Dynamic apnea
Dynamic apnea is a discipline within competitive freediving where athletes swim horizontally underwater in a controlled pool environment on a single breath-hold, aiming to achieve the maximum possible distance while remaining fully submerged below the surface.[1] The performance is measured from the point of airway submersion to the moment the nose or mouth breaks the surface, with strict rules prohibiting propulsion aids except in fin-assisted variants.[2] Governed primarily by organizations such as AIDA International and the Confédération Mondiale des Activités Subaquatiques (CMAS), it includes three main sub-disciplines: Dynamic Apnea with Fins (DYN), using a monofin for propulsion; Dynamic Apnea with Bi-Fins (DYNB), employing two separate fins; and Dynamic Apnea without Fins (DNF), relying exclusively on undulating body movements like dolphin kicks.[3][1] Originating as part of the broader evolution of competitive freediving from mid-20th-century spearfishing contests in Italy and France, dynamic apnea formalized as a pool-based event in the early 1980s, emphasizing horizontal distance over depth.[4] This discipline quickly became a cornerstone of indoor competitions, allowing for precise measurement and safety protocols in controlled settings, distinct from open-water depth disciplines.[5] By the 1990s, international federations like AIDA and CMAS established standardized rules, including requirements for pool lengths of at least 25 meters, mandatory safety divers, and surface protocols to validate performances.[2] Key to success in dynamic apnea are techniques that optimize oxygen efficiency, such as the dolphin kick—a fluid, wave-like motion of the body—and streamlined positioning to minimize drag.[6] Training regimens typically incorporate interval swims, CO2 tolerance drills, and dry-land simulations to enhance endurance, with athletes often preparing through progressive breath-hold sessions in pools.[7] Safety is paramount, with protocols requiring at least two safety freedivers per lane and immediate medical support, reflecting the physiological stresses like bradycardia and hypoxia that occur during prolonged submersion.[2] As of November 2025, world records in dynamic apnea highlight remarkable human limits, with CMAS recognizing Mateusz Malina's 326.5 meters in DYN (senior men) set on May 24, 2025, Julia Kozerska's 222.5 meters in DNF (absolute women) set on August 10, 2025, at the World Games in Chengdu, and Zsófia Törőcsik's 300 meters in DYN (women's absolute) set on August 11, 2025, also at the World Games.[8][9][10] In AIDA competitions, notable performances include Zsófia Törőcsik's 259 meters in DYNB (women) on June 28, 2025, and Guillaume Bourdila's 298 meters in DYNB (men) on June 28, 2025.[3][11] These achievements underscore dynamic apnea's role in advancing freediving science, technique, and global participation.[12]Overview
Definition and Principles
Dynamic apnea is a competitive discipline within freediving where athletes swim horizontally underwater on a single breath-hold, aiming to cover the maximum possible distance while keeping the airway submerged.[13][14] This event emphasizes controlled, breath-held propulsion in a pool environment, with the performance measured by the total distance achieved.[13] The fundamental principles of dynamic apnea center on efficient horizontal propulsion, breath-holding endurance, and techniques that promote relaxation to extend the distance covered. Athletes focus on streamlined body positioning and minimal energy expenditure to conserve oxygen, allowing for longer swims without surfacing.[6][15] The mammalian dive reflex plays a supportive role by automatically redirecting blood flow to vital organs, aiding oxygen preservation during the breath-hold.[16] Pool competitions require a minimum length of 25 meters to accommodate the horizontal swims, with athletes starting in-water, touching walls at turns, and completing the dive upon surfacing for recovery.[13] The primary goal is to maximize distance on one breath, with strict rules prohibiting surface swimming or external propulsion aids beyond the body and approved equipment.[13] Dynamic apnea differs from static apnea, which prioritizes time-based breath-holding without movement, and from depth disciplines that involve vertical descent to greater underwater depths.[13] This horizontal, distance-focused approach tests both cardiovascular efficiency and swimming technique under hypoxic conditions.[14]Historical Development
Early 20th-century innovations in freediving equipment laid the groundwork for modern disciplines, evolving from ancient breath-hold techniques into structured underwater activities. In France during the 1930s, pioneers like Louis de Corlieu, who patented the first modern swim fins in 1933, and Jacques O'Marchal, who developed a nose-enclosing mask in 1927 (later refined by Maxime Forjot in 1938), enabled longer horizontal swims without breathing apparatus.[17][18] These French advancements shifted breath-holding from survival and spearfishing to recreational and sporting pursuits, with early informal competitions emerging in European aquatic clubs by the mid-20th century.[19] During the 1950s and 1960s, the Confédération Mondiale des Activités Subaquatiques (CMAS), established in 1959 under the leadership of figures like Jacques-Yves Cousteau, played a pivotal role in formalizing apnea as a competitive discipline by homologating early freediving records and organizing international events.[20][19] CMAS's efforts standardized safety protocols and promoted pool-based apnea challenges, including dynamic variants, which gained traction as safer alternatives to depth diving amid growing interest in underwater sports across Europe.[18] By the late 1960s, CMAS had overseen numerous achievements in breath-hold swimming, though it later ceased ratifying extreme depth records in the 1970s due to safety concerns.[17] The transition from recreational breath-holding to a fully competitive pool discipline accelerated in the 1980s and 1990s, as athletes refined techniques for sustained underwater propulsion in controlled 25- or 50-meter pools, emphasizing efficiency over depth, with dynamic apnea formalizing as a distinct event in France during the early 1980s.[19] This period saw dynamic apnea's popularity surge, particularly in Europe, with informal meets evolving into organized national and international contests that highlighted distance as the primary metric.[18] A major milestone came in 1992 with the founding of the International Association for the Development of Apnea (AIDA) in Nice, France, which established unified rules for apnea competitions, including dynamic disciplines, and hosted the inaugural AIDA World Championships in 1996, focusing initially on static and constant weight but quickly incorporating dynamic events.[21][22] Contemporary dynamic apnea techniques have drawn significant influence from Olympic swimming, incorporating streamlined body positioning, undulating dolphin kicks, and hydrodynamic fin strokes to optimize oxygen conservation and distance coverage during breath-hold swims.[23][24] This cross-pollination, evident in training regimens that blend apnea drills with surface swimming efficiency, has enhanced performance in pool-based competitions since the late 20th century.[25]Disciplines
Dynamic No Fins (DNF)
Dynamic No Fins (DNF) is a competitive freediving discipline in which athletes swim horizontally underwater in a pool, covering the maximum possible distance on a single breath-hold without using fins or any other propulsion aids. The freediver must remain completely submerged throughout the attempt, starting with the airway below the water surface within 1.5 meters of the starting wall, and propulsion is achieved solely through arm movements and body undulation.[2] The primary technique involves a modified underwater breaststroke, where the arms perform a pulling motion—starting from a streamlined position with hands extended forward, pulling down to shoulder level with elbows at 90 degrees, and finishing at the hips to minimize drag—synchronized with leg undulations or kicks for forward momentum. Dolphin kicks, involving a wave-like motion from the core through the hips and legs with feet together and toes pointed, or sculling motions with the hands, are often employed to enhance efficiency and maintain a streamlined body position, emphasizing neutral buoyancy to avoid sinking or rising, which would increase energy costs. Core strength is crucial for sustaining this undulating propulsion and hydrodynamic posture over extended distances.[26][27] World-class performances in DNF typically range from 200 to 250 meters, as exemplified by the men's AIDA world record of 250 meters set by Mateusz Malina in 2022 and the women's CMAS world record of 222.5 meters achieved by Julia Kozerska in August 2025.[28][9][29] This discipline presents unique challenges due to the absence of fin leverage, resulting in significantly higher energy expenditure compared to fin-assisted variants, as athletes rely entirely on their own muscle power for propulsion, necessitating exceptional core stability and efficient stroke timing to manage oxygen consumption and delay lactic acid buildup.[27]Dynamic with Fins (DYN and DYNB)
Dynamic apnea with fins encompasses two primary variations: Dynamic with monofin (DYN), where athletes employ a single monofin to propel themselves horizontally underwater on a single breath-hold, and Dynamic with bifins (DYNB), which utilizes two separate fins for similar horizontal displacement. In DYN, the monofin facilitates undulating kicks akin to a dolphin's tail motion, enabling streamlined propulsion that minimizes energy expenditure while maximizing distance. Elite performers in DYN have achieved distances exceeding 300 meters, as evidenced by the men's AIDA world record of 307 meters set by Ming Jin in 2024 and the men's CMAS world record of 326.5 meters set by Mateusz Malina on May 24, 2025.[30][8][31] In contrast, DYNB involves flutter kicks with bifins, prohibiting dolphin-style undulations to emphasize distinct biomechanical demands, which typically result in slightly shorter elite distances compared to DYN. The men's AIDA world record in DYNB stands at 298 meters by Guillaume Bourdila achieved on June 28, 2025, while the CMAS record is 300 meters by Mateusz Malina set on May 24, 2025, highlighting the nuanced performance differences arising from fin configuration and kick mechanics.[32][21][33][34] Key techniques in both disciplines emphasize synchronization of fin movements with glide phases to optimize momentum conservation, often calibrated during pre-dive breathing patterns to ensure rhythmic initiation post-immersion. This synchronization allows divers to alternate between efficient propulsion bursts and passive gliding, reducing overall metabolic demand.[35][36] The primary advantages of fins in these disciplines lie in their ability to reduce hydrodynamic drag and enhance propulsion efficiency, permitting greater distances than no-fins variants by leveraging amplified thrust from larger surface areas without proportionally increasing energy costs. Studies on underwater energetics confirm that fin-assisted swimming lowers the oxygen cost per meter compared to body-only propulsion, enabling reliance on both aerobic and anaerobic stores for extended efforts.[37][38]Physiology
Physiological Adaptations
Dynamic apnea elicits several key physiological adaptations that optimize oxygen conservation and extend underwater performance. Central to these is the mammalian dive reflex, an evolutionary response triggered by facial immersion in water and breath-holding, which prioritizes oxygen delivery to vital organs.[16] This reflex integrates cardiovascular and respiratory adjustments to minimize metabolic demands during apnea.[39] A primary component of the mammalian dive reflex is bradycardia, where heart rate decreases substantially—often to 30-50% of resting levels (e.g., below 50 beats per minute)—through enhanced parasympathetic vagal tone.[16] This reduction in cardiac output lowers overall oxygen consumption, particularly in non-essential tissues.[39] Concurrently, peripheral vasoconstriction occurs via sympathetic activation, redirecting blood flow away from the limbs, skin, and splanchnic regions to preserve oxygenation for the brain and heart.[16] These changes, mediated by trigeminal nerve stimulation and chemoreceptor activation under low oxygen, can increase arterial blood pressure while conserving limited oxygen stores.[39] Another adaptation involves splenic contraction, which rapidly ejects stored, oxygenated red blood cells into circulation during apnea.[40] This response, more pronounced in apnea than in rebreathing scenarios, elevates hemoglobin concentration by approximately 2-3%, enhancing oxygen-carrying capacity without altering total blood volume.[40] In breath-hold divers, spleen volume can decrease by up to 20%, providing a quick boost to systemic oxygenation critical for prolonged submersion.[40] Repeated exposure to breath-holding fosters hypoxic adaptation, increasing tolerance to low oxygen levels through enhanced oxygen utilization and reduced metabolic rate.[41] Elite breath-hold divers exhibit higher red blood cell counts and hemoglobin levels, along with elevated myoglobin in skeletal muscles, which improves oxygen storage and delivery under hypoxic stress.[42] These changes allow for sustained performance by mitigating the effects of arterial oxygen desaturation.[41] Hypercapnia tolerance also develops, enabling better management of carbon dioxide accumulation during apnea.[42] This adaptation blunts the ventilatory drive in response to elevated CO2, delaying the urge to breathe and extending breath-hold duration.[41] In chronic practitioners, reduced chemosensitivity to hypercapnia supports cardiovascular stability, complementing the dive reflex to maintain performance amid rising blood CO2 levels.[42]Oxygen and Limits
In dynamic apnea, the dive response helps reduce overall metabolic demands, with resting oxygen consumption around 0.25 liters per minute due to responses like bradycardia.[43] However, swimming effort elevates oxygen use, typically 2-4 times the basal rate depending on speed. Trained athletes typically have total usable oxygen stores estimated at 2-3 liters, distributed across the lungs (about 1-1.5 liters), blood (around 1 liter bound to hemoglobin), and minimal tissue reserves.[44] Elite divers may achieve higher stores through increased lung volumes up to 8-10 liters of air via lung packing (glossopharyngeal insufflation), a technique that adds 20-50% to vital capacity by swallowing air into the lungs.[45][46] These stores are rapidly depleted during exertion. The primary physiological limit in dynamic apnea is the hypoxic blackout threshold, where cerebral oxygen desaturation leads to loss of consciousness, typically occurring after 3-5 minutes in trained individuals depending on effort intensity.[47] This threshold is influenced by swimming speed and distance, as higher velocities increase oxygen uptake by 2-4 times the basal rate, shortening safe apnea duration compared to static holds.[48] Key risks associated with oxygen limits include shallow water blackout, a form of hypoxic blackout that often occurs near the surface during ascent or recovery due to depleted oxygen reserves and rapid decompression effects on partial pressures.[49] A critical factor affecting these limits is the avoidance of hyperventilation, which artificially lowers carbon dioxide levels and delays the urge to breathe, creating a false sense of oxygen sufficiency and heightening blackout risk by allowing prolonged hypoxia.[50]Equipment
Fins and Propulsion Aids
In dynamic apnea with fins (DYN), monofins serve as the primary propulsion aid, featuring either full-foot pockets that enclose both feet or open-heel designs that accommodate foot straps for adjustability. These monofins typically have blade lengths ranging from 70 to 90 cm, with widths around 60 to 70 cm, enabling a streamlined dolphin kick that maximizes horizontal distance in pool environments. Constructed from carbon fiber composites, the blades provide high stiffness to optimize the undulating motion, reducing energy loss and enhancing forward thrust during breath-hold swims.[51] For dynamic apnea with bifins (DYNB), athletes employ pairs of individual fins with shorter blades, generally 60 to 80 cm in length and narrower profiles (about 20 to 22 cm wide), which support a flutter kick technique for controlled propulsion. These bifins often incorporate flexible carbon or fiberglass blades to allow smoother oscillation at lower intensities, prioritizing endurance over explosive power in competitive settings. The design facilitates easier turns at pool walls, a critical aspect of the discipline.[52][53] Nose clips represent a simple yet essential propulsion aid in both DYN and DYNB, preventing water ingress through the nostrils during exhalations or turns, thereby maintaining focus on finning efficiency without the need for manual clearing. Typically made from soft silicone or rubber for comfort, these clips minimize drag and support consistent breathing patterns post-dive.[54] Selection of fins emphasizes buoyancy characteristics—often slightly positive at the surface for recovery ease—and a balanced stiffness ratio tailored to the athlete's strength and body weight to avoid fatigue. Softer stiffness suits lighter divers or longer sessions, while stiffer options benefit stronger kickers seeking maximal glide.[55][56]Wetsuits and Accessories
In dynamic apnea, wetsuits are essential for providing thermal insulation, buoyancy, and hydrodynamic benefits in controlled pool environments. Typically constructed from 1-3 mm thick neoprene, these suits enhance streamlining by conforming closely to the body, minimizing water resistance during horizontal swims.[57] For instance, models like the Cetma Competition Dynamic-Tech use 2 mm power stretch neoprene with a smooth exterior to optimize glide.[58] The thin profile of these wetsuits contributes to drag reduction, with studies on similar hydrodynamic suits showing approximately a 14% decrease in resistance at typical swimming speeds of 1.25 m/s.[59] This reduction supports longer distances in disciplines like DYN and DNF by allowing efficient propulsion without excessive effort. While AIDA and CMAS rules impose no strict thickness limits for pool events to encourage fair competition, practitioners limit suits to 1-3 mm to prevent undue buoyancy advantages that could alter neutral positioning.[13][60] Accessories complement wetsuits by addressing specific comfort and balance needs. Ear plugs, such as silicone models designed for apnea, aid in pressure equalization and protect against minor ear canal discomfort from repeated submersion, even in shallow pools.[61] Weight belts, often made of rubber or silicone with quick-release buckles, help achieve neutral buoyancy; AIDA permits up to 3 kg worn under the suit for pool disciplines to counteract any positive lift from the wetsuit.[62] These belts ensure horizontal body alignment, enhancing efficiency without hindering movement. Proper maintenance extends the lifespan of wetsuits and accessories. After use, rinse items in fresh water to remove chlorine, then air-dry them in a shaded area away from direct sunlight to prevent neoprene degradation.[63] For storage, hang wetsuits on wide hangers in a cool, dry place to avoid creases and material breakdown; ear plugs and belts should be stored separately in ventilated pouches.[64] Neglecting these steps can lead to cracking or loss of elasticity over time.Rules and Judging
Competition Standards
Dynamic apnea competitions are primarily governed by two international organizations: the Association Internationale pour le Développement de l'Apnée (AIDA) and the Confédération Mondiale des Activités Subaquatiques (CMAS). AIDA, headquartered in Switzerland, establishes rules emphasizing safety, fairness, and athlete autonomy, with competitions held in pools of at least 25 meters in length and a minimum depth of 1.2 meters for world championships; water temperature is typically maintained between 28–30°C to support athlete comfort and performance.[13] CMAS, based in Italy, oversees similar events with stricter pool specifications for international meets, requiring 50-meter lengths and a minimum depth of 1.20 meters, though temperature guidelines are not explicitly mandated in core rules; world and continental records are valid only in 50-meter pools.[65] Dive protocols under AIDA prohibit the use of compressed gases exceeding 21% oxygen concentration for at least 60 minutes prior to an attempt, effectively discouraging excessive hyperventilation while allowing natural breathing preparation; recovery time between attempts is managed by the competition schedule.[13] In CMAS competitions, oxygen use is forbidden for 1 hour before any attempt, with surface intervals set at a minimum of 8 minutes between starts to mitigate cumulative physiological stress; preparation includes a 3-minute window before the official top time, during which athletes must commence the dive or face disqualification.[65] Competitions feature individual events across disciplines like dynamic with bifins (DYNB), monofin (DYN), and no fins (DNF), alongside team formats in world championships where national squads compete collectively; divisions are separated by gender (men's and women's categories) and age groups, including juniors (15–17 years under CMAS, or 16+ with consent under AIDA), seniors (18–49), and masters (50+ with subcategories).[13][65] Disqualification occurs for violations such as early surfacing, where the athlete's airway emerges from the water before completing the announced distance, or failure to provide the required OK signal; under AIDA, this signal must include one visible hand gesture and one verbal declaration ("I'm OK") within 15 seconds of surfacing, performed in sequence without assistance.[13] CMAS mandates an OK sign within 20 seconds post-surfacing, followed by maintaining the head above water, with any deviation like straying from the lane or receiving aid resulting in immediate disqualification.[65]Performance Measurement and Safety Protocols
In dynamic apnea competitions governed by organizations such as AIDA International, performance is measured by the horizontal distance an athlete covers underwater on a single breath, typically in a 25-meter or 50-meter pool. The distance is recorded from the starting wall to the point where the athlete's airways emerge at the surface upon completion, rounded down to the nearest meter for scoring purposes, with each meter equivalent to 0.5 points as of 2025. Judges at the pool's end wall visually confirm the athlete's touch of the wall at turns and the final emergence, ensuring no propulsion aids or surface swimming occur during the attempt.[13] To ensure accuracy, especially in high-stakes events like world championships, video recording of each attempt is mandatory, allowing for post-dive review by the judging panel if discrepancies arise. The panel typically consists of at least two certified AIDA judges, who issue a white card for a valid performance meeting all criteria, such as proper wall tags without assistance. In CMAS-sanctioned events, measurement is rounded down to the nearest half meter using tape or electronic systems, with a chief judge and video judges validating within three minutes of the attempt.[13][65] Safety protocols are integrated into every dynamic apnea attempt to mitigate risks like blackout. One or more spotters—certified safety freedivers—are positioned every 25 meters along the performance zone to monitor the athlete continuously, with an additional spotter required for pools longer than 25 meters. Recovery teams, including counterweighted lines or scuba support, stand ready for immediate intervention, particularly in the final 15 meters where blackout risk peaks. Upon detecting a blackout, judges disqualify the athlete from the discipline, but the recovery procedure involves prompt surfacing assistance without further penalties, followed by a mandatory medical evaluation to assess severity. Mild blackouts prohibit diving for the remainder of the competition day, while moderate or severe cases require extended rest and physician clearance. Post-dive medical checks are compulsory after any suspected incident, ensuring athlete welfare before subsequent attempts.[13][65]Training
Dry Training Techniques
Dry training techniques form the foundation for building breath-hold capacity and physical efficiency in dynamic apnea, allowing athletes to develop tolerance to hypoxia and hypercapnia on land before progressing to water-based sessions. These methods emphasize controlled breath-holds and targeted exercises to enhance CO2 and O2 management, while strengthening key muscle groups for streamlined propulsion. Performed safely with a buddy to monitor for loss of motor control, dry training progresses gradually to avoid overexertion and injury.[66] Apnea tables are structured drills designed to improve tolerance to elevated carbon dioxide (CO2) and reduced oxygen (O2) levels through repetitive breath-holds with varying recovery intervals. CO2 tables focus on building comfort with the urge to breathe by using fixed hold times—typically 50% or less of one's personal best—with progressively shorter recoveries, such as holding for 2 minutes followed by rests decreasing from 2:00 to 0:15 minutes across 8-10 repetitions. This elevates CO2 buildup gradually, training the body to relax through contractions without pushing to blackout thresholds. O2 tables, conversely, emphasize endurance under low oxygen by increasing hold durations—starting at 1:30 minutes and progressing to 3:15 minutes—with fixed 2:00-minute recoveries, adapting the athlete to sustained hypoxia while keeping holds at 80% or less of maximum capacity. These tables directly support dynamic apnea by enhancing the ability to maintain breath-holds during exertion, contributing to longer underwater distances.[66][67][68] Apnea walks simulate the metabolic demands of dynamic movement under breath-hold by combining walking with timed apneas, fostering CO2 tolerance and awareness of hypoxic sensations on solid ground. To perform a standard apnea walk, an athlete begins with a 2-3 minute relaxed breathe-up while seated, takes a peak inhale, holds for 10-30 seconds to lower heart rate, then stands and walks steadily on level terrain until the first strong contraction or urge to breathe, marking the distance covered. Multiple walks—typically 3-6 per session with 2-minute recoveries—can be structured as a CO2 table by reducing recovery times or increasing distances, promoting lactic acid buildup similar to swimming efforts. This technique heightens the dive reflex and builds confidence in managing contractions, which translates to more efficient propulsion in dynamic disciplines.[69][70] Strength exercises in dry training target core and upper body muscles to optimize propulsion efficiency, reducing drag and energy expenditure during horizontal swims. Core workouts, such as planks held for 30-60 seconds (progressing to side planks or leg raises), build stability for maintaining a hydrodynamic body position. Upper body exercises like push-ups, pull-ups, and rows—performed in 3 sets of 10-15 repetitions—strengthen the shoulders, back, and arms for undulating or sculling motions, ensuring balanced power output without excess fatigue. These land-based routines enhance overall physiological adaptations, such as improved oxygen utilization, by supporting efficient muscle recruitment.[71][72] Dry training sessions are typically conducted 3-5 times per week, with each lasting 45-60 minutes to allow recovery and prevent burnout. Progression begins with beginner holds of 1-2 minutes in tables and walks, advancing over 4-6 weeks to 4+ minutes by increasing durations or repetitions in 15-30 second increments, always testing personal bests sparingly (once weekly) to track gains safely. Alternating CO2 and O2 focuses—such as CO2 tables every other day initially, then incorporating O2—ensures balanced development, with rest days to mitigate fatigue.[73][68]In-Water and Mental Training
In-water training for dynamic apnea focuses on building endurance and efficiency through structured pool sessions that incorporate breath-hold swims. Practitioners typically begin with interval drills, such as repeating 25-meter swims on short recoveries, gradually increasing repetitions and distances to simulate competition demands while maintaining controlled breathing urges.[74] For instance, sets of 8 x 25 meters with 1-2 minute recoveries can progress to doubles—swimming 25 meters out, taking 1-3 breaths, and returning—aiming for contraction-free efforts to extend total distance toward 100 meters.[74] These drills enhance tolerance to hypoxia by combining static apnea holds (e.g., 1-minute breath-holds) with subsequent dynamic swims at a pace of 43 seconds per 50 meters, building from 80 meters to full target distances over multiple sessions.[75] Technique refinement during these sessions emphasizes streamlining, where divers maintain a hydrodynamic body position with minimal drag, often practicing slow-paced swims (50-60 seconds per 50 meters) to maximize glide and reduce stroke cycles.[75] Kick efficiency is honed through focused propulsion drills, prioritizing steady, powerful undulations over erratic movements to conserve energy and oxygen.[74] Relaxation under effort is integrated by alternating high-intensity sets with lighter technique-focused swims, promoting mental ease and low heart rate even during prolonged breath-holds.[75] Mental training complements in-water practice by cultivating psychological resilience essential for managing the discomfort of extended apneas. Visualization techniques involve mentally rehearsing dives, engaging senses to simulate streamlining, efficient kicks, and calm ascents, which builds confidence and reduces pre-dive anxiety.[76] Meditation practices, such as mindfulness sessions during breath-ups, help control panic by fostering present-moment awareness and emotional regulation, often practiced several times weekly alongside physical drills.[77] Diaphragmatic breathing, emphasizing deep abdominal inhalations, is employed pre-dive to promote relaxation, optimize oxygen uptake, and transition from conscious to effortless respiration underwater.[78] Safety integration is paramount in in-water sessions, with the buddy system requiring a trained partner to monitor for blackout precursors like visual greying, motor control loss, or erratic bubbles.[79] Drills incorporate paired protocols where one diver swims while the other observes and assists on surfacing, practicing rescue maneuvers such as supporting the head and providing air if loss of consciousness occurs.[80] This approach ensures early recognition of hypoxia signs, preventing incidents during interval builds or max efforts.[81]Records and Achievements
World Records
World records in dynamic apnea are ratified by organizations such as AIDA International and CMAS, with AIDA maintaining an official database of performances verified through video evidence, doping tests, and competition protocols. As of November 2025, the current AIDA world records reflect peak achievements in the primary disciplines: Dynamic with Fins (DYN), Dynamic without Fins (DNF), and Dynamic with Bifins (DYNB).| Discipline | Gender | Athlete | Distance | Date | Location/Event |
|---|---|---|---|---|---|
| DYN | Men | Ming (William Joy) Jin (CHN) | 307 m | 25 August 2024 | AIDA Asian Pool Championship, Goyang, South Korea[82] |
| DYN | Women | Zsófia Törőcsik (HUN) | 280 m | 2 July 2025 | 34th AIDA Freediving World Championship, Wakayama, Japan[83] |
| DNF | Men | Mateusz Malina (POL) | 250 m | 17 December 2022 | AIDA Polish Freediving Pool Competition, Łódź, Poland[84] |
| DNF | Women | Julia Kozerska (POL) | 213 m | 13 June 2023 | AIDA International Competition, Kalamata, Greece[3] |
| DYNB | Men | Guillaume Bourdila (FRA) | 298 m | 28 June 2025 | 34th AIDA Freediving World Championship, Wakayama, Japan[11] |
| DYNB | Women | Zsófia Törőcsik (HUN) | 259 m | 28 June 2025 | 34th AIDA Freediving World Championship, Wakayama, Japan[83] |
| Discipline | Gender | Athlete | Distance | Date | Location/Event |
|---|---|---|---|---|---|
| DYN | Men | Mateusz Malina (POL) | 326.5 m | 24 May 2025 | CMAS World Championship Freediving Indoor, Athens, Greece[8] |
| DYN | Women | Julia Kozerska (POL) | 284 m | 24 May 2025 | CMAS World Championship Freediving Indoor, Athens, Greece[85] |
| DNF | Men | Mateusz Malina (POL) | 239 m | 20 May 2025 | CMAS World Championship Freediving Indoor, Athens, Greece[12] |
| DNF | Women | Julia Kozerska (POL) | 222.5 m | 10 August 2025 | World Games 2025, Chengdu, China[29] |
| DYNB | Men | Goran Čolak (HRV) | 292.15 m | 2023 | CMAS World Championship, Kuwait[86] |
| DYNB | Women | Mirela Kardašević (HRV) | 259 m | 24 May 2025 | CMAS World Championship Freediving Indoor, Athens, Greece[86] |