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Bubble ring

A bubble ring, also known as a toroidal bubble, is a formed underwater in which a column of air occupies the core of a rotating of , creating a stable, doughnut-shaped structure that rises due to . The rotational motion of the surrounding fluid generates lower pressure in the vortex center, drawing the air bubble into a coherent ring and counteracting disruptive forces like . This phenomenon exemplifies principles, including conservation and viscous interactions in incompressible fluids. Bubble rings are prominently observed in marine environments, where bottlenose dolphins (Tursiops truncatus) and other cetaceans such as humpback whales (Megaptera novaeangliae) intentionally create them. Bottlenose dolphins generate a vortex with their flukes or fins and then inject air from their blowholes into the low-pressure core as a form of play. These rings can reach diameters of up to 60 cm and remain stable for several seconds, propelled upward by while the vortex smooths out surface ripples to prevent premature breakup. Advanced formations, such as helical bubble chains up to 5 meters long, are produced by dolphins like those at Sea Life Park in through curved swimming paths that twist the vortex. In their dynamics, bubble rings expand radially as they ascend in a viscous fluid, with their rise velocity decreasing over time until surface tension-induced instabilities cause the structure to fragment into smaller bubbles. Factors such as initial circulation strength, , and number influence stability, with higher circulation prolonging the ring's coherence. While naturally occurring in aquatic settings, bubble rings have been replicated in laboratory simulations using numerical methods like the lattice Boltzmann approach to study vortex evolution.

Physics and Formation

Vortex Ring Fundamentals

A is a torus-shaped region of rotating fluid in which the fluid elements exhibit around an imaginary central axis that forms a closed , creating a self-contained structure of . The mathematical foundation of vortex rings was first established by in 1858, who described them as collections of vortex filaments governed by specific theorems on motion conservation in inviscid fluids. Experimental observations and further theoretical development followed in 1867 by William Thomson (later ), who analyzed their propagation and stability, laying the groundwork for understanding their dynamic behavior. The strength of a vortex ring is quantified by its circulation \Gamma, defined as the line integral of the velocity field around a closed loop enclosing the vortex core: \Gamma = \oint \mathbf{v} \cdot d\mathbf{l} This measure remains constant for a material loop in an inviscid, barotropic fluid according to Kelvin's circulation theorem, which stems from Helmholtz's original formulations. Under inviscid flow assumptions, the propagation speed v of a vortex ring arises from the self-induced velocity due to the Biot-Savart law applied to the toroidal vortex filament, approximated as v \approx \frac{\Gamma}{4\pi R} \left(1 - \frac{(a/R)^2}{2}\right) where R is the radius and a is the radius; this derives from mutual between elements of the , balancing the effects for a slender core. Vortex rings maintain through the balance between their self-induced propagation velocity, which advects the structure forward, and viscous that tends to spread the ; this is characterized by the circulation-based \mathrm{Re} = \Gamma / \nu > 1000, above which rings persist over significant distances in without rapid breakdown. Bubble rings represent a special case of vortex rings where the core contains a low-density gas, altering the overall dynamics while retaining these fundamental principles.

Buoyancy-Induced Toroidal Bubbles

Buoyancy-induced bubbles form through the injection of air into a , such as , which generates a buoyant plume that organizes into a shape via at the injection orifice. This process creates a two-phase where air concentrates along the core axis due to centrifugal forces and baroclinic torques arising from gradients between the gas and . The resulting structure ascends under buoyancy while maintaining coherent rotation, distinguishing it from spherical bubbles that rise without such organization. The buoyancy force driving this ascent and expansion is given by F_b = \frac{4}{3} \pi r^3 (\rho_\text{liquid} - \rho_\text{gas}) g, where r is the effective bubble radius, \rho_\text{liquid} and \rho_\text{gas} are the densities of the liquid and gas, and g is ; this force equals the weight of the displaced liquid minus the bubble's weight, propelling the ring upward and inducing radial growth. In the early stages of propagation, the ring radius R(t) expands approximately as R(t) \approx \sqrt{ \frac{2 g \Delta \rho \, t^2}{3 \rho_\text{liquid}} }, derived by balancing the buoyancy force against the induced drag on the vortex ring, where \Delta \rho = \rho_\text{liquid} - \rho_\text{gas}; this scaling reflects the increasing impulse of the ring as buoyancy continuously adds vertical momentum, leading to radial spreading. Experimental generation of these bubbles typically employs nozzles or piston-driven flows to produce pulsed air injections, mimicking the sudden release needed for vortex ring formation. For instance, a 4 mm diameter nozzle with air pressures of 2–6 bar and valve durations of 10–25 ms yields rings with initial diameters of 50–70 mm that propagate up to 600 mm in height, consistent with typical scales of 5–30 cm in water-based setups. The lifetime of buoyancy-induced toroidal bubbles is influenced by liquid viscosity \nu and \sigma, which promote vorticity diffusion from the bubble interface and destabilize the ring structure over time. Viscosity leads to gradual dissipation of circulation, with a characteristic time scale \tau \approx R^2 / \nu, beyond which the ring loses ; further contributes by generating instabilities at the gas-liquid , accelerating in low-viscosity fluids like .

Natural Occurrences

In Cetaceans

Bottlenose dolphins (Tursiops truncatus) are the primary cetaceans known for intentionally creating bubble rings, with observations of this behavior first documented in captive individuals at starting around 1995. These dolphins produce the rings through a rapid expulsion of air from the blowhole, forming stable structures driven by buoyancy-induced vortices. Ring diameters can reach up to 60 cm, allowing the animals to manipulate and interact with them underwater. The behavior serves multiple purposes, primarily as a form of play that provides and facilitates social interaction among group members. In the wild, similar bubble ring production has been documented in Hawaiian spinner dolphins (Stenella longirostris), where it occurs during agonistic interactions suggestive of signaling. This intentional creation highlights cetaceans' advanced and cognitive engagement with self-generated objects. Research milestones include the seminal 1996 documentation by Marten et al., which detailed the physics and play aspects through aquarium observations, followed by the 2000 analysis by the same team emphasizing cognitive implications like anticipation and quality assessment of rings.

In Other Marine Life

Squid and octopuses, members of the cephalopod class, generate toroidal vortex rings as part of their pulsed jet propulsion mechanism, providing efficient thrust for locomotion. In brief squid (Lolliguncula brevis) and longfin inshore squid (Doryteuthis pealeii), short-duration jets (mode I) produce isolated vortex rings, while longer jets (mode II) form a leading ring followed by a trailing jet lobe, enabling speeds up to 25 body lengths per second. These structures arise from the roll-up of the jet's shear layer, analogous in form to the vortex dynamics in cetacean bubble rings. Such vortex rings play a key ecological role in predator avoidance and prey capture, augmenting hydrodynamic during rapid maneuvers essential for survival in predator-rich environments. Larval octopuses similarly employ vortex rings for precise strikes on prey, highlighting their utility across life stages in these . Unlike air-filled bubble rings, these are vortices without buoyancy-driven ascent, but they contribute to sudden directional changes that can disrupt predator pursuit. Observations indicate these rings form reflexively in response to threats or hunting opportunities, contrasting with the more deliberate, playful production seen in cetaceans, and typically measure a few centimeters in for small to medium cephalopods. Documenting these vortex rings in the wild presents challenges due to the transparency of both the animals and surrounding water, often requiring specialized techniques like () for visualization. While lab studies have detailed their formation since the early 2010s, in situ measurements remain limited, particularly for deep-water species, relying on dye tracers or digital during controlled field observations. Incidental toroidal wakes may accompany ink release during escape responses, further complicating natural sightings as ink clouds obscure visibility.

Human Interactions

Creation by Divers

Scuba divers create bubble rings primarily through manual techniques that release air in a controlled manner to form a vortex, often practiced during stops for entertainment. The basic mouth-exhale method involves filling the cheeks with air from the , positioning horizontally or on the back with the head tilted slightly, and releasing a small of air—about the size of a —by forming an "O" with the lips and expelling it with a sharp "PUH" sound without tongue movement, then abruptly closing the mouth to initiate the ring formation. This technique relies on the initial air creating a vortex that causes to ascend stably. An alternative hand method uses a cupped or loose-fisted hand position: divers bring knuckles near the mouth, exhale air into the cupped hands, extend arms horizontally like a pull, and push the air-water mixture forward with a twisting motion to impart spin and shape the ring. Optimal depth for visibility and formation is 2-6 meters, where water pressure aids in compressing the air sufficiently without excessive turbulence. Advanced methods build on these fundamentals for more precise or varied rings. Divers can refine the mouth technique by using the : fill cheeks with air, extend the tongue to create , then retract it sharply to release the air , producing smoother rings with less . Hand variations include single-hand cups for smaller rings or dual-hand pulls for larger ones, often practiced in calm, deeper water around 5-10 meters to enhance stability. These approaches apply basic principles, where from the twist maintains the bubble's integrity as it rises due to differences between air and water. Bubble ring creation has gained popularity in recreational training, with informal instruction common in advanced open water and workshops at dive centers since the early , and formalized in specialty courses like the Bubble Ring Artist () program introduced in 2024. Viral videos of divers producing chains of rings, such as those shared on platforms in the , significantly boosted interest, turning the skill into a sought-after "party trick" during dives. Safety is paramount, as creating rings requires temporarily removing the , which carries a small of or delayed reinsertion; divers should in controlled environments like pools first and maintain excellent to remain horizontal without drifting. To conserve air and avoid impacting dive profiles or obligations, limit attempts to a few per stop, typically no more than 3-5 rings to preserve tank reserves for extended bottom times.

Applications in Science and Engineering

Bubble rings, also known as bubbles, serve as valuable models in research for investigating and mixing phenomena. These structures exhibit complex interactions with surrounding fluids, where the rotational motion induces enhanced mixing and , aiding studies of multiphase flows. In 2023, (CFD) simulations using demonstrated the dynamics of ring vortex formation following bubble jetting near solid boundaries, revealing how toroidal bubbles propagate and interact to generate persistent vortices that promote turbulent . These simulations, incorporating and mechanisms as foundational drivers, quantified ring interactions under varying pressure conditions, providing insights into scalable mixing processes in industrial flows. In engineering applications, bubble rings contribute to improved strategies in by facilitating better oxygen through induced circulation. Unlike conventional spherical bubbles, shapes generate self-sustaining vortex flows that enhance gas-liquid contact. This approach draws from buoyancy-driven formation to optimize diffuser designs for sustainable treatment processes. Research on vortex rings in cardiovascular blood flow has explored their role in the left ventricle, where they aid efficient and affect distribution. Studies since 2016 have used computational models of these vortices to understand patterns in healthy and diseased hearts, with vortex ring formation correlated to cardiac function. High-impact studies emphasize how vortex ring breakdown correlates with pathological conditions. Experimental investigations of bubble rings employ advanced tools like high-speed cameras and to quantify propagation velocities and structural evolution. captures instantaneous velocity fields around the ring, while high-speed imaging tracks deformation under external forces. In 2025, studies demonstrated spark discharge-driven ring bubble generation with velocities up to 12 m/s, advancing understanding of rapid bubble transport in . Emerging technologies explore vortex rings for in underwater robotics, mimicking natural dynamics for . A 2024 study demonstrated an surfing vortex rings to achieve a near five-fold reduction in during traversal of a large . These designs integrate sensing of fluid flows for efficient interaction, ensuring maneuverability in currents.

Additional Contexts

In Popular Culture

Bubble rings have been prominently featured in nature documentaries, showcasing cetacean interactions with these formations as a form of play, inspired by observed behaviors in wild dolphins. In the BBC Earth series Ocean Giants (2011), a segment depicts bottlenose dolphins encountering and manipulating artificial bubble rings produced by an underwater machine, highlighting their curiosity and social engagement with the phenomenon. Similarly, the PBS Nature episode "Ocean Giants: Bubble Play" (2012) captures dolphins playfully chasing and batting at silvery air rings, emphasizing their innate affinity for such structures. In animated media tied to underwater adventures, bubble rings appear as interactive elements in tie-in video games. For instance, in the 2003 video game adaptation of Disney/Pixar's Finding Nemo, players must swim through bubble rings to achieve bonus objectives and progress in ocean levels, portraying them as shimmering collectibles amid playful marine scenes. Video games have further integrated bubble rings as environmental features in aquatic settings; in Super Mario 64 (1996), they serve as underwater rings that Mario can swim through for points and navigation in submerged worlds. Social media platforms have amplified bubble rings through content, particularly diver-created examples that have sparked global trends. Since 2020, videos demonstrating techniques for forming underwater bubble rings during dives have garnered millions of views, with one clip of a blowing rings accumulating over 10 million engagements and inspiring user challenges to replicate the feat. These short-form videos often blend tutorial elements with mesmerizing visuals, turning the activity into a popular pastime shared by enthusiasts worldwide. In educational media aimed at children, bubble rings illustrate principles of ocean physics and animal behavior in accessible formats. publications, such as their animal fact pages and magazine features in 2022 issues, describe bottlenose dolphins creating and swimming through self-made bubble rings to engage young readers with marine ecology. Interactive apps and books from similar outlets use animated bubble ring sequences to teach concepts like and , fostering curiosity about underwater phenomena. Bubble rings symbolize the enchanting mysteries of the deep in artistic expressions, often evoking wonder and fluidity. In aquarium settings, cetacean performances of bubble ring creation have inspired exhibits and photographic art since the mid-2010s; for example, beluga whales at Shimane Aquarium in produce intricate rings that are captured in canvas prints and installations celebrating marine artistry. These representations extend to gallery works, where divers' footage of swirling rings is transformed into visual media highlighting the poetic grace of currents.

Alternative Meanings

In jewelry design, "bubble ring" denotes a style of finger characterized by bubble-like or beaded gem settings and textured patterns that evoke rounded, effervescent forms. This aesthetic gained prominence in the through brands like , which produced sterling silver and 14k gold versions featuring bubble detailing for stacking or standalone wear, often with polished finishes or embedded stones such as or . In and chemistry, ring-shaped bubble formations refer to thin films stretched between circular frames, forming minimal surfaces like catenoids that minimize area for given boundaries, distinct from dynamic fluid vortex rings. These structures, studied for their equilibrium shapes and under varying ring separations, provide insights into interfacial tension and stability, as explored in 2019 research on films supported by coaxial rings. Informally, "bubble ring" appears in and idioms, such as visualizations of economic bubbles depicted as inflating rings in financial or memes, symbolizing speculative expansions prone to collapse. It also describes party toys like handheld bubble wands shaped as rings, used to produce streams of bubbles at events. To avoid confusion, "bubble ring" should not be conflated with ring-like clusters of spherical bubbles in carbonated beverages, where CO2 at container imperfections forms rising chains or streams, rather than vortices. Historically, early 20th-century innovations in bubble toys included patented devices using ring-like elements for blowing soap bubbles, such as sheet-material constructions from the , often featured in settings for playful unrelated to underwater hydrodynamics.

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