Your search keyword '"Katrina Bossert"' showing total 9 results

1. Secondary Gravity Waves Generated by Breaking Mountain Waves Over Europe

Author

Chistopher J. Heale, Andreas Dörnbrack, Christoph Jacobi, Gunter Stober, Jonathan B. Snively, Katrina Bossert, Sharon L. Vadas, and Lars Hoffmann

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, MLT, Forcing (mathematics), 01 natural sciences, Physics::Geophysics, Atmosphere, Filter (large eddy simulation), Mountain wave, ddc:550, Earth and Planetary Sciences (miscellaneous), Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, thermosphere, Verkehrsmeteorologie, thermospheric winds, Gravitational wave, Breaking wave, Geophysics, Wavelength, Amplitude, Space and Planetary Science, Physics::Space Physics, Astrophysics::Earth and Planetary Astrophysics, Thermosphere, Geology

Abstract

A strong mountain wave, observed over Central Europe on 12 January 2016, is simulated in 2D under two fixed background wind conditions representing opposite tidal phases. The aim of the simulation is to investigate the breaking of the mountain wave and subsequent generation of nonprimary waves in the upper atmosphere. The model results show that the mountain wave first breaks as it approaches a mesospheric critical level creating turbulence on horizontal scales of 8–30 km. These turbulence scales couple directly to horizontal secondary waves scales, but those scales are prevented from reaching the hermosphere by the tidal winds, which act like a filter. Initial secondary waves that can reach the thermosphere range from 60 to 120 km in horizontal scale and are influenced by the scales of the horizontal and vertical forcing associated with wave breaking at mountain wave zonal phase width, and horizontal wavelength scales. Large-scale nonprimary waves dominate over the whole duration of the simulation with horizontal scales of 107–300 km and periods of 11–22 minutes. The thermosphere winds heavily influence the time-averaged spatial distribution of wave forcing in the thermosphere, which peaks at 150 km altitude and occurs both westward and eastward of the source in the 2 UT background simulation and primarily eastward of the source in the 7 UT background simulation. The forcing amplitude is ∼2× that of the primary mountain wave breaking and dissipation. This suggests that nonprimary waves play a significant role in gravity waves dynamics and improved understanding of the thermospheric winds is crucial to understanding their forcing distribution.

Published

2020

2. Momentum Flux Spectra of a Mountain Wave Event Over New Zealand

Author

Andrew J. Spargo, David C. Fritts, John M. C. Plane, Stephen D. Eckermann, Andrew D. MacKinnon, Katrina Bossert, Damian J. Murphy, C. J. Heale, Jonathan B. Snively, Bifford P. Williams, and Iain M. Reid

Subjects

Physics, Atmospheric Science, Momentum (technical analysis), 010504 meteorology & atmospheric sciences, Gravitational wave, 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Spectral line, Wavelength, Geophysics, Altitude, Amplitude, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous), 14. Life underwater, Gravity wave, Thermosphere, 0105 earth and related environmental sciences

Abstract

During the Deep Propagating Gravity Wave Experiment (DEEPWAVE) 13 July 2014 research flight over the South Island of New Zealand, a multiscale spectrum of mountain waves (MWs) was observed. High‐resolution measurements of sodium densities were available from ~70 to 100 km for the duration of this flight. A comprehensive technique is presented for obtaining temperature perturbations, T′, from sodium mixing ratios over a range of altitudes, and these T′ were used to calculate the momentum flux (MF) spectra with respect to horizontal wavelengths, λH, for each flight segment. Spectral analysis revealed MWs with spectral power centered at λH of ~80, 120, and 220 km. The temperature amplitudes of these MWs varied between the four cross‐mountain flight legs occurring between 6:10UT and 9:10UT. The average spectral T′ amplitudes near 80 km in altitude ranged from 7–13 K for the 220 km λH MW and 4–8 K for the smaller λH MWs. These amplitudes decayed significantly up to 90 km, where a critical level for MWs was present. The average MF per unit mass near 80 km in altitude ranged from ~13 to 60 m²/s² across the varying spectra over the duration of the research flight and decayed to ~0 by 88 km in altitude. These MFs are large compared to zonal means and highlight the importance of MWs in the momentum budget of the mesosphere and lower thermosphere at times when they reach these altitudes.

Published

2018

3. Secondary gravity wave generation over New Zealand during the DEEPWAVE campaign

Author

Katrina Bossert, Michael J. Taylor, P. D. Pautet, David C. Fritts, Jonathan B. Snively, Bifford P. Williams, C. J. Heale, and Christopher G. Kruse

Subjects

Atmospheric Science, Momentum (technical analysis), 010504 meteorology & atmospheric sciences, Meteorology, Gravitational wave, 01 natural sciences, Wavelength, Geophysics, Lidar, Altitude, Space and Planetary Science, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), Mountain wave, Gravity wave, 010303 astronomy & astrophysics, Stratosphere, Geology, 0105 earth and related environmental sciences

Abstract

Multiple events during the Deep Propagating Gravity Wave Experiment measurement program revealed mountain wave (MW) breaking at multiple altitudes over the Southern Island of New Zealand. These events were measured during several research flights from the National Science Foundation/National Center for Atmospheric Research Gulfstream V aircraft, utilizing a Rayleigh lidar, an Na lidar, and an Advanced Mesospheric Temperature Mapper simultaneously. A flight on 29 June 2014 observed MWs with horizontal wavelengths of ~80–120 km breaking in the stratosphere from ~10 to 50 km altitude. A flight on 13 July 2014 observed a horizontal wavelength of ~200–240 km MW extending from 20 to 90 km in altitude before breaking. Data from these flights show evidence for secondary gravity wave (SGW) generation near the breaking regions. The horizontal wavelengths of these SGWs are smaller than those of the breaking MWs, indicating a nonlinear generation mechanism. These observations reveal some of the complexities associated with MW breaking and the implications this can have on momentum fluxes accompanying SGWs over MW breaking regions.

Published

2017

4. Numerical modeling of a multiscale gravity wave event and its airglow signatures over Mount Cook, New Zealand, during the DEEPWAVE campaign

Author

D. C. Fritts, Pierre-Dominique Pautet, C. J. Heale, Katrina Bossert, Michael J. Taylor, Jonathan B. Snively, and Blackwell Publishing Ltd

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Physics, Airglow, Breaking wave, Geophysics, Gravity waves, Instability, Modeling, Mountain waves, 010502 geochemistry & geophysics, 01 natural sciences, Vortex, Temperature gradient, Amplitude, Convective instability, Space and Planetary Science, Earth and Planetary Sciences (miscellaneous), Gravity wave, Stratosphere, Geology, 0105 earth and related environmental sciences

Abstract

A 2-D nonlinear compressible model is used to simulate a large-amplitude, multiscale mountain wave event over Mount Cook, NZ, observed as part of the Deep Propagating Gravity Wave Experiment (DEEPWAVE) campaign and to investigate its observable signatures in the hydroxyl (OH) layer. The campaign observed the presence of a _x=200ækm mountain wave as part of the 22nd research flight with amplitudes of >20æK in the upper stratosphere that decayed rapidly at airglow heights. Advanced Mesospheric Temperature Mapper (AMTM) showed the presence of small-scale (25_28ækm) waves within the warm phase of the large mountain wave. The simulation results show rapid breaking above 70ækm altitude, with the preferential formation of almost-stationary vortical instabilities within the warm phase front of the mountain wave. An OH airglow model is used to identify the presence of small-scale wave-like structures generated in situ by the breaking of the mountain wave that are consistent with those seen in the observations. While it is easy to interpret these feature as waves in OH airglow data, a considerable fraction of the features are in fact instabilities and vortex structures. Simulations suggest that a combination of a large westward perturbation velocity and shear, in combination with strong perturbation temperature gradients, causes both dynamic and convective instability conditions to be met particularly where the wave wind is maximized and the temperature gradient is simultaneously minimized. This leads to the inevitable breaking and subsequent generation of smaller-scale waves and instabilities which appear most prominent within the warm phase front of the mountain wave. ©2017. American Geophysical Union. All Rights Reserved.

Published

2017

5. Dynamics of Orographic Gravity Waves Observed in the Mesosphere over the Auckland Islands during the Deep Propagating Gravity Wave Experiment (DEEPWAVE)

Author

Ronald B. Smith, Jun Ma, Dave Broutman, James D. Doyle, P. D. Pautet, Katrina Bossert, David C. Fritts, Michael J. Taylor, Stephen D. Eckermann, and Bifford P. Williams

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Gravitational wave, Airglow, Breaking wave, Geophysics, 010502 geochemistry & geophysics, Fourier model, Atmospheric sciences, 01 natural sciences, Altitude, Wave field, Gravity wave, Physics::Atmospheric and Oceanic Physics, Geology, 0105 earth and related environmental sciences, Orographic lift

Abstract

On 14 July 2014 during the Deep Propagating Gravity Wave Experiment (DEEPWAVE), aircraft remote sensing instruments detected large-amplitude gravity wave oscillations within mesospheric airglow and sodium layers at altitudes z ~ 78–83 km downstream of the Auckland Islands, located ~1000 km south of Christchurch, New Zealand. A high-altitude reanalysis and a three-dimensional Fourier gravity wave model are used to investigate the dynamics of this event. At 0700 UTC when the first observations were made, surface flow across the islands’ terrain generated linear three-dimensional wave fields that propagated rapidly to z ~ 78 km, where intense breaking occurred in a narrow layer beneath a zero-wind region at z ~ 83 km. In the following hours, the altitude of weak winds descended under the influence of a large-amplitude migrating semidiurnal tide, leading to intense breaking of these wave fields in subsequent observations starting at 1000 UTC. The linear Fourier model constrained by upstream reanalysis reproduces the salient aspects of observed wave fields, including horizontal wavelengths, phase orientations, temperature and vertical displacement amplitudes, heights and locations of incipient wave breaking, and momentum fluxes. Wave breaking has huge effects on local circulations, with inferred layer-averaged westward flow accelerations of ~350 m s−1 h−1 and dynamical heating rates of ~8 K h−1, supporting recent speculation of important impacts of orographic gravity waves from subantarctic islands on the mean circulation and climate of the middle atmosphere during austral winter.

Published

2016

6. 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

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

Subjects

Institut für Physik der Atmosphäre, Lidar, Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, Verkehrsmeteorologie, Gravity Wave DEEPWAVE, Atmospheric sciences, 01 natural sciences, Atmospheric research, Mesosphere, Atmosphere, 0103 physical sciences, Gravity wave, Rayleigh lidar, 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences, Orographic lift

Abstract

The Deep Propagating Gravity Wave Experiment (DEEPWAVE) was designed to quantify gravity wave (GW) dynamics and effects from orographic and other sources to regions of dissipation at high altitudes. The core DEEPWAVE field phase took place from May through July 2014 using a comprehensive suite of airborne and ground-based instruments providing measurements from Earth’s surface to ∼100 km. Austral winter was chosen to observe deep GW propagation to high altitudes. DEEPWAVE was based on South Island, New Zealand, to provide access to the New Zealand and Tasmanian “hotspots” of GW activity and additional GW sources over the Southern Ocean and Tasman Sea. To observe GWs up to ∼100 km, DEEPWAVE utilized three new instruments built specifically for the National Science Foundation (NSF)/National Center for Atmospheric Research (NCAR) Gulfstream V (GV): a Rayleigh lidar, a sodium resonance lidar, and an advanced mesosphere temperature mapper. These measurements were supplemented by in situ probes, dropsondes, and a microwave temperature profiler on the GV and by in situ probes and a Doppler lidar aboard the German DLR Falcon. Extensive ground-based instrumentation and radiosondes were deployed on South Island, Tasmania, and Southern Ocean islands. Deep orographic GWs were a primary target but multiple flights also observed deep GWs arising from deep convection, jet streams, and frontal systems. Highlights include the following: 1) strong orographic GW forcing accompanying strong cross-mountain flows, 2) strong high-altitude responses even when orographic forcing was weak, 3) large-scale GWs at high altitudes arising from jet stream sources, and 4) significant flight-level energy fluxes and often very large momentum fluxes at high altitudes.

Published

2016

7. Large-Amplitude Mountain Waves in the Mesosphere Accompanying Weak Cross-Mountain Flow During DEEPWAVE Research Flight RF22

Author

David C. Fritts, Ronald B. Smith, Stephen D. Eckermann, Katrina Bossert, Bifford P. Williams, Iain M. Reid, Michael J. Taylor, John M. C. Plane, Markus Rapp, P.-Dominique Pautet, Tyler Mixa, Andreas Dörnbrack, Simon Vosper, Damian J. Murphy, and Christopher G. Kruse

Subjects

Atmospheric Science, Institut für Physik der Atmosphäre, forcing ceases, 010504 meteorology & atmospheric sciences, Verkehrsmeteorologie, Airglow, Jet stream, Effects of high altitude on humans, Atmospheric sciences, 01 natural sciences, 010305 fluids & plasmas, Mesosphere, Geophysics, Altitude, Lidar, Space and Planetary Science, Weak orographic forcing, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), mesospheric maintain waves, Gravity wave, Stratosphere, Geology, 0105 earth and related environmental sciences

Abstract

Mountain wave (MW) propagation and dynamics extending into the upper mesosphere accompanying weak forcing are examined using in situ and remote‐sensing measurements aboard the National Science Foundation/National Center for Atmospheric Research Gulfstream V (GV) research aircraft and the German Aerospace Center Falcon. The measurements were obtained during Falcon flights FF9 and FF10 and GV Research Flight RF22 of the Deep Propagating Gravity Wave Experiment (DEEPWAVE) performed over Mount Cook, New Zealand, on 12 and 13 July 2014. In situ measurements revealed both trapped lee waves having zonal wavelengths of λₓ ~ 12 km and less, and larger‐scale, vertically propagating MWs primarily at λₓ ~ 20–60 km and ~100–300 km extending from west to ~400 km east of Mount Cook. GV Rayleigh lidar measurements from 25‐ to 60‐km altitudes showed that the weak forcing and zonal winds that increased from ~12 m/s at 12 km to ~40 and 130 m/s at 30 and 55 km, respectively, enabled largely linear MW propagation and strong amplitude growth with altitude into the mesosphere. GV Na lidar and airglow imager measurements revealed an extensive MW response from ~70 to 87 km with large amplitudes and vertical displacements at λₓ ~ 40–300 km but with both decreasing with altitude approaching a critical level near 90 km. These MWs exhibited large‐scale MW breaking and among the largest sustained momentum fluxes observed in the mesosphere. UK Met Office Unified Model simulations of the RF22 MW event captured many aspects of the observed MW field and revealed that despite the dominant large‐scale MW responses in the stratosphere, the major momentum fluxes accompanied smaller‐scale waves.

Published

2018

8. Does Strong Tropospheric Forcing Cause Large-Amplitude Mesospheric Gravity Waves? A DEEPWAVE Case Study

Author

Markus Rapp, P.-Dominique Pautet, Bernd Kaifler, Martina Bramberger, Michael J. Taylor, Benjamin Witschas, Andreas Dörnbrack, David C. Fritts, Katrina Bossert, Christian Mallaun, Simon Vosper, Andrew Orr, Bifford P. Williams, Benedikt Ehard, and American Geophysical Union

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, Forcing (mathematics), 010502 geochemistry & geophysics, Atmospheric sciences, 01 natural sciences, Mountain Waves, Physics::Geophysics, Atmospheric Sciences, forcing conditions, Troposphere, Altitude, Earth and Planetary Sciences (miscellaneous), atmosphere from troposhere to mesosphere, Gravity wave, Stratosphere, Physics::Atmospheric and Oceanic Physics, 0105 earth and related environmental sciences, Lidar, Verkehrsmeteorologie, Oberpfaffenhofen, Geophysics, Amplitude, 13. Climate action, Space and Planetary Science, Tropopause, Geology

Abstract

The DEEPWAVE (deep-propagating wave experiment) campaign was designed for an airborne and ground-based exploration of gravity waves from their tropospheric sources up to their dissipation at high altitudes. It was performed in and around New Zealand from 24 May till 27 July 2014, being the first comprehensive field campaign of this kind. A variety of airborne instruments was deployed onboard the research aircraft NSF/NCAR Gulfstream V (GV) and the DLR Falcon. Additionally, ground-based measurements were conducted at different sites across the southern island of New Zealand, including the DLR Rayleigh lidar located at Lauder (45.04 S, 169.68 E). We focus on the intensive observing period (IOP) 10 on the 4 July 2014, when strong WSW winds of about 40 m/s at 700 hPa provided intense forcing conditions for mountain waves. At tropopause level, the horizontal wind exceeded 50 m/s and favored the vertical propagation of gravity waves into the stratosphere. The DLR Rayleigh Lidar measured temperature fluctuations with peak-to-peak amplitudes of about 20 K in the mesosphere (60 km to 80 km MSL) over a period of more than 10 hours. Two research flights were conducted by the DLR Falcon (Falcon Flight 04 and 05) during this period with straight transects (Mt. Aspiring 2a) over New Zealand´s Alps at three different flight-levels around the tropopause (approx. 11 km MSL). These research flights were coordinated with the GV (Research Flight 16) where the largest mountain wave amplitudes at flight-level (approx. 13 km MSL) were measured during DEEPWAVE. Additionally a first analysis of Falcon's in-situ flight-level data revealed amplitudes in the vertical wind larger than 4 m/s at all altitudes in the vicinity of the highest peaks of the Southern Alps. Here, we present a comprehensive picture of the gravity wave characteristics and propagation properties during this interesting gravity wave event. We use the airborne observations combined with a comprehensive set of ground-based measurements consisting of 13 radiosoundings (1.5 hourly interval) together with the DLR Rayleigh lidar. To cover the altitude range from the troposphere to the mesosphere, high-resolution (1 hourly) ECMWF analyses and forecasts are used to estimate the propagation conditions of the excited mountain waves. The goal of our investigation is to find out whether the large amplitude mesospheric gravity waves are caused by the strong tropospheric forcing.

Published

2017

9. Large-amplitude mesospheric response to an orographic wave generated over the Southern Ocean Auckland Islands (50.7°S) during the DEEPWAVE project

Author

Dave Broutman, Michael J. Taylor, Bifford P. Williams, Katrina Bossert, Pierre-Dominique Pautet, Jun Ma, S. D. Eckermann, James D. Doyle, D. C. Fritts, and American Geophysical Union

Subjects

Atmospheric Science, 010504 meteorology & atmospheric sciences, Meteorology, Physics, 01 natural sciences, mesospheric gravity waves, orographic source, Geophysics, Amplitude, Space and Planetary Science, Climatology, 0103 physical sciences, Earth and Planetary Sciences (miscellaneous), 010303 astronomy & astrophysics, Geology, 0105 earth and related environmental sciences, Orographic lift

Abstract

The Deep Propagating Gravity Wave Experiment (DEEPWAVE) project was conducted over New Zealand and the surrounding regions during June and July 2014, to more fully understand the generation, propagation, and effects of atmospheric gravity waves. A large suite of instruments collected data from the ground to the upper atmosphere (~100 km), with several new remote-sensing instruments operating on board the NSF Gulfstream V (GV) research aircraft, which was the central measurement platform of the project. On 14 July, during one of the research flights (research flight 23), a spectacular event was observed as the GV flew in the lee of the sub-Antarctic Auckland Islands (50.7°S). An apparent "ship wave" pattern was imaged in the OH layer (at ~83.5 km) by the Utah State University Advanced Mesospheric Temperature Mapper and evolved significantly over four successive passes spanning more than 4 h. The waves were associated with orographic forcing generated by relatively strong (15-20 m/s) near-surface wind flowing over the rugged island topography. The mountain wave had an amplitude T_ ~ 10 K, a dominant horizontal wavelength ~40 km, achieved a momentum flux exceeding 300 m2 s-2, and eventually exhibited instability and breaking at the OH altitude. This case of deep mountain wave propagation demonstrates the potential for strong responses in the mesosphere arising from a small source under suitable propagation conditions and suggests that such cases may be more common than previously believed. © 2016. American Geophysical Union. All Rights Reserved.

Published

2016