Tropical Cyclone Track Sensitivity in Deformation Steering Flow

Torn, Ryan D.; Elless, Travis J.; Papin, Philippe; Davis, Christopher A.

doi:10.1175/mwr-d-18-0153.1

Cited by 21 publications

(22 citation statements)

References 40 publications

(49 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Following landfall near Rockport, Harvey remained nearly stationary for several days before reemerging in the Gulf of Mexico on 28 August. Harvey's slowed forward motion occurred as it moved into a weak flow region near the saddle point of a deformation steering flow (e.g., Torn et al 2018), characterized by a trough to the north and flanking ridges to the west and east. Heavy rains persisted on the east and northeast side of Harvey in the Texas coastal plain as Harvey's deep tropical moisture was lifted along a frontogenetical coastal front beneath the equatorward entrance region of an upper-level jet.…”

Section: Discussionmentioning

confidence: 99%

The Hurricane Harvey (2017) Texas Rainstorm: Synoptic Analysis and Sensitivity to Soil Moisture

Galarneau

Zeng

2020

Monthly Weather Review

View full text Add to dashboard Cite

A synoptic analysis and soil moisture (SM) sensitivity experiment is conducted on the record-breaking rainstorm in Texas associated with Hurricane Harvey on 26-30 August 2017. The rainstorm occurred as the moist tropical air mass associated with Harvey was lifted along a frontogenetical near-surface coastal baroclinic zone beneath the equatorward entrance region of an upper-level jet streak. The weak steering winds in Harvey's environment, allowing Harvey to remain nearly stationary, were associated with a deformation steering flow pattern characterized by a trough to the north and flanking ridges to the west and east. This pattern has occurred with other notable tropical cyclone rainstorms along the Gulf Coast, except in Harvey's case it contributed to the collocation of deep tropical moisture and a persistent midlatitude lifting mechanism. Motivated by marked increases in SM during the rainstorm, a suite of six numerical simulations is used to test the sensitivity of the Harvey rainstorm (track, intensity, and rainfall) to varying SM. These simulations include dry, realistic, and wet SM conditions and an additional three runs with the initial SM held constant throughout the simulations. The results showed that track and prelandfall intensity were most sensitive to SM. Decreased SM resulted in the 1) development of an anticyclone in the southern plains that steered Harvey farther southwest in Texas, and 2) interruption in the intensification of Harvey in the Gulf of Mexico as dry air in the Yucatan Peninsula was entrained into Harvey's circulation, contributing to a weaker system at landfall. Implications of these findings on the evolution of tropical systems are also discussed.

show abstract

Section: Discussionmentioning

confidence: 99%

The Hurricane Harvey (2017) Texas Rainstorm: Synoptic Analysis and Sensitivity to Soil Moisture

Galarneau

Zeng

2020

Monthly Weather Review

View full text Add to dashboard Cite

show abstract

“…The theoretical reasons behind such large track errors were explored by Torn et al (2018) for the case of Debby (2012), Joaquin (2015), and Lionrock (2016). Using ensemble sensitivity analysis, the authors concluded that the foremost factor in creating large ensemble spread was a steering flow pattern with a saddle point of strong deformation (Fig.…”

Section: Dynamics Of Large Forecast Errors In Tc Tracksmentioning

confidence: 99%

Recent Progress in the Fundamental Understanding of Tropical Cyclone Motion

Ito

Chan

et al. 2020

Journal of the Meteorological Society of Japan

View full text Add to dashboard Cite

While the fundamental understanding of the movement of a tropical cyclone (TC) is fairly mature, there are still notable advancements being made. This paper summarizes new concepts and updates on existing fundamental theories on TC movement obtained from simplified barotropic models, full-physics models, and data analysis particularly since 2014. It includes the recent works on the interaction of the TC with its environment and the fundamental aspects of predictability related to TC movement. The conventional concepts of the steering flow, β-gyre, and diabatic heating remain important. Yet, a more complete understanding of mechanisms governing TC movement serves as an important basis toward the further improvement of track forecasts.

show abstract

“…TC track forecasts become more uncertain for moderate amplitudes of deep vertical wind shear when the vortex structure may be difficult to predict (Corbosiero and Molinari 2003;Zhang and Tao 2013;Finocchio et al 2016). Other studies have shown that TC motion could be significantly altered by intense convection near the vortex and the resulting asymmetry of wind and precipitation fields (Dengler and Reeder 1997;Corbosiero and Molinari 2002;Torn and Davis 2012). In addition, deep vertical wind shear is capable of tilting the TC vortex, and this tilt has small-amplitude implications for TC motion (Flatau et al 1994).…”

Section: Introductionmentioning

confidence: 99%

“…Previous studies have shown that the vertical profile of the environmental wind (e.g., helicity) is a determining factor in the TC vortex response to vertical wind shear (Onderlinde and Nolan 2016;Ryglicki et al 2018), and the resulting TC vortex structure controls the atmospheric layer responsible for steering the TC. Further, TC positions used to initialize model forecasts are imprecise, especially for weaker TCs without aircraft or land-based observations (e.g., Torn and Snyder 2012;Landsea and Franklin 2013). Uncertainty in the TC position may also translate into differences in the environment with which the vortex interacts and, therefore, may alter TC motion.…”

Section: Introductionmentioning

confidence: 99%

“…High track forecast uncertainty for Joaquin has been the subject of several recent studies (Nystrom et al 2018;Torn et al 2018;Miller and Zhang 2019;Saunders et al 2019). Using EPS forecasts from the Weather Research and Forecasting (WRF) Model, Nystrom et al (2018) found that the largest contributor to the divergence of Joaquin track forecasts was initial condition errors between 600 and 900 km from the initial TC position.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Track Uncertainty in High-Resolution HWRF Ensemble Forecasts of Hurricane Joaquin

Alaka

Zhang

Gopalakrishnan

et al. 2019

Weather and Forecasting

View full text Add to dashboard Cite

Hurricane Joaquin (2015) was characterized by high track forecast uncertainty when it approached the Bahamas from 29 September 2015 to 1 October 2015, with 5-day track predictions ranging from landfall in the United States to east of Bermuda. The source of large track spread in Joaquin forecasts is investigated using an ensemble prediction system (EPS) based on the Hurricane Weather Research and Forecasting (HWRF) Model. For the first time, a high-resolution analysis of an HWRF-based EPS is performed to isolate the factors that control tropical cyclone (TC) track uncertainty. Differences in the synoptic-scale environment, the TC vortex structure, and the TC location are evaluated to understand the source of track forecast uncertainty associated with Joaquin, especially at later lead times when U.S. landfall was possible. EPS members that correctly propagated Joaquin into the central North Atlantic are compared with members that incorrectly predicted U.S. landfall. Joaquin track forecasts were highly dependent on the evolution of the environment, including weak atmospheric steering flow near the Bahamas and three synoptic-scale systems: a trough over North America, a ridge to the northeast of Joaquin, and an upper-tropospheric trough to the east of Joaquin. Differences in the steering flow were associated with perturbations of the synoptic-scale environment at the model initialization time. Ultimately, members that produced a more progressive midlatitude synoptic-scale pattern had reduced track errors. Joaquin track forecast uncertainty was not sensitive to the TC vortex structure or the initial TC position.

show abstract

Tropical Cyclone Track Sensitivity in Deformation Steering Flow

Cited by 21 publications

References 40 publications

The Hurricane Harvey (2017) Texas Rainstorm: Synoptic Analysis and Sensitivity to Soil Moisture

The Hurricane Harvey (2017) Texas Rainstorm: Synoptic Analysis and Sensitivity to Soil Moisture

Recent Progress in the Fundamental Understanding of Tropical Cyclone Motion

Track Uncertainty in High-Resolution HWRF Ensemble Forecasts of Hurricane Joaquin

Contact Info

Product

Resources

About