mapper observations provided key information on concurrent gravity wave (GW) events and their characteristics during the nighttime observations. The study found both MILs were well correlated with the development and presence of an unstable region ~2 km above the MIL peak altitudes and a highly stable region below, implicating the strengthening of MIL is likely due to the increase of downward heat flux by the enhanced saturation of gravity wave, when it propagates through a highly stable layer. Each MIL event also exhibited distinct features: one showed a downward progression most likely due to tidal-GW interaction, while the peak height of the other event remained constant. During further investigation of atmospheric stability surrounding the MIL structure, lidar measurements indicate a sharp enhancement of the convective stability below the peak altitude of each MIL. We postulate that the sources of these stable layers were different; one was potentially triggered by concurrent large tidal wave activity and the other during the passage of a strong mesospheric bore.

Published

2014

7. Investigating Mountain Waves in MTM Image Data at Cerro Pachon, Chile

Author

Criddle, Neal R, Taylor, Michael J., Pautet, P. D., Zhao, Y., Swenson, G., Franke, S., and Liu, A.

Subjects

Physics

Abstract

Gravity waves are important drivers of chemical species mixing, energy and momentum transfer into the MLT (~80 - 100 km) region. As part of a collaborative program involving instruments from several institutions Utah State University has operated a Mesospheric Temperature Mapper (MTM) at the new Andes Lidar Observatory (ALO) on Cerro Pachon (30.2°S, 70.7°W) Since August 2009. A primary goal of this program is to quantify the impact of mountain waves on the MLT region. The Andes region is an excellent natural laboratory for investigating gravity wave influences on the MLT region, especially the study of mountain waves, created by strong winds blowing in from the Pacific Ocean. Large amplitude mountain waves have been measured in the stratosphere on many occasions, however, their penetration into the mesosphere has only recently been recorded (Smith et. al., 2009), as shown in the all sky OH image to the left. In this study we have used MTM image data in coordination with all sky imager, meteor wind radar and other wind measurements to investigate the properties of several mountain wave events observed over Cerro Pachon.

Published

2012

8. Seasonal Variability and Dynamics of Mesospheric Gravity Waves Over the Andes

Author

Criddle, Neal R, Taylor, Michael J., Pautet, P. D., and Zhao, Y.

Subjects

Posters, Physics, Other Applied Mathematics, Andes, Other Physics, Gravity Waves, Mountain Waves, Mesosphere, Atmospheric Sciences

Abstract

The ALO is a new facility developed for atmospheric research, located at the foot of the Andes mountain range in Cerro Pachon, Chile (30.2°S, 70.7°W). As part of a collaborative program, Utah State has a Mesospheric Temperature Mapper (MTM) on site, which is used to study short period gravity wave dynamics and temperature variations in the mesosphere-lower thermosphere region. The MTM began taking measurements of the OH(6,2) and O2(0,1) spectral bands in August 2009 and a complete profile of seasonal variation in gravity wave characteristics has been created for August 2009 through August 2010 using the OH(6,2) Band. The primary goal of this program is to Quantify seasonal variability of gravity wave structures. Compare and contrast seasonal directionality and characteristic variability with results from the Maui-MALT oceanic site. Quantify mountain wave observations, their frequency, images, characteristics and seasonal variability. Seasonal variability for gravity wave structures at this site is shown. New evidence for a number of mountain wave events has been observed during the winter months. Future work includes investigating yearly repeatability, which is seen at other sites, and continued investigation of unique events occurring over the Andes mountain range.

Published

2011

9. First Year Investigation of Gravity Waves and Temperature Variability over the Andes

Author

Pugmire, Jonathan, Criddle, Neal R, Taylor, Michael J., Pautet, Dominique, and Zhao, Yucheng

Subjects

Physics, Atmospheric Sciences

Abstract

The Andes region is an excellent natural laboratory for investigating gravity wave influences on the Upper Mesospheric and Lower Thermospheric (MLT) dynamics: during the summer months the dominant gravity waves result from deep convection arising from severe thunderstorms over the continent to the east. In winter this convective activity is expected to be replaced by strong orographic forcing due to intense prevailing zonal winds blowing eastward from the Pacific Ocean and suddenly encountering the towering Andes mountain range (6000m). This creates large amplitude mountain waves that have been measured well into the stratosphere and most recently penetrate occasionally into the mesosphere (Smith et al., 2009). The instrument suite that comprised the very successful Maui-MALT program was recently re-located to a new Andes Lidar Observatory (ALO) located at Cerro Pachon, Chile (30.2°S 70.7°W) to obtain in-depth seasonal measurements of MLT dynamics over the Andes mountains. As part of the instrument set the Utah State University CEDAR Mesospheric Temperature Mapper (MTM) has operated continuously since August 2009 measuring the near infrared OH(6,2) band and the O2(0,1) Atmospheric band intensity and temperature perturbations. This poster focuses on an analysis of nightly OH temperatures and the observed variability, as well as selected gravity wave events illustrating the high wave activity and its diversity.

Published

2010