An Investigation of Spiral Gravity Waves Radiating from Tropical Cyclones Using a Linear, Nonhydrostatic Model

Nolan, David S.

doi:10.1175/jas-d-19-0259.1

Cited by 5 publications

(4 citation statements)

References 68 publications

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“…4a indicates the lack of consistency between the observational TCR radial propagation velocities and theoretical GW phase velocities. Most of the GW phase velocities are confined to a narrower range at approximately ±20 m s −1 , which is the same order of magnitude as the typical radial propagation speeds of several meters per second for GWs excited within TCs 42 , 44 – 47 . These theoretical propagation estimates are distinctly separated from the primary velocity distributions of the observed radial propagation, which are within the range of ±10 m s −1 (Figs.…”

Section: Resultsmentioning

confidence: 73%

“…In this view, the moist convection occurring in outer TCRs may be triggered by gravity-wave-induced upward motions 42 , 43 . Despite the potential discrepancy in the propagation speed between theoretical GWs and observed outer TCRs 3 , 30 , 42 – 47 , what we learned from these previous works is still unable to adequately address whether outer TCRs would be initially triggered by the GWs within the inner-core region and then propagate outward to the outer region of TCs.…”

Section: Introductionmentioning

confidence: 76%

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Origin of outer tropical cyclone rainbands

Yu,

Lin,

Pun

2023

Nat Commun

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Outer tropical cyclone rainbands (TCRs) are a concentrated region of heavy precipitation and hazardous weather within tropical cyclones (TCs). Outer TCRs pose considerable risk to human societies, but their origin remains unresolved. Here, we identify a total of 1029 outer TCRs at their formative stage from 95 TCs and present a large collection of radar observations in order to establish a robust foundation of the natural diversity of rainband origin. The results show the dominance of outer origin for the observed outer TCRs, in distinct contrast to theoretical modeling works of outer TCRs, which propose inner-origin scenarios. Our analysis also suggests that squall-line dynamics are a common, but not the sole, mechanism responsible for outer TCR formation. The nature of preexisting outer precipitation is found to be an important factor to influence the squall-line and non-squall-line outer TCR initiation.

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Section: Resultsmentioning

confidence: 73%

Section: Introductionmentioning

confidence: 76%

Origin of outer tropical cyclone rainbands

Yu,

Lin,

Pun

2023

Nat Commun

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“…Nolan (2020; hereafter N20) proposed that the primary source of SGWs is the pulsation of convective maxima in the TC eyewall as they are advected through the convectively enhanced, downshear‐left quadrant of a TC. N20 tested this hypothesis by forcing a linear dynamical model of perturbations to a TC‐like vortex with idealized heat sources that were rotating and pulsing.…”

Section: Introductionmentioning

confidence: 99%

“…The most prominent p oscillations had periods of 2,000-3,000 s, consistent with the simulated p waves, but their radial scales or speeds could not be independently deduced from solitary observations at fixed points. Nolan (2020;hereafter N20) proposed that the primary source of SGWs is the pulsation of convective maxima in the TC eyewall as they are advected through the convectively enhanced, downshear-left quadrant of a TC. N20 tested this hypothesis by forcing a linear dynamical model of perturbations to a TC-like vortex with idealized heat sources that were rotating and pulsing.…”

mentioning

confidence: 99%

The Representation of Spiral Gravity Waves in a Mesoscale Model With Increasing Horizontal and Vertical Resolution

Nolan

Onderlinde²

2022

J Adv Model Earth Syst

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Anthes et al. (1971) and Anthes (1972) presented some of the earliest attempts at three-dimensional numerical modeling of a tropical cyclone (TC). Despite using horizontal grid spacings of 30 km and only three model levels, the simulations did produce some of the desired features, such as low-level flow spiraling toward the center that abruptly rose to the tropopause, and then diverged outward into asymmetric patterns. Long spiral bands of enhanced precipitation were also evident, about 90 km wide, and propagating outward at 24 knots (12 m s −1 ). Anthes (1972) explained that these were probably inertia-gravity waves and perhaps not correct representations of spiral rainbands in real TCs. Kurihara and Tuleya (1974) presented a three-dimensional simulation with 20 km grid spacing and 11 vertical levels. They also noted robust spiral bands of vertical motion, in their case propagating outward at 27 m s −1 , with temperature and vertical motion out of phase, thus consistent with gravity waves.After those early attempts, the vertical and horizontal grid spacings of TC models steadily decreased while the realisms of their simulated TCs steadily increased (Braun et al., 2006;Liu et al., 1997;Rogers et al., 2003). The TC eye and eyewall became well-resolved while the spiral bands of precipitation became narrower and moved more slowly to the point where it can be difficult to differentiate their motion with that of the tangential circulation (Moon & Nolan, 2015a, 2015b. At the same time, vertical motions associated with gravity waves have become steadily less prominent in numerical simulations and have received accordingly less interest. An exception is the study by Chow et al. (2002), who analyzed outward propagating spirals in a Mesoscale Model 5 (MM5)

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