A laboratory study of global-scale wave interactions in baroclinic flow with topography II: vacillations and low-frequency variability

Risch, S. H.; Read, P. L.

doi:10.1080/03091929.2015.1055477

Cited by 5 publications

(5 citation statements)

References 65 publications

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“…Taylor number, this component was never found to dominate the flow structure, and thus, in contrast to earlier work (e.g. Read and Risch 2011;Risch and Read 2015;Marshall and Read 2015), no clear evidence of topographic resonance was discovered.…”

Section: Analysis Of Partial Barrier Experimental Resultscontrasting

confidence: 94%

“…Instead the flow always exhibits a drifting wave structure, transitioning from a dominant wavenumber-2 to wavenumber-3, and with occasional transitions to wavenumber-4, as the rotation rate increases. Compared to experiments with pure wavenumber-3 bottom topography, such as investigated by Read and Risch (2011), Marshall and Read (2015) and Risch and Read (2015), amplitude and/or structural vacillations were encountered in similar areas of parameter space, but some points, denoted in Figure 3 as the dashed (green online) Transition region, exhibit a greatly increased number of apparent transitions between wavenumbers over time. In these flows, which lie near the 'irregular' region, a given dominant wavenumber is only foremost for part of the time, with other wavenumbers irregularly dominating the structure.…”

Section: Results and Analysismentioning

confidence: 86%

“…In this way, the sensitivity of the problem under investigation to truncation effects can be studied, complementing the results from finite resolution numerical models, regardless of complexity. As such, it appears that a suitable approach would be both to employ a baroclinic annulus flow, thus testing the sensitivity of Tian et al's (2001) barotropic results to the presence of additional vertical degrees of freedom, and to use quantitative analyses, systematically exploring parameter space and thus verifying and extending the qualitative findings of Risch (1999), Read and Risch (2011) and Risch and Read (2015). Combining this with the fully nonlinear interactions of a physical annulus, an investigation into the existence of multiple equilibria could be launched, stringently putting to the test the assertions of Tung and Rosenthal (1985) and Cehelsky and Tung (1987).…”

Section: Blocking In Geophysical Flowsmentioning

confidence: 99%

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An experimental investigation of blocking by partial barriers in a rotating baroclinic annulus

Marshall

Read

2017

Geophysical & Astrophysical Fluid Dynamics

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We present a series of experimental investigations in which a differentially-heated annulus was used to investigate the effects of topography on rotating, stratified flows with similarities to the Earth's atmospheric or oceanic circulation. In particular, we compare and investigate blocking effects via partial mechanical barriers to previous experiments by the authors utilising azimuthally-periodic topography.The mechanical obstacle used was an isolated ridge, forming a partial barrier, employed to study the difference between partially blocked and fully unblocked flow. The topography was found to lead to the formation of bottom-trapped waves, as well as impacting the circulation at a level much higher than the top of the ridge. This produced a unique flow structure when the drifting flow and the topography interacted in the form of an 'interference' regime at low Taylor number, but forming an erratic 'irregular' regime at higher Taylor number. The results also showed evidence of resonant wavetriads, similar to those noted with periodic wavenumber-3 topography by Marshall and Read (2015), though the component wavenumbers of the wave-triads and their impact on the flow were found to depend on the topography in question. With periodic topography, wave-triads were found to occur between both the baroclinic and barotropic components of the zonal wavenumber-3 mode and the wavenumber-6 baroclinic component, whereas with the partial barrier two nonlinear resonant wavetriads were noted, each sharing a common wavenumber-1 mode.

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Section: Analysis Of Partial Barrier Experimental Resultscontrasting

confidence: 94%

Section: Results and Analysismentioning

confidence: 86%

Section: Blocking In Geophysical Flowsmentioning

confidence: 99%

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An experimental investigation of blocking by partial barriers in a rotating baroclinic annulus

Marshall

Read

2017

Geophysical & Astrophysical Fluid Dynamics

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“…For example, the reader is referred to the works by the groups at Florida State University (Pfeffer et al 1980;Buzyna et al 1984), at Japanese universities (Ukaji and Tamaki 1989;Tajima and Kawahira 1993;Sugata and Yoden 1994;Tajima and Nakamura 2000;Tamaki and Ukaji 2003), at Oxford (Read et al 1992;Read 1997, 1998;Wordsworth et al 2008), in Bremen/Cottbus (von Larcher and Egbers 2005;Harlander et al 2011) and in Budapest (Jánosi et al 2010). Furthermore, researchers have introduced the β-effect in rotating tank experiments through modifying the configuration to mimic the planetary curvature (Mason 1975;Bastin and Read 1997;von Larcher et al 2013;Read et al 2015a;Yadav et al 2016) and zonally asymmetric topography (Leach 1981;Li et al 1986;Bernardet et al 1990;Risch and Read 2015). Very recently, Scolan and Read (2017) proposed a new experimental configuration to add the forcing thermal convection in the cylindrical rotating annulus through heating the bottom near the external wall and cooling the circular disk near the axis at the top surface of the annulus.…”

Section: Experiments: Historymentioning

confidence: 99%

Rossby Waves in Astrophysics

et al. 2021

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Rossby waves are a pervasive feature of the large-scale motions of the Earth’s atmosphere and oceans. These waves (also known as planetary waves and r-modes) also play an important role in the large-scale dynamics of different astrophysical objects such as the solar atmosphere and interior, astrophysical discs, rapidly rotating stars, planetary and exoplanetary atmospheres. This paper provides a review of theoretical and observational aspects of Rossby waves on different spatial and temporal scales in various astrophysical settings. The physical role played by Rossby-type waves and associated instabilities is discussed in the context of solar and stellar magnetic activity, angular momentum transport in astrophysical discs, planet formation, and other astrophysical processes. Possible directions of future research in theoretical and observational aspects of astrophysical Rossby waves are outlined.

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“…Most notably, both experiments evidently exhibit a lack of dominant stationary wave activity, both show evidence of topographic interactions and jet-shifting effects as the wave structures drift over the topographic peak or patch of heating elements, creating flows similar to the blocked and zonal states found with periodic bottom topography (such as found by Read and Risch 2011, Risch and Read 2015and Marshall and Read 2015. Both systems were shown to have the same general shape of regime diagram, separated into two separate and distinct regions.…”

Section: Discussionmentioning

confidence: 75%

Thermal versus mechanical topography: an experimental investigation in a rotating baroclinic annulus

Marshall

Read

2020

Geophysical & Astrophysical Fluid Dynamics

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We present a series of experimental investigations in which a differentially-heated annulus was used to investigate the effects of topography on rotating, stratified flows. In particular, we investigate blocking effects via azimuthally varying differential-heating and compare them to previous experiments utilising partial mechanical barriers (Marshall and Read, Geophys. Astrophys. Fluid Dyn. 2018, 112).The thermal topography used consisted of a flat patch of heating elements covering a small azimuthal extent of the base, forming an equivalent of a partial barrier, to study the difference between blocked and unblocked flow. These azimuthally-varying heating experiments produced results with many similarities to our previous experiments with a mechanical barrier, despite the lack of a physical obstacle or formation of bottom-trapped waves. In particular, a unique flow structure was found when the drifting flow and the topography interacted in the form of an 'interference' regime at low Taylor number, but forming an erratic 'irregular' regime at higher Taylor number. This suggests that blocking may be induced by either or both of a thermal or mechanical inhomogeneity. Evidence of coherent/persistent resonant wave triads was noted in both kinds of experiment, though the component wavenumbers of the wave-triads and their impact on the flow was found to depend on the topography in question.

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A laboratory study of global-scale wave interactions in baroclinic flow with topography II: vacillations and low-frequency variability

Cited by 5 publications

References 65 publications

An experimental investigation of blocking by partial barriers in a rotating baroclinic annulus

An experimental investigation of blocking by partial barriers in a rotating baroclinic annulus

Rossby Waves in Astrophysics

Thermal versus mechanical topography: an experimental investigation in a rotating baroclinic annulus

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