2014
DOI: 10.1017/jfm.2014.389
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Entrainment in two coalescing axisymmetric turbulent plumes

Abstract: A model of the total volume flux and entrainment occurring in two coalescing axisymmetric turbulent plumes is developed and compared with laboratory experiments. The dynamical evolution of the two plumes is divided into three regions. In region 1, where the plumes are separate, the entrainment in each plume is unaffected by the other plume, although the two plumes are drawn together due to the entrainment of ambient fluid between them. In region 2 the two plumes touch each other but are not yet merged. In this… Show more

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Cited by 33 publications
(58 citation statements)
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“…The predicted merging height was somewhat greater than that observed in accompanying experiments, a result attributed in part to sensitivity of the model to the plume entrainment constant. Cenedese & Linden (2014) extended this model with the introduction of an intermediate region where the plumes overlap but are not yet fully merged. The model predictions compared favourably with measurements of the volume flux (inferred from interface movement) in two merging plumes obtained from 'filling-box' experiments, although these results are also sensitive to the entrainment constant, as will be discussed later.…”
Section: Introductionmentioning
confidence: 99%
“…The predicted merging height was somewhat greater than that observed in accompanying experiments, a result attributed in part to sensitivity of the model to the plume entrainment constant. Cenedese & Linden (2014) extended this model with the introduction of an intermediate region where the plumes overlap but are not yet fully merged. The model predictions compared favourably with measurements of the volume flux (inferred from interface movement) in two merging plumes obtained from 'filling-box' experiments, although these results are also sensitive to the entrainment constant, as will be discussed later.…”
Section: Introductionmentioning
confidence: 99%
“…Hence, the virtual origin correction is the distance from the physical source that an imaginary pure plume, with zero momentum and volume fluxes but with the same buoyancy flux issuing from the virtual origin, has in order for the actual buoyancy, momentum, and volume fluxes of the plume to be the same at the physical source. The entrainment of warm bottom layer waters in the two merging plumes is reduced compared to that with two independent plumes (Cenedese and Linden 2014), and as a consequence the plume waters are colder and melting is reduced. As the two sources are located closer together, the two plumes interact for a larger portion of their vertical rise and consequently the melting is reduced for decreasing values of x 0 , as shown in Fig.…”
Section: Discussionmentioning
confidence: 96%
“…2). When the two sources of subglacial discharge are located closer together the two plumes will touch and merge at a distance from the ''virtual origin'' given by z T 5 0.35x 0 /a and z M 5 0.44x 0 /a, respectively (Cenedese and Linden 2014;Kaye and Linden 2004), where the distance from the virtual origin is z 5 (z 0 1 z V ), z 0 is the vertical distance from the source, and z V is the location of the virtual origin below the source (Hunt and Kaye 2001). The virtual origin correction is necessary because the plume's self-similar solutions of Morton et al (1956) are strictly valid only for a ''pure'' plume with zero momentum and volume fluxes.…”
Section: Discussionmentioning
confidence: 99%
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