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Review

Review on the Hydro- and Thermo-Dynamic Wakes of Underwater Vehicles in Linearly Stratified Fluid

by
Liushuai Cao
1,
Yanyan Pan
2,
Gang Gao
1,
Linjie Li
1 and
Decheng Wan
1,*
1
Computational Marine Hydrodynamics Lab (CMHL), School of Ocean and Civil Engineering, Shanghai Jiao Tong University, Shanghai 200240, China
2
Shanghai Radio Equipment Research Institute, Shanghai 201109, China
*
Author to whom correspondence should be addressed.
J. Mar. Sci. Eng. 2024, 12(3), 490; https://doi.org/10.3390/jmse12030490
Submission received: 10 January 2024 / Revised: 9 March 2024 / Accepted: 13 March 2024 / Published: 15 March 2024
(This article belongs to the Special Issue Computational Marine Hydrodynamics (CMH))
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Abstract

:
Wakes produced by underwater vehicles, particularly submarines, in density-stratified fluids play a pivotal role across military, academic, and engineering domains. In comparison to homogeneous fluid environments, wakes in stratified flows exhibit distinctive phenomena, including upstream blocking, pancake eddies, internal waves, and variations in hydrodynamic performance. These phenomena are crucial for optimizing the operation of underwater vehicles. This review critically assesses the hydrodynamic and thermodynamic aspects of these wakes through an integration of theoretical, experimental, and numerical approaches. The hydrodynamic wake evolution, comprising near-wake, non-equilibrium, and quasi-two-dimensional regimes, is scrutinized. The underlying physics, encompassing energy transformation, vertical motion suppression, and momentum dissipation, are analyzed in detail. Special emphasis is placed on numerical methods, encompassing diverse approaches and turbulence models and highlighting their differences in fidelity and computational cost. Numerical simulations not only provide insights into the intricate interplay among various factors but also emerge as a crucial focal point for future research directions. In the realm of thermodynamic wakes, we delve into the thermal wake induced by the discharge of high-temperature cooling water and the cold wake resulting from the stirring of seawater. The generation, evolution, and ascent to the free surface of these wakes are explored. Additionally, this review identifies and analyzes current research shortcomings in each aspect. By systematically addressing existing knowledge gaps, our study contributes novel insights that propel academic progress and bear significant implications for submarine engineering. This work not only enhances our understanding of the intricate dynamics involved but also provides a foundation for future research endeavors in this critical field.

1. Introduction

Underwater vehicles, particularly submarines, play a vital role in modern naval fleets due to their unique combination of stealth, agility, endurance, and minimal logistical needs. As the propagation distance of sound waves far surpasses that of visible light, radar, infrared, and other electromagnetic waves, sonar detection remains the most effective method for tracking underwater vessels. However, the relentless pursuit of quieter submarines necessitates the continuous evolution of detection systems aligned with the strategic objectives of wide-area surveillance (WAS), demanding long-range detection capabilities and comprehensive monitoring. This calls for a paradigm shift in submarine detection technology, including the exploration of non-acoustic detection methods [1].
The movement of underwater vehicles disrupts the sea surface flow field, causing wrinkles and ripples of varying roughness to appear. By capturing these changes in sea surface roughness signals, synthetic aperture radar (SAR) enables the detection and estimation of underwater objects [2,3]. Additionally, thermal signals play a crucial role. Surveillance satellites equipped with highly sensitive infrared CCD cameras can capture thermal images of underwater vehicles, permitting precise determination of their position, direction, and speed [4,5].
When traversing the open ocean, the generation and evolution of an underwater vehicle’s wake are inextricably linked to the specific characteristics of the environment. A key feature of the marine environment is stratification, where seawater properties like temperature, salinity, and density vary with depth. Compared to uniform flow, an underwater vehicle navigating within a density-stratified flow experiences a more complex wake due to the influence of density gradients. This complexity can lead to unique phenomena such as upstream blocking [6], the generation of internal waves [7], and the formation of pancake eddies in the far-field late wake [8].
Therefore, the impact of stratification on underwater vehicle wake characteristics is highly significant and cannot be ignored. Numerous studies have been conducted to enhance an understanding of flow and wake characteristics, employing theoretical analyses [9], model experiments [10,11], and numerical simulations [12,13,14]. However, a significant portion of these studies neglect the influence of stratification. Research on the generation, evolution, and propagation characteristics of wakes from underwater vehicles in density-stratified flow is not only a pressing need in engineering practice, but also a key issue in current international hydrodynamics research.

2. Definition and Classification

The wake of an underwater vehicle is the complex, turbulent flow field generated around the moving vessel. This dynamic signature continuously evolves and propagates to distant regions, leaving a signature like the proverbial “trace” of a wild goose. Submarines and other submersibles inevitably disturb the surrounding water during their navigation, causing some fluid to adhere due to viscosity and the remainder to propagate outward as waves. This review focuses on the study of hydrodynamic and thermodynamic wakes produced by underwater vehicles, outlining their definitions and classifications.

2.1. Hydrodynamic Wakes of Underwater Vehicles

A submarine’s hydrodynamic wake refers to the perturbation in the fluid flow pattern created by its movement. This manifests as alterations in velocity and pressure fields within the wake region, leading to the generation of vorticity and turbulence [15,16,17,18]. Understanding these wakes is crucial for assessing a submarine’s stealth, maneuverability, and overall hydrodynamic performance. The formation process is intricate and involves various contributing factors, which are broadly categorized into three types: the Bernoulli hump, Kelvin wake, and internal wave.

2.1.1. Bernoulli Hump

The Bernoulli hump is a rise and fall in sea surface height above the submarine, most prominent when operating close to the surface [19]. This phenomenon plays a significant role in submarine-detection programs for world navies, as changes in the free surface caused by the hump can be tracked by various methods. The hump’s height varies from tens of centimeters near the surface to a few millimeters at a depth of about 50 m, primarily influenced by the vessel’s velocity, depth, and dimensions.

2.1.2. Kelvin Wake

One of the most studied surface waves, the Kelvin wake forms the distinct V-shaped pattern trailing behind a moving object [20]. While all objects moving on the free surface in deep water generate such a wave pattern, ship-generated Kelvin wakes have received extensive attention due to their contribution to resistance forces. In contrast, thorough research on submarine-generated Kelvin wakes, including the behavior of wave height and wake angle with respect to Froude number and submergence depth, is lacking [21].

2.1.3. Internal Wave

Unlike surface waves, internal waves propagate within a stratified fluid medium, typically beneath the surface, driven by oscillations and movement along density interfaces [22]. These waves can travel horizontally along these interfaces, their behavior influenced by the fluid’s stratification. The ocean’s pycnocline, a sharp density gradient between layers, plays a crucial role in their generation and propagation. Internal waves represent the dynamic interplay between gravity and buoyancy forces in a stratified environment, significantly impacting vertical mixing of properties within the fluid.

2.1.4. Wake Behavior in Stratified Fluids

In a uniform fluid, inertial and viscous forces primarily influence the wake and near-field fluid structure of underwater vehicles. These momentum wakes dissipate rapidly due to viscous effects. However, in stratified fluids, buoyancy becomes a crucial factor in determining the momentum wake and flow structure, alongside inertial and viscous forces. Due to the vertical density gradient, turbulent fluctuations in the wake are restricted in their vertical motion, forming large-scale coherent structures [23].

2.2. Thermodynamic Wakes of Underwater Vehicles

The thermodynamic wakes associated with submarines encompass alterations in temperature and energy distribution surrounding the submerged vessel. This transformation results from the exchange of heat between the submarine and its environment, giving rise to temperature gradients and energy dissipation. The investigation of these wakes yields valuable insights into the thermal signature and environmental impact of submarines, which is particularly pertinent for naval operations and environmental monitoring.

2.2.1. Thermal Wake Due to Cooling Water Discharge

Submerged vehicles, especially those utilizing nuclear propulsion, release heated cooling water that rapidly elevates the surrounding seawater temperature. The reduced density of the heated water causes it to ascend to the sea surface, forming a distinct “thermal signal” [24].

2.2.2. Cold Wake Due to Stirring of Stratified Water

As an underwater vehicle navigates through stratified seawater with varying temperature and density, its hull and propellers disrupt the stable structure. This disturbance brings colder seawater to the free surface, creating a discernible “cold signal” on the sea surface [25].
These thermal and cold signals, manifested on the sea surface through the movement of underwater vehicles, play a crucial role in comprehending their overall environmental impact and susceptibility to detection.
Underwater vehicle wakes in stratified flows involve complex hydrodynamic and thermodynamic processes, presenting a challenging multi-field coupling problem with interdisciplinary intersections and multifactor interferences. As depicted in Figure 1, the sketch vividly captures the key flow features and wake categories discussed earlier. The illustration portrays submarine wakes traversing through stratified fluids, giving rise to a diverse array of vortices and wakes that propagate downstream. Phenomena distinctive to stratified fluids are accentuated with yellow lettering, underscoring their appearance and significance within the depicted context. By examining the research methods, current status, and outcomes from various perspectives, this review aims to provide a comprehensive overview of underwater vehicle wakes and pave the way for future research directions.

3. Hydrodynamic Wakes in the Stratified Fluid

The formation of wakes has always been a matter of great concern for scholars and engineers engaged in fluid dynamics, as it is a fundamental flow phenomenon generated when fluid flows past obstacles. The formation of wakes is closely related to the Reynolds number, as shown in Equation (1) [26].
R e = U L ν
where U represents the flow velocity, L is the characteristic length, and v is the kinematic viscosity of the fluid.
When the Reynolds number gradually exceeds a critical value, the wake begins to become unstable and exhibits a regular flow pattern, such as the Karman vortex street behind a cylinder. As the Reynolds number continues to increase, the regular flow pattern is disrupted, leading to the formation of turbulence [27].
In comparison to uniform fluids, in stratified fluids with density and temperature, the wake is not only related to the Reynolds number but also closely associated with the internal Froude number Fr, as shown in Equation (2) [28].
F r = U N L
where N is the Brunt-Väisälä frequency, defined as [29]
N = g ρ 0 ρ z
where ρ0 is the undisturbed original density, z is the vertical coordinate, and g is the gravitational acceleration. The Brunt–Väisälä frequency is commonly used to indicate the oscillation frequency of fluid particles under infinitesimal disturbances, serving as a fundamental characteristic of stratified fluids. In recent years, researchers from various fields have studied the hydrodynamic wakes of objects in linearly stratified fluids from three perspectives: theoretical, experimental, and computational fluid dynamics (CFD).

3.1. Theoretical Methods

Theoretical investigations of hydrodynamic wakes in linearly stratified fluids with density and temperature gradients have initially focused on simplified models like point sources. Hudimac [30] modeled a perturbation source in stratified flow as a stationary moving point, applying Fourier transforms to derive theoretical models for surface and interfacial waves after perturbation. This enabled qualitative analysis of the relationship between transverse and dispersive wave systems and the point source velocity. Further contributions to this field were made by Keller and Munk [31], who derived wake equations for wave sources moving in anisotropic media, extensively studying near- and far-field wake behavior. Their work, primarily aimed at internal wave analysis, demonstrated that steady-state linear internal waves generated by submarines exhibit vertical propagation, intensifying their convergence and divergence on the free surface. A consolidation of previous research on Green’s function in stratified fluids was provided by Voisin [32,33], who offered analytical expressions for pulsating point sources in unbounded stratified fluids with and without the Boussinesq assumption.
However, these early studies have dealt with infinite flow fields, neglecting the free surface’s influence. Recognizing this limitation, Zhu et al. [34] incorporated the impact of the free surface into their model. They established a mathematical model for pulsating point source internal waves in continuously stratified fluids and used Fourier transforms and contour integration to derive analytical expressions for the Green’s function under specific frequency conditions. This allowed them to explore the generation mechanism, propagation characteristics, free surface wave characteristics, and influencing factors of such waves in these fluids.
Focusing on simpler geometries, Miles [35], Miles and Huppert [36,37], Huppert and Miles [38], and Long [39,40,41] have used asymptotic analysis to study the formation of lee waves around cylinders under different internal Froude numbers, building upon existing dispersive wave models. Moving closer to realistic scenarios, Tuck [42] employed integration to calculate the velocity field and far-field waveform of the internal wave wake generated by a moving submarine. Similarly, Motygin and Kuznetsov [43] applied the potential flow method to quantify the increased resistance effect of a moving body in stratified fluid. Radko [44] has further utilized perturbation theory to derive the far-field waveform generated by an object moving in a multilayer fluid system. Their findings suggest that the number of layers has a minimal impact on the wake waveform, while the waveform near the free surface and internal interfaces resembles classical Kelvin waves.
Stefanick [45] pioneered the use of near-field theory to estimate the height of the Bernoulli hump produced by an Ohio-class submarine under varying submersion depths and speeds. His calculations revealed that the Bernoulli hump’s shape is largely independent of submersion depth but decreases rapidly with distance from the submarine and quadratically with increasing speed. It also decreases quadratically with increasing submersion depth but typically remains below one submarine length in height.

3.2. Experimental Methods

While theoretical studies provide valuable insights into wake behavior, experiments play a crucial role in validating and enriching our understanding. Initially, researchers have focused on simple geometries like spheres, employing flow visualization techniques, hot-wire anemometry, shadowgraphy, and particle image velocimetry (PIV) to unravel the complexities of wake evolution in stratified fluids. These studies, spanning a wide range of Reynolds (Re) and internal Froude (Fr) numbers, have revealed a fascinating story of wake development under the influence of stratification. Afanasyev [46], Chomaz et al. [47], and Lin et al. [48] have investigated wakes generated by spheres of different diameters dragged at varying speeds under diverse stratification intensities. These experiments, covering Reynolds numbers (Re) in the range of [100, 104] and internal Froude numbers (Fr) between [0.1 and 100], have revealed crucial insights into the behavior of stratified wakes.
As Figure 2 demonstrates, high Fr wakes exhibit three distinct regimes: near-wake (NW), non-equilibrium (NEQ), and quasi-two-dimensional (Q2D). Within the NW regime, the wake spreads uniformly and turbulence resembles that in a homogeneous fluid. Meunier and Spedding [49], Spedding et al. [50,51], and Spedding [52] have identified the NEQ regime as the onset of stratification effects, marked by the conversion of potential energy to kinetic energy and anisotropic horizontal and vertical motions. Finally, the Q2D regime is characterized by vertically suppressed two-dimensional eddies known as “pancake vortices”.
According to the different Re, in the near wake, the flow structure includes stable two-dimensional attached vortices, unstable attached vortices, two-dimensional shedding vortices, unstable symmetrical lee waves, non-axisymmetric attached vortices, symmetrical shedding vortices, asymmetrical shedding vortices, and turbulent wakes. Additionally, Kelvin–Helmholtz (K-H) and spiral instability structures may also appear. Measurements of the frequency characteristics of the near-wake flow field have found two frequency modes in the near-field wake: a low-frequency mode with a corresponding Strouhal number (St) of approximately 0.18, and a high-frequency mode with St increasing with Re. For a more in-depth exploration of wake evolution dependent on Re, additional insights can be gleaned from the works of Derakhshandeh and Alam [53] and Thompson et al. [54]. These comprehensive reviews delve into the dynamics of wakes past bluff bodies in homogeneous flow, providing valuable perspectives on the influence of Re on the evolving wake structures.
After the near wake undergoes evolution over a buoyancy period T = 2π/N, the vertical spreading will reach its maximum. The buoyancy effect in stratified fluids inhibits the vertical movement, leading to the collapse of the wake. During this phase, the vertical velocity and thickness of the wake gradually decrease, while the horizontal velocity and width increase. According to results from PIV experiments, the flow energy within the momentum wake dissipates rapidly [55,56,57]. The horizontal average velocity  v i  of fluid particles within the momentum wake is proportional to  x 1 , where x is the horizontal distance between the velocity measurement point and the trailing sphere. This behavior is consistent with the situation of dragging a sphere in a uniformly dense fluid. However, in the collapse stage, it is observed that the average velocity of the momentum wake in fluids exhibiting linearly stratified density and temperature does not diminish with increasing x distance. This suggests that in this stage, in addition to energy dissipation, there is also energy conversion [58].
After the vertical velocity of the wake decreases to near zero, the late wake begins. In this stage, the average velocity of fluid within the momentum wake begins to decrease again with the increase in x, and it is proportional to  x 0.38 . Obviously, the rate of energy decay of the momentum wake at this stage is much slower than in a uniform fluid or in the near wake. In the late wake, vertical motion almost completely disappears, and the wake evolves only in the horizontal plane. Pancake vortices gradually appear at the edges of the wake on both sides and expand gradually. After a certain moment, these pancake vortices evolve into a set of vortex pairs with opposite rotation directions. Ultimately, in the entire late wake region, a Q2D large-scale vortex street structure is formed, and the rotation direction of the vortices is consistent with the Karman vortex street, also known as the positive Karman-type dipole vortex street [47,59,60,61].
Regarding the formation mechanism of this Q2D vortex structure, there are currently two viewpoints. One viewpoint suggests that this large-scale coherent vortex street is actually the product of the amplification of near-field shedding vortices of the dragging sphere under the influence of the buoyancy effect of stratified fluids, causing them to be “flattened” [62]. The other viewpoint suggests that the formation of the Q2D vortex street structure is unrelated to the near-field characteristics of the dragging sphere but is caused by the shear instability of the momentum wake edge interacting with the background fluid [55,63].
After decades of research, there is now a relatively comprehensive understanding of the evolution of large-scale vortex structures related to the momentum wake of a spherical body in stratified fluids. Various aspects, such as the characteristics of the momentum wake in the near-field, collapse, and far-field stages, energy transport characteristics during wake evolution, and the formation mechanisms and characterization rules of large-scale vortex streets, have been well understood. However, as research continues to advance, researchers have gradually realized that, for underwater moving objects, the jet momentum wake generated by the propulsion system is equally important as the momentum wake caused by the resistance of the hull.
To study the generation and evolution of momentum wakes, the traditional approach has been to simplify the effects of the propulsion system, such as jetting, by equivalent representation as jet flow through a nozzle. In early studies, a linearly stratified environment was created in a density-stratified water tank, and the motion of dye-colored liquid was used to simulate the effects of a moving jet. Under the appropriate conditions of jet momentum flow, it was found that a pair of oppositely rotating dipole vortices could be easily generated. This is an early discovered Q2D structure present in density-stratified fluids. Numerous theoretical, numerical simulation, and experimental results have been obtained regarding the generation mechanism and evolutionary characteristics of these dipoles. These dipole vortices can interact with each other or with solid structures, leading to many meaningful phenomena [64,65].
In experiments conducted in density-stratified water tanks using the method of moving a dye-colored liquid to simulate the effects of a moving jet, it was demonstrated that both steady and unsteady moving jet flows in density-stratified fluids can lead to the formation of large-scale quasi-two-dimensional dipole vortex street structures [66]. The rotation direction of these vortices is consistent with the Karman vortex street, also known as the positive Karman-type dipole vortex street. The actual oceanic scale of these large-scale dipole vortex street structures can reach 1 to 2 km, and the decay time required can be several days. Additionally, significant vortex flow features can be observed on the free surface [67]. Relevant research indicates that although the structures of jet momentum wakes and resistance momentum wakes differ in the near-field, and the induced velocity distributions are inconsistent, and the evolution characteristics of the two wakes have similarities. The buoyancy effect of stratified fluids has a similar inhibitory effect on the vertical motion of both types of momentum wakes, and the energy dissipation patterns within the wakes during the collapse and late wake also exhibit similarities [50,68].
In recent years, the evolution characteristics of the self-propelled momentum wake of underwater moving bodies have been increasingly emphasized. This is because, in real-world scenarios, underwater moving bodies generate both resistance momentum wakes from their hulls and jet momentum wakes from their propulsion systems. The interaction between these two types of momentum significantly influences the formation of large-scale vortex structures in self-propelled bodies.

3.3. Computational Fluid Dynamics

Numerical simulations have emerged as a powerful tool for studying stratified wakes, offering detailed insights beyond the limitations of experiments. Unlike experiments, numerical methods can readily handle high Reynolds numbers and complex geometries, enabling a deeper understanding of wake dynamics.
Early studies have focused on spheres, highlighting the significant impact of initial conditions on near-wake characteristics. However, the late wake, characterized by large-scale dipole vortex streets, was found to be less sensitive, behaving similarly to a turbulent water mass. Comparing homogeneous and stratified fluids, researchers have observed a striking difference in energy dissipation. In homogeneous fluids, the wake’s energy rapidly dissipates, while in stratified fluids, it remains significantly higher, highlighting the stabilizing effect of stratification.
Gourlay et al. [69] have paved the way for direct numerical simulation (DNS) of turbulent wakes. Later, large eddy simulation (LES) was employed by Dommermuth et al. [70] and Diamessis et al. [71] to successfully capture the late-wake structures, confirming their agreement with experimental findings. Further intriguing findings came from Menuier et al. [72], who have identified an additional viscous three-dimensional wake stage following the near-wake, collapse, and late-wake stages. Numerical simulations excel in their ability to tackle high Reynolds numbers, exceeding the capabilities of experiments. Diamessis et al. [73] have reported simulations at Re = 105, an order of magnitude higher than experiments. Bonnier et al. [55] have demonstrated that late-wake dynamics are independent of initial conditions, allowing researchers like Riley and Debruynkops [74], Waite and Bartello [75], Brethouwer et al. [76], Deloncle et al. [77], Augier and Billant [78], and Augier et al. [79] to study wake evolution at higher Re values by simply increasing computational costs.
To alleviate computational burdens, researchers have introduced the temporal evolution model [80,81,82]. This approach utilizes the stabilized wake flow field as an initial condition, effectively skipping the early stages of wake evolution. However, Redford et al. [83] have revealed its sensitivity to initial conditions, impacting velocity decay patterns and potentially leading to inaccurate results. Recognizing the limitations of the time model, some researchers have opted for direct simulations. This approach avoids the need for initial conditions but requires more cells, making it computationally expensive for high-Re and low-Fr conditions. Pasquetti [84] and Vandine et al. [85] have proposed a hybrid approach, directly simulating the near wake and employing a time model or spatially evolving model for the far wake.
Direct simulations of spheres at low Re have only recently become feasible. Orr et al. [86] have simulated conditions with Re = 1000, and Pal et al. [87] have simulated wakes at low Reynolds numbers (Re = 3700) and low Froude numbers (Fr < O(1)). These simulations have captured patterns of vortex shedding from the object, wake oscillations modulated by lee waves, wake fluctuations activated in low Froude number conditions, and unique phenomena of vortex dynamics in density-stratified flows. These features are evidently challenging to capture using a time model. Through the combined study of experiments and numerical simulations, researchers have clarified the entire process of the evolution of wakes behind a sphere in density-stratified flows across various stages.
Recently, there has been significant progress in numerical modeling for linearly stratified fluids based on density and temperature. Magnaudet and Mercier [88] and Zhang et al. [89] have developed their proprietary code, JADIM, which discretizes governing equations using the finite volume method and directly solves Navier–Stokes equations. The code includes boundary-fitted methods and a fixed grid approach, enabling it to handle rigid body motion and interface topological deformation. It is suitable for DNS simulations of two-phase and three-phase flows. Brucker and Sarkar [80], de Stadler and Sarkar [81], Pal et al. [87], and Ortiz-Tarin et al. [90] have used a direct simulation approach to simulate the turbulent flow around spheres and ellipsoids in stratified flows. They have mainly analyzed the effects of Reynolds number, internal Froude number, and geometric factors on turbulent wakes. Their results indicate that density gradients significantly influence the evolution of separated shear flows, recirculation, and turbulent wakes. It was demonstrated that even for weakly stratified flows, the late wake morphology tends to Fr = O(1), implying that density stratification leads to a larger spreading and longer duration of turbulent wakes. Diamessis et al. [73], Abdilghanie and Diamessis [82], and Zhou and Diamessis [91] have introduced the spectral multidomain penalty method (SMPM) model, which is an implicit LES method for solving incompressible Navier–Stokes equations. SMPM is primarily used to simulate local stratified turbulence in high-Reynolds number conditions.
The studies mentioned above have often focused on simple geometries like spheres, and DNS and LES methods were commonly employed for turbulent flow simulations. While these methods offer high computational accuracy and a detailed capture of flow phenomena, they come with high computational costs, making them almost impractical for engineering applications in high-Reynolds number conditions. For example, in simulating the turbulent wake behind a sphere using LES, when Re = 4 × 105 and Fr = 4, the required number of grids reached 1024 × 512 × 1106 = 579,862,528, and the computational time was 5 × 106 CPU/h. Such computational costs make it nearly impossible to simulate the hydrodynamic wakes of underwater vehicles in practical engineering applications. Thus, even in the design phase, there is limited consideration for the hydrodynamic performance of underwater vehicles in realistic stratified ocean environments, and the prediction and assessment of complex turbulent flows are rarely addressed. This discrepancy with the actual operating environment prevents an accurate prediction of the hydrodynamic performance in real ocean conditions.
In recent years, researchers in the field of ocean engineering have made initial explorations into simulating the wake fields of underwater vehicles in linearly stratified fluids with density and temperature variations. Esmaeilpour [92], Liu et al. [93], and Li et al. [94] have simulated near wakes of underwater vehicles and surface ships, including bubbly mixed flow, highlighting the substantial impact of linear stratification on hydrodynamic vessel performance. Ma et al. [95,96] have employed a hybrid grid and DES model to study underwater vehicles in linearly stratified fluids, examining the influence of parameters like speed, depth, density gradient, and motion attitude on turbulent wakes at the free surface. Cao et al. [97,98,99] and Huang et al. [100] have proposed a thermocline model based on Boussinesq approximation, simulating vortical structures and wakes of sphere and a generic submarine model in homogeneous and stratified environments. Anisotropy of the surface wave crest and trough, along with a larger influencing zone of Kelvin waves, was evident in the stratified case (Figure 3).
Shi et al. [101] have studied the wave-making wake of maneuvering underwater vehicles in density-stratified fluid using RANS simulation, revealing Kelvin wave system characteristics and notable hydrodynamic performance changes with increasing drift angle. Jones and Paterson [102] have investigated swirl’s impact on the near wake of a self-propelled axisymmetric vehicle with three propulsor schemes, noting reduced potential energy in the CRP configuration. Wang et al. [103] and Li et al. [104] have used CFD and the modified Korteweg-de Vries theory to simulate the interaction between internal solitary waves (ISWs) and submerged bodies, discussing forces and moments on submarine models at different submergence depths [105]. He et al. [106] have proposed a new numerical scheme for ISW generation with a current, demonstrating the interaction between a moving submarine and ISWs under varying pycnocline thicknesses and speeds.
In summary, the numerical simulation work on the hydrodynamic wakes of underwater vehicles in linearly stratified fluids, as mentioned above, has some limitations and shortcomings. Firstly, most of the current work focuses on simple geometric shapes such as spheres, ellipsoids, disks, plates, etc. The turbulent wakes of these geometric shapes exhibit strong regularity, and there is a relatively clear understanding of the wakes formed in linearly stratified fluids. However, the shapes of most marine and ocean engineering models are highly complex, and their turbulent characteristics vary widely. Therefore, corresponding numerical methods must be developed for the study of actual oceanic vehicles. Secondly, the Reynolds numbers in the mentioned research are generally low, typically ranging from Re = [100 to 105], while the Reynolds numbers of ships and marine engineering models are mostly above 106, and the Reynolds numbers at actual scales can reach 109, with more prominent instantaneous and turbulent characteristics. The flow phenomena are significantly different at these higher Reynolds numbers. Finally, the aforementioned works mainly focus on the model scale of underwater vehicles, with almost no simulations conducted at the actual scale of underwater vehicles. Currently, there is no relevant research on the similarity principles of flow fields in linearly stratified fluids, making it difficult to obtain an accurate overview of the hydrodynamics and flow fields of underwater vehicles at high Reynolds numbers and actual scales. Therefore, it is essential to conduct an analysis of the hydrodynamics of underwater vehicles in linearly stratified fluids and their free surface characteristics.

4. Thermodynamic Wakes in Stratified Fluid

When a submerged body is in motion underwater, especially the rotation of the stern propeller and the generation of specific spatiotemporal scale wake vortices, it stirs the surrounding fluid, thereby disturbing the originally stable stratified structure. This disturbance leads to the excitation of internal waves, disrupting the original density and temperature distribution characteristics. In addition, the rotation of the hull and propeller generates heat due to the impact friction with seawater. Submerged bodies, especially those with nuclear power systems releasing cooling water, can cause a rapid increase in the surrounding seawater temperature. The corresponding reduction in the density of some seawater during the diffusion process gradually causes it to rise.
Stefanick [5] has pointed out that a nuclear-powered submarine with a power of 190 MW and a speed of 5 knots would release about 45 million calories of heat energy per second into the ocean, or 45.4 °C cubic meters of hot water. The emitted heat energy causes the seawater behind the underwater vehicle to immediately rise by 0.2 °C. Although submerged vehicles continuously release heat, the emitted heat energy is quickly diluted by the surrounding seawater. About 1 km downstream of a normally traveling underwater vehicle, the temperature change in the seawater may be only about one hundredth of a degree Celsius. The attenuation of the thermal wake temperature difference signal intensity is relatively fast in the initial stage, but over a long distance with the rise in height, the weakening of the thermal signal is extremely slow. Even after rising several tens of meters, the thermal wake still shows temperature changes in the order of 0.1 °C. During the wake’s ascent, its width keeps increasing, and the thermal trace signal width of a typical underwater vehicle on the water surface can reach from a dozen to several dozen meters.
Only when changes in seawater temperature are reflected on the sea surface can they be detected by the thermal imaging system of an infrared detector. Currently, airborne and spaceborne high-sensitivity infrared detectors can sense temperature differences as small as 0.001 °C on the sea surface [107]. By detecting temperature imaging over a wide range of sea areas, it is possible to monitor the thermal wake of underwater vehicles in all weather conditions and analyze their heading, speed, and depth characteristics. However, detecting the thermal wake of underwater vehicles from the vast ocean is not easy; the temperature change caused by underwater vehicles on the sea surface must be at least 0.005 °C or more to be detectable. This is because, except for the Arctic region, the average temperature gradient of seawater on Earth is 0.005 °C/m [108].

4.1. Theoretical and Experimental Methods

As early as the 1950s, researchers discovered that the cooling water discharged by surface and underwater vessels leaves behind a “thermal wake” on the sea surface. The Naval Air Development Center of the United States proposed a detection technology project for submarine wakes as early as 1957, defining two types of submarine wakes: “thermal wakes” related to changes in sea surface temperature, and “turbulent wakes” generated by submarine turbulence [109]. In 1959, Moser [107] pointed out in a technical report for the U.S. military that a P2V-5 aircraft, flying at an altitude of approximately 150 m with a speed of 18 knots and equipped with a thermal sensor with a sensitivity of 0.0016 K, could monitor the “thermal wake” of a submarine at a depth of 50 m in all weather conditions. The results showed that submarines caused a sea surface temperature change of 0.04 °C (night) to 0.1 °C (day), and that the width of the “thermal wake” impact range could be up to 100 to 120 m.
In 1984, Gebhart et al. [110] simplified the process of submarine power plant coolant discharge to a small pipe thermal jet. They established a mathematical model that could predict the trajectory and attenuation of the thermal jet in uniform and stratified fluids through theoretical modeling and experimental verification. In the 1980s, experimental research on the “thermal wake” of surface vessels began to emerge. For example, Garrett and Smith [111] and Peltzer et al. [112] used infrared remote sensing on an aircraft to analyze the distribution of the thermal wake of a 75 m catamaran. They pointed out that although the wake was called “thermal surface characteristics,” the measurement results showed that the actual surface wake was a cold wake, meaning that the wake temperature was lower than the temperature of the ambient water. In the experiment, to make the wake signal more clearly detected by infrared remote sensing, oil alcohol was sprayed behind the hull, and the wake with chemical substances mixed in showed more pronounced temperature difference signals, more persistent characteristics, and a larger impact range. In this case, the maximum temperature difference of the wake can reach 0.8 °C, and the impact range can extend to about 3 km behind the hull. However, searching for targets in the vast ocean through the temperature difference of the wake without knowing the specific location of the vessel is challenging. Schwartz and Priest [113] have pointed out that the temperature difference between the ship’s wake and the background water shown in infrared remote sensing images may be due to reflection phenomena rather than actual temperature differences. If observed from different angles, even if the wake and the background water have the same temperature, the infrared remote sensing image may erroneously show a temperature difference. Therefore, he corrected the infrared contrast between the ship’s wake and the rough sea surface in the calculation model, correcting the temperature deviation in the infrared remote sensing image.
However, due to the complexity of the ocean itself and limitations in experimental conditions, most of the experiments mentioned above have focused on only studying the ascent and diffusion patterns of thermal wakes emitted by underwater vehicle models. It is challenging to directly conduct experimental research on the process of full-scale underwater vehicles emitting thermal wakes. Yang et al. [114], based on the principle of similarity, have designed a scaled-down model infrared imaging experimental test system using geometric similarity, temperature field similarity, drained heat flux similarity, and density field similarity. The system systematically investigated the infrared characteristics of submarine thermal wakes under two different conditions: stationary thermal plumes and towed thermal plumes.

4.2. Computational Fluid Dynamics

The emission, diffusion, and ascent process of thermal wakes from underwater vehicles are fundamentally a heat and mass transfer process into the seawater. The entire process is highly complex, and relying solely on experiments makes it difficult to fully uncover the mysteries of the thermodynamic wake generation and propagation of underwater vehicles. It is challenging to conduct experiments specifically for full-scale underwater vehicles. Experimental research is costly and time-consuming, and the accuracy is constrained by the precision of measurement methods and instruments.
With the development of computer technology, researchers have both domestically and internationally begun using numerical methods to simulate the emission process of thermal wakes from underwater vehicles. Similar to experimental approaches, numerical simulation studies often start with simpler objects. For example, Smith et al. [115] and Judd et al. [116] have studied underwater vortex pairs and thermal plumes, respectively, analyzing their thermal characteristics after interacting with the free liquid surface. Moody et al. [117] have calculated the structure and intensity of the wake generated by a cylinder moving in stratified fluid and analyzed the thermal trace on the free surface.
Due to secrecy concerns, there is not much publicly available literature on the numerical simulation of naval thermal wakes. Only a few articles describe relevant research on ship thermal wakes. Schwartz and Priest [113] have proposed a corrected model to predict the spreading process of ship wakes in the background sea. Voropayev et al. [118] have simulated the main processes of ship-generated thermal wakes. They pointed out that when a ship travels in the ocean, the propeller and hull will mix the surface seawater with the colder water below, causing a temperature difference of approximately 1 to 2 °C.
The issue of thermal wakes from underwater vehicles not only involves the emission process of underwater thermal wakes but also includes the detection of surface thermal signals. Therefore, capturing surface thermal signals is also an important consideration in the computational process. In recent years, as CFD has matured, researchers have gained the capability to thoroughly investigate the entire process of thermal wakes induced by the discharge of cooling water from realistic submarine models. Luo et al. [119] and Li et al. [120] have used overlapping grids to more accurately simulate the motion of submarine models. They have discovered that compared to traditional inflow methods, the results obtained using overlapping grids have high accuracy and can fully reflect the ascent and spreading process of thermal wakes, especially the vortex characteristics.
In summary, the generation of the thermal wake of an underwater vehicle is typically coupled with the creation of its hydrodynamic wake. The mechanisms involved in their generation and propagation are highly intricate. However, most current research primarily focuses on the emission and ascent-spreading processes of underwater vehicle thermal wakes, with limited attention given to the simultaneous propagation of thermal wakes and hydrodynamic wakes. Additionally, experimental and numerical simulation efforts related to the emission process of underwater vehicle thermal wakes are often conducted at a model scale. When studying the influence of factors such as velocity, submersion depth, and the linear stratification of density and temperature on thermal wake patterns, there is often a lack of effective establishment of scaled ocean stratification environments, similarities in the excitation of internal waves by underwater vehicles, and correspondence between the model scale and the actual scale in the wake propagation process. Consequently, there is an insufficient understanding of the ascent and spreading processes of actual underwater vehicle thermal wakes. Therefore, it is crucial to conduct simulations of the emission, ascent, spreading, and propagation of actual-scale underwater vehicle thermal wakes to the free surface in linearly stratified fluid, as well as to analyze the characteristics of the free surfaces.

5. Conclusions

This review focuses specifically on the hydrodynamic and thermodynamic wakes of underwater vehicles in stratified fluids, providing a comprehensive overview of the current research landscape from theoretical, experimental, and computational perspectives. The key conclusions drawn are as follows:
  • After decades of research, there is now a thorough understanding of the evolution of wakes generated by simple geometric bodies, such as spheres and cylinders, in stratified fluids. Clear insights into the flow characteristics during the near-wake, non-equilibrium, and far-field developmental stages of wakes have been gained. Additionally, the understanding of the energy transport during wake evolution and the formation mechanisms and features of large-scale vortex streets has been greatly enhanced.
  • In recent years, there has been a growing focus on the evolution characteristics of wakes generated by underwater vehicles with complex shapes. Changes in the hydrodynamic performance of underwater vehicles in linearly stratified flows of density and temperature, along with the extensive generation, evolution, and flow characteristics of hydrodynamic and thermodynamic wakes, have gradually become subjects of study. Comparisons with uniform flows demonstrate that the wakes of underwater vehicles in stratified flows exhibit a larger propagation range and a longer duration.
  • Due to the complexity of the marine environment and limitations in experimental conditions, research on underwater vehicle wakes in stratified flows is often conducted at model scales. Currently, there is a lack of research on similarity criteria for flow fields in stratified fluids. In the study of the impact of speed, depth, and stratification on wakes, an effective establishment of a scaled ocean stratified environment, a similar relationship for the excitation of internal waves, and a correspondence between model-scale and full-scale wake propagation processes have not been established.
  • With the advent of CFD technology, research methodologies have evolved from theoretical analysis and model experiments to predominantly numerical simulations, expanding toward complex geometries and high Reynolds numbers. Numerical simulations, relative to model experiments, provide more comprehensive information about the flow field.
  • The discharge of cooling water from underwater vehicles is often coupled with the generation of hydrodynamic wakes, creating highly intertwined mechanisms for their generation and propagation. However, most current studies focus solely on either the hydrodynamic or thermodynamic wakes from underwater vehicles, with little research on the mixed or coupled propagation process.
The comprehensive exploration of wakes generated by underwater vehicles in density-stratified fluids has laid a solid foundation for future investigations. As we move forward, there are several promising directions for further research.
  • Extending the current understanding of wake evolution to encompass more complex geometries, especially those representing realistic underwater vehicles, will be crucial.
  • Addressing the transition from model-scale experiments to full-scale wakes and establishing similarity criteria for flow fields in stratified fluids will enhance the applicability of findings to real-world scenarios.
  • The increasing reliance on numerical simulations opens avenues for exploring complex geometries and high Reynolds numbers. Future research could delve deeper into refining numerical methods, focusing on enhancing fidelity while managing computational costs.
  • Efforts should be directed towards bridging the gap between hydrodynamic and thermodynamic wakes, considering their intertwined nature during underwater vehicle operations.
  • The mixed or coupled propagation processes resulting from the discharge of cooling water need more attention, as existing studies often focus on either hydrodynamic or thermodynamic aspects.
By addressing these areas, future research endeavors can contribute to a more holistic understanding of wakes in density-stratified fluids, with direct implications for both academic progress and practical submarine engineering.

Author Contributions

Conceptualization, L.C. and D.W.; methodology, Y.P. and G.G.; validation, G.G. and L.L.; investigation, Y.P. and G.G.; resources, Y.P. and L.L.; writing—original draft preparation, L.C., G.G., and L.L.; writing—review and editing, L.C. and Y.P.; supervision, D.W.; project administration, D.W. All authors have read and agreed to the published version of the manuscript.

Funding

This research was partially funded by the National Natural Science Foundation of China, grand numbers 52001210 and 52131102.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflicts of interest.

Nomenclature

gGravitational acceleration
LLength
NBrunt–Väisälä frequency
TTime
U Characteristic velocity
vVelocity
xLongitudinal coordinate
yLateral coordinate
zVertical coordinate
FrInternal Froude number
ReReynolds number
StStrouhal number
ρ Density
ν Kinematic viscosity

Abbreviations

CCDCharge-coupled device
CFDComputational fluid dynamics
CPUCentral processing unit
CRPContra-rotating propellers
DESDetached eddy simulation
DNSDirect numerical simulation
ISWInternal solitary wave
JADIMIn-house computational code
K-HKelvin–Helmholtz
LESLarge eddy simulation
MWMegawatt
NEQNon-equilibrium
NWNear wake
PIVParticle image velocimetry
Q2DQuasi-two-dimensional
RANSReynolds-averaged Navier–Stokes
SARSynthetic aperture radar
SMPMSpectral multidomain penalty method
U. S.United States
WASWide-area surveillance

References

  1. Slimming, B.; Beniwal, D.; Devrelis, V.; Mau, J.; Delic, D. The non-acoustic signatures of underwater vehicles. In Ocean Sensing and Monitoring XV, Proceedings of the SPIE Defense + Commercial Sensing, Orlando, FL, USA, 30 April–5 May 2023; Spie Digital Library: Bellingham WA, USA, 2023; Volume 12543. [Google Scholar]
  2. Bürgmann, R.; Rosen, P.A.; Fielding, E.J. Synthetic aperture radar interferometry to measure Earth’s surface topography and its deformation. Annu. Rev. Earth Planet. Sci. 2000, 28, 169–209. [Google Scholar] [CrossRef]
  3. Xue, F.; Jin, W.; Qiu, S.; Yang, J. Wake features of moving submerged bodies and motion state inversion of submarines. IEEE Access 2020, 8, 12713–12724. [Google Scholar] [CrossRef]
  4. Naresh, P.; Santhanakrishnan, T.; Mathew, B. Detection of underwater targets in the ocean through non-acoustic methods. In Proceedings of the 2021 International Symposium on Ocean Technology (SYMPOL), Kochi, India, 9–11 December 2021; pp. 1–6. [Google Scholar]
  5. Stefanick, T. The nonacoustic detection of submarines. Sci. Am. 1988, 258, 41–47. [Google Scholar] [CrossRef]
  6. Baines, P.G. Upstream blocking and airflow over mountains. Annu. Rev. Fluid Mech. 1987, 19, 75–95. [Google Scholar] [CrossRef]
  7. Bonneton, P.; Chomaz, J.M.; Hopfinger, E.J. Internal waves produced by the turbulent wake of a sphere moving horizontally in a stratified fluid. J. Fluid Mech. 1993, 254, 23–40. [Google Scholar] [CrossRef]
  8. Sutyrin, G.G.; Radko, T. The fate of pancake vortices. Phys. Fluids 2017, 29, 031701. [Google Scholar] [CrossRef]
  9. Mai, T.L.; Jeon, M.; Vo, A.K.; Yoon, H.K.; Kim, S.; Lee, J. Establishment of empirical formulae for hydrodynamic derivatives of submarine considering design parameters. Int. J. Nav. Archit. Ocean Eng. 2023, 15, 100537. [Google Scholar] [CrossRef]
  10. Bridges, D.H.; Blanton, J.N.; Brewer, W.H.; Park, J.T. Experimental investigation of the flow past a submarine at angle of drift. AIAA J. 2003, 41, 71–81. [Google Scholar] [CrossRef]
  11. Overpelt, B.; Nienhuis, B.; Anderson, B. Free running manoeuvring model tests on a modern generic SSK class submarine (BB2). In Proceedings of the Pacific International Maritime Conference, Sydney, Australia, 6–8 October 2015. [Google Scholar]
  12. Carrica, P.M.; Kim, Y.; Martin, J.E. Near-surface self-propulsion of a generic submarine in calm water and waves. Ocean Eng. 2019, 183, 87–105. [Google Scholar] [CrossRef]
  13. Carrica, P.M.; Kerkvliet, M.; Quadvlieg, F.; Martin, J.E. CFD simulations and experiments of a submarine in turn, zigzag, and surfacing maneuvers. J. Ship Res. 2020, 65, 293–308. [Google Scholar] [CrossRef]
  14. Carrica, P.M.; Kim, Y.; Martin, J.E. Vertical zigzag maneuver of a generic submarine. Ocean Eng. 2021, 219, 108386. [Google Scholar] [CrossRef]
  15. Chai, J.; Wang, Z.; Yang, Z.; Wang, Z. Investigation of internal wave wakes generated by a submerged body in a stratified flow. Ocean Eng. 2022, 266, 112840. [Google Scholar] [CrossRef]
  16. Chongsiripinyo, K.; Sarkar, S. Decay of turbulent wakes behind a disk in homogeneous and stratified fluids. J. Fluid Mech. 2020, 885, A31. [Google Scholar] [CrossRef]
  17. Ortiz-Tarin, J.L.; Nidhan, S.; Sarkar, S. High-Reynolds-number wake of a slender body. J. Fluid Mech. 2021, 918, A30. [Google Scholar] [CrossRef]
  18. Ortiz-Tarin, J.L.; Nidhan, S.; Sarkar, S. The high-Reynolds-number stratified wake of a slender body and its comparison with a bluff-body wake. J. Fluid Mech. 2023, 957, A7. [Google Scholar] [CrossRef]
  19. Sudharsun, G.; Ali, A.; Mitra, A.; Jaiswal, A.; Naresh, P.; Warrior, H.V. Free surface features of submarines moving underwater: Study of Bernoulli Hump. Ocean Eng. 2022, 249, 110792. [Google Scholar]
  20. Rabaud, M.; Moisy, F. Ship Wakes: Kelvin or Mach Angle? Phys. Rev. Lett. 2013, 110, 214503. [Google Scholar] [CrossRef] [PubMed]
  21. Amiri, M.M.; Sphaier, S.H.; Vitola, M.A.; Esperança, P.T. Investigation into the wave system of a generic submarine moving along a straight path beneath the free surface. Eur. J. Mech. B/Fluids 2019, 76, 98–114. [Google Scholar] [CrossRef]
  22. Garrett, C.; Munk, W. Internal waves in the ocean. Annu. Rev. Fluid Mech. 1979, 11, 339–369. [Google Scholar] [CrossRef]
  23. Voropayev, S.I.; Mceachern, G.B.; Fernando, H.J.S.; Boyer, D.L. Large vortex structures behind a maneuvering body in stratified fluids. Phys. Fluids 1999, 11, 1682–1684. [Google Scholar] [CrossRef]
  24. Bondur, V.G.; Ivanov, V.A.; Fomin, V.V. Peculiarities of polluted water spreading from a submarine source in stratified coastal environment. Izv. Atmos. Ocean. Phys. 2018, 54, 386–393. [Google Scholar] [CrossRef]
  25. Wang, C.; Xu, D.; Gao, J.; Tan, J.; Zhou, Z. Numerical study of surface thermal signatures of lee waves excited by moving underwater sphere at low Froude number. Ocean Eng. 2021, 235, 109314. [Google Scholar] [CrossRef]
  26. Rott, N. Note on the history of the Reynolds number. Annu. Rev. Fluid Mech. 1990, 22, 1–12. [Google Scholar] [CrossRef]
  27. Oertel, H., Jr. Wakes behind blunt bodies. Annu. Rev. Fluid Mech. 1990, 22, 539–562. [Google Scholar] [CrossRef]
  28. Spedding, G.R. Wake signature detection. Annu. Rev. Fluid Mech. 2014, 46, 273–302. [Google Scholar] [CrossRef]
  29. Vallis, G.K. Atmospheric and Oceanic Fluid Dynamics: Fundamentals and Large-Scale Circulation; Cambridge University Press: Cambridge, UK, 2017; ISBN 9781107065505. [Google Scholar]
  30. Hudimac, A.A. Ship waves in a stratified ocean. J. Fluid Mech. 1961, 11, 229–243. [Google Scholar] [CrossRef]
  31. Keller, J.B.; Munk, W.H. Internal Wave Wakes of a Body Moving in a Stratified Fluid. Phys. Fluids 1970, 13, 1425–1431. [Google Scholar] [CrossRef]
  32. Voisin, B. Internal wave generation in uniformly stratified fluids. Part 1. Green’s function and point sources. J. Fluid Mech. 1991, 231, 439–480. [Google Scholar] [CrossRef]
  33. Voisin, B. Internal wave generation in uniformly stratified fluids. Part 2. Moving point sources. J. Fluid Mech. 1994, 261, 333–374. [Google Scholar] [CrossRef]
  34. Zhu, R.C.; Gao, Y.; Miao, G.P.; Yao, Z.C. Green’s function of internal waves in uniformly stratified fluid. J. Shanghai Jiaotong Univ. 2016, 50, 265–271. [Google Scholar]
  35. Miles, J.W. Lee waves in a stratified flow Part 1. Thin barrier. J. Fluid Mech. 1968, 32, 549–567. [Google Scholar] [CrossRef]
  36. Miles, J.W.; Huppert, H.E. Lee waves in a stratified flow. Part 2. Semi-circular obstacle: Appendix. J. Fluid Mech. 1968, 33, 803–814. [Google Scholar] [CrossRef]
  37. Miles, J.W.; Huppert, H.E. Lee waves in a stratified flow. Part 4. Perturbation approximations. J. Fluid Mech. 1969, 35, 497–525. [Google Scholar] [CrossRef]
  38. Huppert, H.E.; Miles, J.W. Lee waves in a stratified flow Part 3. Semi-elliptical obstacle. J. Fluid Mech. 1969, 35, 481–496. [Google Scholar] [CrossRef]
  39. Long, R.R. Some aspects of the flow of stratified fluids: I. A theoretical investigation. Tellus 1953, 5, 42–58. [Google Scholar] [CrossRef]
  40. Long, R.R. Some aspects of the flow of stratified fluids: II. Experiments with a two-fluid system. Tellus 1954, 6, 97–115. [Google Scholar] [CrossRef]
  41. Long, R.R. Some aspects of the flow of stratified fluids: III. Continuous density gradients. Tellus 1955, 7, 341–357. [Google Scholar] [CrossRef]
  42. Tuck, E.O. Submarine Internal Waves; Materials Research Laboratory: Maribyrnong, Australia, 1993. [Google Scholar]
  43. Motygin, O.V.; Kuznetsov, N.G. The wave resistance of a two-dimensional body moving forward in a two-layer fluid. J. Eng. Math. 1997, 32, 53–72. [Google Scholar] [CrossRef]
  44. Radko, T. Ship Waves in a Stratified Fluid. J. Ship Res. 2001, 45, 1–12. [Google Scholar] [CrossRef]
  45. Stefanick, T. Strategic Antisubmarine Warfare and Naval Strategy; Lexington Books: Lexington, MA, USA, 1987. [Google Scholar]
  46. Afanasyev, Y.D. Wakes behind towed and self-propelled bodies: Asymptotic theory. Phys. Fluids 2004, 16, 3235–3238. [Google Scholar] [CrossRef]
  47. Chomaz, J.M.; Bonneton, P.; Hopfinger, E.J. The structure of the near wake of a sphere moving horizontally in a stratified fluid. J. Fluid Mech. 1993, 254, 1–21. [Google Scholar] [CrossRef]
  48. Lin, Q.; Lindberg, W.R.; Boyer, D.L.; Fernando, H.J.S. Stratified flow past a sphere. J. Fluid Mech. 1992, 240, 315–354. [Google Scholar] [CrossRef]
  49. Meunier, P.; Spedding, G.R. Stratified propelled wakes. J. Fluid Mech. 2006, 552, 229–256. [Google Scholar] [CrossRef]
  50. Spedding, G.R.; Browand, F.K.; Fincham, A.M. The long-time evolution of the initially turbulent wake of a sphere in a stable stratification. Dyn. Atmos. Oceans 1996, 23, 171–182. [Google Scholar] [CrossRef]
  51. Spedding, G.R.; Browand, F.K.; Fincham, A.M. Turbulence, similarity scaling and vortex geometry in the wake of a towed sphere in a stably stratified fluid. J. Fluid Mech. 1996, 314, 53–103. [Google Scholar] [CrossRef]
  52. Spedding, G.R. The evolution of initially turbulent bluff-body wakes at high internal Froude number. J. Fluid Mech. 1997, 337, 283–301. [Google Scholar] [CrossRef]
  53. Derakhshandeh, J.F.; Alam, M.M. A review of bluff body wakes. Ocean Eng. 2019, 182, 475–488. [Google Scholar] [CrossRef]
  54. Thompson, M.C.; Leweke, T.; Hourigan, K. Bluff bodies and wake–wall interactions. Annu. Rev. Fluid Mech. 2021, 53, 347–376. [Google Scholar] [CrossRef]
  55. Bonnier, M.; Eiff, O.; Bonneton, P. On the density structure of far-wake vortices in a stratified fluid. Dyn. Atmos. Oceans 2000, 31, 117–137. [Google Scholar] [CrossRef]
  56. Spedding, G.R. The streamwise spacing of adjacent coherent structures in stratified wakes. Phys. Fluids 2002, 14, 3820–3828. [Google Scholar] [CrossRef]
  57. Bonnier, M.; Eiff, O. Experimental investigation of the collapse of a turbulent wake in a stably stratified fluid. Phys. Fluids 2002, 14, 791–801. [Google Scholar] [CrossRef]
  58. De Silva, I.; Fernando, H. Some aspects of mixing in a stratified turbulent patch. J. Fluid Mech. 1992, 240, 601–625. [Google Scholar] [CrossRef]
  59. Lin, Q.; Boyer, D.L.; Fernando, H.J.S. Turbulent wakes of linearly stratified flow past a sphere. Phys. Fluids 1992, 4, 1687–1696. [Google Scholar] [CrossRef]
  60. Lofquist, K.E.B.; Purtell, L.P. Drag on a sphere moving horizontally through a stratified liquid. J. Fluid Mech. 1984, 148, 271–284. [Google Scholar] [CrossRef]
  61. Honji, H. Near wakes of a sphere in a stratified fluid. Fluid Dyn. Res. 1987, 2, 75–76. [Google Scholar] [CrossRef]
  62. Kopp, G.A.; Keffer, J.F. Coherent structures in two uniformly distorted plane turbulent wakes. Phys. Fluids 1996, 8, 2706–2711. [Google Scholar] [CrossRef]
  63. Fonseka, S.V.; Fernando, H.; Van Heijst, G. Evolution of an isolated turbulent region in a stratified fluid. J. Geophys. Res. 1998, 103, 24–868. [Google Scholar] [CrossRef]
  64. Praud, O.; Fincham, A.M. The structure and dynamics of dipolar vortices in a stratified fluid. J. Fluid Mech. 2005, 544, 1–22. [Google Scholar] [CrossRef]
  65. Voropayev, S.I.; Fernando, H.J.S.; Morrison, R. Dipolar eddies in a decaying stratified turbulent flow. Phys. Fluids 2008, 20, 26602. [Google Scholar] [CrossRef]
  66. Voropayev, S.I.; Smirnov, S.A. Vortex streets generated by a moving momentum source in a stratified fluid. Phys. Fluids 2003, 15, 618–624. [Google Scholar] [CrossRef]
  67. Voropayev, S.I.; Fernando, H.J.S.; Smirnov, S.A.; Morrison, R. On surface signatures generated by submerged momentum sources. Phys. Fluids 2007, 19, 76603. [Google Scholar] [CrossRef]
  68. Chen, K.; You, Y.; Noblesse, F. Experimental study of quasi-2D dipolar vortex streets generated by a moving momentum source in a stratified fluid. Phys. Fluids 2016, 28, 75105. [Google Scholar] [CrossRef]
  69. Gourlay, M.J.; Arendt, S.C.; Fritts, D.C.; Werne, J. Numerical modeling of initially turbulent wakes with net momentum. Phys. Fluids 2001, 13, 3783–3802. [Google Scholar] [CrossRef]
  70. Dommermuth, D.G.; Innis, G.E.; Novikov, E.A.; Rottman, J.W. Numerical simulation of the wake of a towed sphere in a weakly stratified fluid. J. Fluid Mech. 2002, 473, 83–101. [Google Scholar] [CrossRef]
  71. Diamessis, P.J.; Domaradzki, J.A.; Hesthaven, J.S. A spectral multidomain penalty method model for the simulation of high Reynolds number localized incompressible stratified turbulence. J. Comput. Phys. 2005, 202, 298–322. [Google Scholar] [CrossRef]
  72. Meunier, P.; Diamessis, P.J.; Spedding, G.R. Self-preservation in stratified momentum wakes. Phys. Fluids 2006, 18, 106601. [Google Scholar] [CrossRef]
  73. Diamessis, P.J.; Domaradzki, J.A.; Spedding, G.R. Similarity scaling and vorticity structure in high-Reynolds-number stably stratified turbulent wakes. J. Fluid Mech. 2011, 671, 52–95. [Google Scholar] [CrossRef]
  74. Riley, J.J.; Debruynkops, S.M. Dynamics of turbulence strongly influenced by buoyancy. Phys. Fluids 2003, 15, 2047–2059. [Google Scholar] [CrossRef]
  75. Waite, M.L.; Bartello, P. Stratified turbulence dominated by vortical motion. J. Fluid Mech. 2004, 517, 281–308. [Google Scholar] [CrossRef]
  76. Brethouwer, G.; Billant, P.; Lindborg, E.; Chomaz, J. Scaling analysis and simulation of strongly stratified turbulent flows. J. Fluid Mech. 2007, 585, 343–368. [Google Scholar] [CrossRef]
  77. Deloncle, A.; Billant, P.; Chomaz, J. Nonlinear evolution of the zigzag instability in stratified fluids: A shortcut on the route to dissipation. J. Fluid Mech. 2008, 599, 229–239. [Google Scholar] [CrossRef]
  78. Augier, P.; Billant, P. Onset of secondary instabilities on the zigzag instability in stratified fluids. J. Fluid Mech. 2011, 682, 120–131. [Google Scholar] [CrossRef]
  79. Augier, P.; Billant, P.; Chomaz, J. Spectral analysis of the transition to turbulence from a dipole in stratified fluid. J. Fluid Mech. 2012, 713, 86–108. [Google Scholar] [CrossRef]
  80. Brucker, K.A.; Sarkar, S. A comparative study of self-propelled and towed wakes in a stratified fluid. J. Fluid Mech. 2010, 652, 373–404. [Google Scholar] [CrossRef]
  81. de Stadler, M.B.; Sarkar, S. Simulation of a propelled wake with moderate excess momentum in a stratified fluid. J. Fluid Mech. 2012, 692, 28–52. [Google Scholar] [CrossRef]
  82. Abdilghanie, A.M.; Diamessis, P.J. The internal gravity wave field emitted by a stably stratified turbulent wake. J. Fluid Mech. 2013, 720, 104–139. [Google Scholar] [CrossRef]
  83. Redford, J.A.; Lund, T.S.; Coleman, G.N. A numerical study of a weakly stratified turbulent wake. J. Fluid Mech. 2015, 776, 568–609. [Google Scholar] [CrossRef]
  84. Pasquetti, R. Temporal/spatial simulation of the stratified far wake of a sphere. Comput. Fluids 2011, 40, 179–187. [Google Scholar] [CrossRef]
  85. Vandine, A.; Chongsiripinyo, K.; Sarkar, S. Hybrid spatially-evolving DNS model of flow past a sphere. Comput. Fluids 2018, 171, 41–52. [Google Scholar] [CrossRef]
  86. Orr, T.S.; Domaradzki, J.A.; Spedding, G.R.; Constantinescu, G.S. Numerical simulations of the near wake of a sphere moving in a steady, horizontal motion through a linearly stratified fluid at Re = 1000. Phys. Fluids 2015, 27, 35113. [Google Scholar] [CrossRef]
  87. Pal, A.; Sarkar, S.; Posa, A.; Balaras, E. Regeneration of turbulent fluctuations in low-Froude-number flow over a sphere at a Reynolds number of 3700. J. Fluid Mech. 2016, 804, R2. [Google Scholar] [CrossRef]
  88. Magnaudet, J.; Mercier, M.J. Particles, drops, and bubbles moving across sharp interfaces and stratified layers. Annu. Rev. Fluid Mech. 2020, 52, 61–91. [Google Scholar] [CrossRef]
  89. Zhang, J.; Mercier, M.J.; Magnaudet, J. Core mechanisms of drag enhancement on bodies settling in a stratified fluid. J. Fluid Mech. 2019, 875, 622–656. [Google Scholar] [CrossRef]
  90. Ortiz-Tarin, J.L.; Chongsiripinyo, K.C.; Sarkar, S. Stratified flow past a prolate spheroid. Phys. Rev. Fluids 2019, 4, 94803. [Google Scholar] [CrossRef]
  91. Zhou, Q.; Diamessis, P.J. Large-scale characteristics of stratified wake turbulence at varying Reynolds number. Phys. Rev. Fluids 2019, 4, 84802. [Google Scholar] [CrossRef]
  92. Esmaeilpour, M. A ship Advancing in a Stratified Fluid: The Dead Water Effect Revisited. Doctoral Dissertation, University of Iowa, Iowa City, IA, USA, 2017. [Google Scholar]
  93. Liu, S.; He, G.; Wang, Z.; Luan, Z.; Zhang, Z.; Wang, W.; Gao, Y. Resistance and flow field of a submarine in a density stratified fluid. Ocean Eng. 2020, 217, 107934. [Google Scholar] [CrossRef]
  94. Li, J.; Martin, J.E.; Carrica, P.M. Large-scale simulation of ship bubbly wake during a maneuver in stratified flow. Ocean Eng. 2019, 173, 643–658. [Google Scholar] [CrossRef]
  95. Ma, W.; Li, Y.; Ding, Y.; Hu, K.; Lan, L. Numerical simulations of linearly stratified flow past submerged bodies. Pol. Marit. Res. 2018, 25, 68–77. [Google Scholar] [CrossRef]
  96. Ma, W.; Li, Y.; Ding, Y.; Duan, F.; Hu, K. Numerical investigation of internal wave and free surface wave induced by the DARPA SUBOFF moving in a strongly stratified fluid. Ships Offshore Struct. 2020, 15, 587–604. [Google Scholar] [CrossRef]
  97. Cao, L.; Huang, F.; Wan, D.; Gao, Y. Computational Analysis of Sphere Wakes in a Linearly Stratified Fluid. Int. J. Offshore Pol. Eng. 2021, 31, 309–315. [Google Scholar] [CrossRef]
  98. Cao, L.; Huang, F.; Liu, C.; Wan, D. Vortical structures and wakes of a sphere in homogeneous and density stratified fluid. J. Hydrodyn. 2021, 33, 207–215. [Google Scholar] [CrossRef]
  99. Cao, L.; Gao, G.; Guo, E.; Wan, D. Hydrodynamic performances and wakes induced by a generic submarine operating near the free surface in continuously stratified fluid. J. Hydrodyn. 2023, 35, 396–406. [Google Scholar] [CrossRef]
  100. Huang, F.; Meng, Q.; Cao, L.; Wan, D. Wakes and free surface signatures of a generic submarine in the homogeneous and linearly stratified fluid. Ocean Eng. 2022, 250, 111062. [Google Scholar] [CrossRef]
  101. Shi, C.; Cheng, X.; Liu, Z.; Han, K.; Liu, P.; Jiang, L. Numerical simulation of the maneuvering motion wake of an underwater vehicle in stratified fluid. J. Mar. Sci. Eng. 2022, 10, 1672. [Google Scholar] [CrossRef]
  102. Jones, M.C.; Paterson, E.G. Influence of propulsion type on the stratified near wake of an axisymmetric self-propelled body. J. Mar. Sci. Eng. 2018, 6, 46. [Google Scholar] [CrossRef]
  103. Wang, C.; Wang, J.; Liu, Q.; Zhao, S.; Li, Z.; Kaidi, S.; Hu, H.; Chen, X.; Du, P. Dynamics and “falling deep” mechanism of submerged floating body under internal solitary waves. Ocean Eng. 2023, 288, 116058. [Google Scholar] [CrossRef]
  104. Li, Z.; Hu, H.; Wang, C.; Xie, Z.; Chen, X.; Yuan, Z.; Du, P. Hydrodynamics and stability of oblique water entry in waves. Ocean Eng. 2024, 292, 116506. [Google Scholar] [CrossRef]
  105. Li, J.; Zhang, Q.; Chen, T. Numerical investigation of internal solitary wave forces on submarines in continuously stratified fluids. J. Mar. Sci. Eng. 2021, 9, 1374. [Google Scholar] [CrossRef]
  106. He, G.; Xie, H.; Zhang, Z.; Liu, S. Numerical investigation of internal solitary wave forces on a moving submarine. J. Mar. Sci. Eng. 2022, 10, 1020. [Google Scholar] [CrossRef]
  107. Moser, P.M. Infrared Wake Detection; Anti-Submarine Warfare Laboratory, Naval Air Development Center: Warminster, PA, USA, 1959. [Google Scholar]
  108. Yu, J.; Campos, E.; Du, Y.; Eldevik, T.; Gille, S.T.; Losada, T.; Mcphaden, M.J.; Smedsrud, L.H. Variability of the oceans, In Interacting Climates of Ocean Basins; Cambridge University Press: Cambridge, UK, 2020. [Google Scholar]
  109. Moser, P.M. Submarine Wake Detection Program; Anti-Submarine Warfare Laboratory, Naval Air Development Center: Warminster, PA, USA, 1959. [Google Scholar]
  110. Gebhart, B.; Hilder, D.S.; Kelleher, M. The diffusion of turbulent buoyant jets. Adv. Heat Transf. 1984, 16, 1–57. [Google Scholar]
  111. Garrett, W.D.; Smith, P.M. Physical and Chemical Factors Affecting the Thermal IR Imagery of Ship Wakes; Naval Research Laboratory: Washington, DC, USA, 1984. [Google Scholar]
  112. Peltzer, R.; Garrett, W.; Smith, P. A remote sensing study of a surface ship wake. In Proceedings of the OCEANS’85—Ocean Engineering and the Environment, San Diego, CA, USA, 12–14 November 1985; pp. 277–286. [Google Scholar]
  113. Schwartz, I.B.; Priest, R.G. Reflection Driven Ship Wake Contrasts in the Infrared; NRL Report 9144; Naval Research Laboratory: Stennis Space Center, MS, USA, 1988. [Google Scholar]
  114. Yang, W.; Zhang, Z.; Li, J.; Yu, Z. Thermal wakes detectability of submerged objects based on scale model. Infrared Laser Eng. 2016, 45, 302002. [Google Scholar] [CrossRef]
  115. Smith, G.B.; Volino, R.J.; Handler, R.A.; Leighton, R.I. The thermal signature of a vortex pair impacting a free surface. J. Fluid Mech. 2001, 444, 49–78. [Google Scholar] [CrossRef]
  116. Judd, K.P.; Smith, G.B.; Handler, R.A.; Sisodia, A. The thermal signature of a low Reynolds number submerged turbulent jet impacting a free surface. Phys. Fluids 2008, 20, 115102. [Google Scholar] [CrossRef]
  117. Moody, Z.E.; Merriam, C.J.; Radko, T.; Joseph, J. On the structure and dynamics of stratified wakes generated by submerged propagating objects. J. Oper. Oceanogr. 2017, 10, 191–204. [Google Scholar] [CrossRef]
  118. Voropayev, S.I.; Nath, C.; Fernando, H. Thermal surface signatures of ship propeller wakes in stratified waters. Phys. Fluids 2012, 24, 116603. [Google Scholar] [CrossRef]
  119. Luo, F.; Shuai, C.; Du, Y.; Ma, J. Thermal characteristics of vehicle wake induced by the interaction between hydrodynamic wake and cold skin. Ocean Eng. 2023, 267, 113272. [Google Scholar] [CrossRef]
  120. Li, G.; Du, Y.; Yang, L. Simulation Study on Thermal Wake Characteristics of Underwater Vehicle under Rotary Motion. Appl. Sci. 2023, 13, 1531. [Google Scholar] [CrossRef]
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Figure 1. Sketch of submarine wakes in stratified fluids.
Figure 1. Sketch of submarine wakes in stratified fluids.
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Figure 2. Flow regimes past a bluff body in stratified fluids, streamwise velocity is depicted for three scenarios: (a) unstratified wake; (b) stratified wake in the vertical cut; (c) stratified wake in the horizontal cut.
Figure 2. Flow regimes past a bluff body in stratified fluids, streamwise velocity is depicted for three scenarios: (a) unstratified wake; (b) stratified wake in the vertical cut; (c) stratified wake in the horizontal cut.
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Figure 3. Comparison of the influence zone on the free surface of a submarine in homogeneous and stratified fluids.
Figure 3. Comparison of the influence zone on the free surface of a submarine in homogeneous and stratified fluids.
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MDPI and ACS Style

Cao, L.; Pan, Y.; Gao, G.; Li, L.; Wan, D. Review on the Hydro- and Thermo-Dynamic Wakes of Underwater Vehicles in Linearly Stratified Fluid. J. Mar. Sci. Eng. 2024, 12, 490. https://doi.org/10.3390/jmse12030490

AMA Style

Cao L, Pan Y, Gao G, Li L, Wan D. Review on the Hydro- and Thermo-Dynamic Wakes of Underwater Vehicles in Linearly Stratified Fluid. Journal of Marine Science and Engineering. 2024; 12(3):490. https://doi.org/10.3390/jmse12030490

Chicago/Turabian Style

Cao, Liushuai, Yanyan Pan, Gang Gao, Linjie Li, and Decheng Wan. 2024. "Review on the Hydro- and Thermo-Dynamic Wakes of Underwater Vehicles in Linearly Stratified Fluid" Journal of Marine Science and Engineering 12, no. 3: 490. https://doi.org/10.3390/jmse12030490

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