Liguang Wu scite author profile

In order to understand the roles of various physical processes in baroclinic tropical cyclone (TC) motion and the vertical coupling between the upper-and lower-level circulations, a new dynamical framework is advanced. A TC is treated as a positive potential vorticity (PV) anomaly from environmental flows, and its motion is linked to the positive PV tendency. It is shown that a baroclinic TC moves to the region where the azimuthal wavenumber one component of the PV tendency reaches a maximum, but does not necessarily follow the ventilation flow (the asymmetric flow over the TC center). The contributions of individual physical processes to TC motion are equivalent to their contributions to the wavenumber one PV component of the PV tendency. A PV tendency diagnostic approach is described based on this framework. This approach is evaluated with idealized numerical experiments using a realistic hurricane model. The approach is capable of estimating TC propagation with a suitable accuracy and determining fractional contributions of individual physical processes (horizontal and vertical advection, diabatic heating, and friction) to motion. Since the impact of the ventilation flow is also included as a part of the influence of horizontal PV advection, this dynamical framework is more general and particularly useful in understanding the physical mechanisms of baroclinic and diabatic TC motion.

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Warning signs for stabilizing global CO ₂ emissions

Jackson

Quéré

Andrew

et al. 2017

Environ. Res. Lett.

186

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Carbon dioxide (CO 2 ) emissions from fossil fuels and industry comprise ∼90% of all CO 2 emissions from human activities. For the last three years, such emissions were stable, despite continuing growth in the global economy. Many positive trends contributed to this unique hiatus, including reduced coal use in China and elsewhere, continuing gains in energy efficiency, and a boom in low-carbon renewables such as wind and solar. However, the temporary hiatus appears to have ended in 2017. For 2017, we project emissions growth of 2.0% (range: 0.8%−3.0%) from 2016 levels (leap-year adjusted), reaching a record 36.8 ± 2 Gt CO 2 . Economic projections suggest further emissions growth in 2018 is likely. Time is running out on our ability to keep global average temperature increases below 2 • C and, even more immediately, anything close to 1.5 • C. R M Andrew https://orcid.org/0000-0001-8590-6431 G P Peters https://orcid.org/0000-0001-7889-8568

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A Numerical Study of Hurricane Erin (2001). Part II: Shear and the Organization of Eyewall Vertical Motion

Braun

2007

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A high-resolution numerical simulation of Hurricane Erin (2001) is used to examine the organization of vertical motion in the eyewall and how that organization responds to a large and rapid increase in the environmental vertical wind shear and subsequent decrease in shear. During the early intensification period, prior to the onset of significant shear, the upward motion in the eyewall was concentrated in small-scale convective updrafts that formed in association with regions of concentrated vorticity (herein termed mesovortices) with no preferred formation region around the eyewall. Asymmetric flow within the eye was weak. As the shear increased, an azimuthal wavenumber-1 asymmetry in storm structure developed with updrafts tending to occur on the downshear to downshear-left side of the eyewall. Continued intensification of the shear led to increasing wavenumber-1 asymmetry, large vortex tilt, and a change in eyewall structure and vertical motion organization. During this time, the eyewall structure was dominated by a vortex couplet with a cyclonic (anticyclonic) vortex on the downtilt-left (downtilt-right) side of the eyewall and strong asymmetric flow across the eye that led to strong mixing of eyewall vorticity into the eye. Upward motion was concentrated over an azimuthally broader region on the downtilt side of the eyewall, upstream of the cyclonic vortex, where low-level environmental inflow converged with the asymmetric outflow from the eye. As the shear diminished, the vortex tilt and wavenumber-1 asymmetry decreased, while the organization of updrafts trended back toward that seen during the weak shear period. Based upon the results for the Erin case, as well as that for a similar simulation of Hurricane Bonnie (1998), a conceptual model is developed for the organization of vertical motion in the eyewall as a function of the strength of the vertical wind shear. In weak to moderate shear, higher wavenumber asymmetries associated with eyewall mesovortices dominate the wavenumber-1 asymmetry associated with the shear so that convective-scale updrafts form when the mesovortices move into the downtilt side of the eyewall and dissipate on the uptilt side. Under strong shear conditions, the wavenumber-1 asymmetry, characterized by a prominent vortex couplet in the eyewall, dominates the vertical motion organization so that mesoscale ascent (with embedded convection) occurs over an azimuthally broader region on the downtilt side of the eyewall. Further research is needed to determine if these results apply more generally.

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Effects of Convective Heating on Movement and Vertical Coupling of Tropical Cyclones: A Numerical Study*

Wu¹,

Wang²

2001

J. Atmos. Sci.

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The influence of convective heating on movement and vertical coupling of tropical cyclones (TCs) is investigated using a hurricane model with different environmental flows. The authors identify two processes by which convective heating may affect TC motion. One is the advection of symmetric potential vorticity (PV) by heatinginduced asymmetric flow. The other is the direct generation of a positive PV tendency by asymmetric heating, which acts to shift a TC to the region of maximum downward gradient of asymmetric heating. A steering level exists that is located at the level where the direct influence of asymmetric heating vanishes, normally in the lower troposphere. At that level, a TC moves with the asymmetric flow averaged within a radius of 200 km, because the influence of asymmetric flows on TC motion is weighted by the horizontal PV gradient that is primarily confined within the TC core. Although the vertical shear in the asymmetric flow (including environmental and heating-induced flows) could tilt the vortex, the influence of asymmetric heating tends to offset the vertical tilt caused by the vertical shear through a fast adjustment between the asymmetric wind and diabatic heating. Therefore, diabatic heating enhances the vertical coupling.

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What Caused the Unprecedented Absence of Western North Pacific Tropical Cyclones in July 2020?

Wang

et al. 2021

Geophysical Research Letters

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The WNP tropical cyclone (TC) activity peaks in July-August-September, accounting for about 60% of the annual TC count (Chan, 2005;Lander, 1994). TCs in this study are defined as those in the data sets with maximum wind speed exceeding the tropical storm intensity (17.2 m s −1 or 34 knots). Climatologically, about four TCs form in July and it usually takes a northward-recurved track and exerts great impacts on subtropical East Asia. However, no TC formation in July 2020 over the WNP was recorded in July 2020 (Figure 1a), which is the first time in the available historical records since 1945. The unprecedented absence of TC formation suggests its possible unique driving factors.It is well known that El Niño-Southern Oscillation (ENSO) is an important factor modulating TC activity over the WNP (Chan, 1985;Lander, 1994;Wang & Chan, 2002). During the El Niño decaying summer, an anomalous anticyclonic circulation is a recurrent pattern in the WNP, which acts to suppress TC genesis over the WNP (

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Liguang Wu

A Potential Vorticity Tendency Diagnostic Approach for Tropical Cyclone Motion*

Warning signs for stabilizing global CO ₂ emissions

A Numerical Study of Hurricane Erin (2001). Part II: Shear and the Organization of Eyewall Vertical Motion

Effects of Convective Heating on Movement and Vertical Coupling of Tropical Cyclones: A Numerical Study*

What Caused the Unprecedented Absence of Western North Pacific Tropical Cyclones in July 2020?

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Liguang Wu

A Potential Vorticity Tendency Diagnostic Approach for Tropical Cyclone Motion*

Warning signs for stabilizing global CO 2 emissions

A Numerical Study of Hurricane Erin (2001). Part II: Shear and the Organization of Eyewall Vertical Motion

Effects of Convective Heating on Movement and Vertical Coupling of Tropical Cyclones: A Numerical Study*

What Caused the Unprecedented Absence of Western North Pacific Tropical Cyclones in July 2020?

Contact Info

Product

Resources

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Warning signs for stabilizing global CO ₂ emissions