Static apnea
Static apnea (STA), a core discipline in competitive freediving, involves an athlete holding their breath underwater for the longest possible duration while remaining completely motionless, with the face immersed and the body floating face down, typically in a controlled pool environment.[1] This static form of apnea emphasizes mental discipline, physical relaxation, and physiological efficiency to minimize oxygen consumption and delay the urge to breathe, distinguishing it from dynamic or depth-based freediving variants that involve movement or descent.[2] Governed primarily by organizations such as AIDA International and CMAS, static apnea competitions measure performance solely by time, requiring total body stillness to avoid disqualification, and it serves as a foundational training tool for building carbon dioxide tolerance and hypoxia resistance in freedivers.[1] Physiologically, elite performers leverage adaptations like the mammalian diving reflex, which triggers bradycardia and peripheral vasoconstriction to conserve oxygen, alongside training-induced increases in lung volume and hemoglobin levels via splenic contraction.[3] As of 2025, the AIDA men's world record stands at 11 minutes 35 seconds, set by Stéphane Mifsud of France in Hyères on June 8, 2009, while the women's record is 9 minutes 22 seconds, achieved by Heike Schwerdtner of Germany in Stockholm on May 4, 2025.[4][5] These feats highlight the sport's extreme demands on human limits, with ongoing research underscoring benefits like improved cardiovascular efficiency but also risks of shallow-water blackout if not practiced safely.[6]Definition and Fundamentals
Overview of Static Apnea
Static apnea, also known as STA, is a breath-holding discipline in freediving where an athlete remains motionless underwater or at the surface with airways submerged, aiming to maximize the duration of voluntary apnea until resurfacing or involuntary loss of consciousness.[7] This practice emphasizes mental focus, relaxation, and physiological tolerance without any requirement for horizontal or vertical movement, distinguishing it as a pure test of static breath-hold capacity.[8] The standard rules for static apnea are governed by international bodies such as AIDA International and CMAS, typically conducted in a controlled pool environment with a minimum depth of 60 cm for international AIDA competitions and 110 cm for AIDA World Championships (as of 2025), or 1.4 m for CMAS championships.[7][9][10] The performance begins with the official top time when the athlete's airway (nose and mouth) is fully submerged, often starting face-down and horizontal on the water surface, and ends when the airway resurfaces, with the athlete completing a surface protocol including an okay signal within 15 seconds.[7] No propulsion or swimming is permitted during the hold; any significant movement results in disqualification, and the official time is the average of two judges' measurements, rounded down to the nearest second.[11][8] Equipment in static apnea is minimal to maintain fairness and focus on natural ability, consisting primarily of a nose clip to prevent water ingress, standard swimwear, and optional items like a mask or snorkel that must be removed upon surfacing. Weights, limited to 3 kg and worn under the suit, may be used for neutral positioning; fins and buoyancy aids are not permitted.[7][11][9] No breathing apparatus or internal monitoring devices, such as heart rate trackers, are allowed.[11][9] As a core component of competitive freediving, static apnea events are organized under AIDA or CMAS regulations, where athletes declare an intended performance time in advance and compete for rankings, national titles, or world records based on verified holds exceeding prior benchmarks by at least one second.[12][8] These competitions highlight static apnea's role within the broader spectrum of apnea disciplines, promoting safety through judge oversight and medical supervision.[7]Distinctions from Dynamic and Other Apnea Disciplines
Static apnea distinguishes itself from dynamic apnea primarily through its emphasis on immobility and time duration rather than horizontal propulsion and distance covered. In static apnea, the freediver remains stationary with their face submerged in water, typically floating face-down in a pool, aiming to maximize breath-hold time without any voluntary movement.[1] In contrast, dynamic apnea requires continuous swimming underwater on a single breath-hold, either without fins (DNF) or with fins (DYN), where performance is judged by the farthest distance traveled, often exceeding 200 meters in competitive settings.[13] This stationary focus in static apnea isolates pure breath-holding capacity, minimizing energy expenditure from locomotion that is central to dynamic disciplines.[2] Beyond dynamic apnea, static apnea contrasts with depth-oriented variants that prioritize vertical descent and ascent under breath-hold. No-limits apnea involves descending to extreme depths using a weighted sled along a guide line, then ascending via an inflated buoyancy bag connected to a scuba cylinder, with success measured by maximum depth achieved, such as the men's record of 214 meters set in 2007.[14] Constant weight apnea, a more common depth discipline, requires the freediver to swim down and up to a targeted depth using only their own power and fins (CWT) or monofin, without weight changes or mechanical aids, emphasizing efficiency in vertical movement over endurance alone.[13] Unlike these, static apnea eschews depth and propulsion entirely, concentrating solely on physiological limits of oxygen conservation and CO2 tolerance in a controlled, horizontal environment.[1] A hybrid form, static apnea with pure oxygen pre-breathing, extends hold times dramatically but is restricted to non-competitive record attempts, such as Guinness World Records, where divers inhale 100% oxygen for several minutes prior to submersion to preload tissues and delay hypoxia. This variant has yielded holds over 24 minutes, far surpassing competitive limits, but is prohibited in organized freediving events due to safety concerns and to maintain fairness in testing natural apnea ability.[15] In competitive contexts governed by organizations like AIDA International, static apnea (STA) is conducted as a pure discipline without aids, where any intentional movement disqualifies the attempt, ensuring the metric reflects unadulterated breath-hold endurance.[16] Rules mandate the freediver to submerge fully, remain prone and still, and surface only upon blackout or voluntary end, with judges monitoring for compliance to isolate the physiological challenge.[11]Physiological Aspects
Mechanisms of Breath-Holding
Static apnea involves the voluntary interruption of the respiratory cycle, where inhalation ceases after a deep breath, preventing further gas exchange in the lungs. This leads to a progressive accumulation of carbon dioxide (CO2) in the blood, known as hypercapnia, and a gradual depletion of oxygen (O2), resulting in hypoxia. The rate of PaCO2 increase during apnea is approximately 0.07 mmHg per second, contributing to the primary drive to resume breathing as levels approach 50-60 mmHg, at which point the urge to breathe becomes intense.[17][18] Similarly, arterial partial pressure of oxygen (PaO2) declines, often dropping below 40 mmHg in prolonged holds, which heightens the risk of loss of consciousness due to cerebral hypoxia.[17] Key physiological responses facilitate tolerance to these changes, beginning with diaphragm relaxation that halts respiratory muscle activity to conserve energy. In aquatic environments, facial immersion in water triggers the mammalian dive reflex, an adaptive mechanism conserved across mammals. This reflex induces bradycardia, reducing heart rate to as low as 20-30 beats per minute via parasympathetic activation of the vagus nerve, and peripheral vasoconstriction, which redirects blood flow to vital organs like the brain and heart by increasing vascular resistance through sympathetic stimulation. These components—apnea, bradycardia, and vasoconstriction—are mediated by the trigeminal nerve sensing cold water on the face, enhancing oxygen efficiency during breath-holding.[18][17] Neural control of breath-holding is governed by chemoreceptors that monitor blood gas levels and ultimately override voluntary inhibition. Central chemoreceptors in the ventral medulla detect rising PaCO2 through associated decreases in cerebrospinal fluid pH, while peripheral chemoreceptors in the carotid and aortic bodies sense falling PaO2 below approximately 60 mmHg and contribute to hypercapnia detection. As hypercapnia and hypoxia intensify, these sensors stimulate the medullary respiratory centers, including the dorsal and ventral respiratory groups, generating involuntary diaphragmatic contractions that compel resumption of breathing despite conscious effort to maintain apnea.[19] This override mechanism ensures survival by prioritizing gas homeostasis over extended voluntary holds.[19]Factors Influencing Hold Duration
Several individual physiological variables significantly influence the duration of breath-holds in static apnea. Lung capacity, particularly vital capacity, plays a key role, with elite freedivers often exhibiting forced vital capacity values exceeding those of the general population by up to 1.8 liters due to adaptations like glossopharyngeal insufflation, allowing for greater oxygen storage in the lungs. In exceptional cases, lung packing techniques can push effective lung volumes toward 10 liters in trained athletes, enhancing initial oxygen reserves. Body composition also affects performance, as leaner individuals with lower body fat percentages tend to have reduced metabolic rates, conserving oxygen by minimizing overall energy expenditure during apnea. Genetic factors, such as larger spleen size observed in populations like the Bajau sea nomads, further aid oxygen storage by enabling greater contraction and release of red blood cells into circulation upon immersion, increasing hemoglobin availability. Environmental conditions can modulate breath-hold times through their impact on physiological responses. Colder water temperatures intensify the mammalian dive reflex, eliciting stronger bradycardia and peripheral vasoconstriction, which collectively reduce oxygen consumption and extend apnea duration compared to warmer conditions. In static apnea, typically performed in shallow pools of 3-4 meters depth, hydrostatic pressure has minimal influence on gas exchange or lung compression, distinguishing it from deeper disciplines where pressure effects are pronounced. Pre-dive air quality, including higher oxygen partial pressures or cleaner environments, may subtly optimize initial gas stores, though its effects are secondary to other factors. Psychological elements are crucial for maximizing hold duration by mitigating unnecessary oxygen use. Mental relaxation techniques, such as visualization, lower stress levels and associated sympathetic activation, thereby decreasing heart rate and overall metabolic demand during the breath-hold. This psychological control helps override the urge to breathe driven by rising carbon dioxide, allowing divers to tolerate higher levels of hypoxia and hypercapnia. Performance enhancers like pre-dive hyperventilation can prolong apnea by lowering carbon dioxide levels, delaying the respiratory drive, but this practice increases the risk of shallow-water blackout due to unrecognized severe hypoxia. Pre-breathing pure oxygen, often for 15-30 minutes, dramatically extends hold times—up to 29 minutes 3 seconds in records, as achieved by Vitomir Maričić in the 2025 Guinness World Record—by saturating tissues and eliminating the hypoxic signal, though it is restricted in competitive static apnea to maintain fairness and safety.[20]History and Development
Early Practices and Origins
Breath-holding practices underlying static apnea trace their origins to ancient subsistence activities in coastal cultures reliant on underwater resource gathering. In ancient Greece, breath-hold diving was documented as early as 500 BC, where divers plunged into coastal waters to recover valuables from sunken ships, often using simple weights and ropes to extend their time underwater. This method was essential for economic activities like sponge harvesting, which supported trade and daily use, as evidenced by references in classical texts to divers enduring prolonged submersion without breathing apparatus.[21] Parallel traditions emerged in East Asia, particularly among Japanese ama divers—predominantly women known as "sea women"—who practiced breath-hold diving for pearls, abalone, and seaweed. Legends attribute the ama tradition to origins over 3,000 years ago during the Jomon period, with archaeological evidence of shellfish harvesting tools dating back millennia; the earliest written records appear in the 8th-century Man'yōshū poetry anthology, describing their feats of diving to depths of 10 meters or more while holding breath for up to two minutes. These practices were not only vital for community sustenance but also embedded in cultural lore, portraying ama as mythical mermaids with superhuman endurance against the sea's perils.[22][23] By the 19th century, scientific curiosity shifted focus to the physiological limits of apnea. French physiologist Paul Bert conducted pioneering experiments in 1870, observing profound bradycardia—a slowing of the heart rate—during induced apnea in ducks submerged in water, highlighting the mammalian diving reflex that conserves oxygen. His seminal 1878 work, La Pression Barométrique, expanded on hypoxia's effects through animal and human trials in low-pressure chambers, establishing foundational insights into the risks and tolerances of oxygen deprivation akin to prolonged breath-holds. These studies marked the transition from empirical cultural knowledge to systematic inquiry into apnea's mechanisms.[18][24] In the early 20th century, non-competitive demonstrations of prolonged breath-holds gained attention, particularly through Japanese divers who showcased holds exceeding three minutes in informal settings, reflecting honed subsistence skills rather than sport. European interest paralleled this via emerging swimming clubs, where breath-holding exercises were incorporated into training for endurance swimming. Militarily, static apnea featured prominently in submarine escape drills, as U.S. Navy programs from the 1920s onward trained personnel to manage breath-holds during buoyant ascents from depths up to 100 feet, using apparatus like the Momsen lung to mitigate hypoxia risks. These applications underscored apnea's practical role in survival and folklore, often romanticized in tales of divers communing with underwater realms.[25]Evolution into Competitive Sport
The transition of static apnea from informal breath-holding practices to a structured competitive discipline began with the establishment of international governing bodies in the late 20th century. The Confédération Mondiale des Activités Subaquatiques (CMAS), founded in 1958 as a global umbrella organization for underwater activities, initially focused on scuba diving but incorporated formal apnea competitions by the 1970s to standardize rules and safety protocols for emerging freediving events, including static apnea.[26] Similarly, the International Association for Development of Apnea (AIDA), established in 1992 by French freedivers Roland Specker, Loïc Leferme, and Claude Chapuis, aimed specifically to promote and regulate freediving disciplines such as static apnea through democratic governance and international collaboration.[27][28][29] AIDA's emphasis on non-profit organization and athlete involvement distinguished it from CMAS, fostering rapid adoption among competitive freedivers seeking consistent standards for records and events.[28] Key milestones in this evolution included the integration of static apnea as a core event in organized freediving competitions during the 1990s. Static apnea, involving maximal breath-holds while floating face-down in a pool, was introduced as a primary discipline in early AIDA events to test mental endurance and physiological limits without propulsion or depth variables. The first AIDA World Championships in 1996, held in Nice, France, marked the inaugural global competition for national teams, featuring static apnea alongside constant weight disciplines and drawing participants from six countries to establish international benchmarks.[30] This event solidified static apnea's role in competitive formats, with subsequent championships expanding to include individual categories and emphasizing relaxation techniques for optimal performance. The 2000s witnessed a significant surge in static apnea's popularity, propelled by increased media coverage of extreme breath-holds that highlighted the sport's intensity and risks. High-profile stories, such as those in major outlets covering record attempts and tragic incidents, brought global attention to freedivers pushing beyond eight-minute holds, transforming static apnea from a niche training element into a spectator draw within broader freediving competitions.[31] This era also saw organizational advancements, with AIDA's competitions featuring gender-specific categories to promote inclusivity, ensuring equal opportunities for male and female athletes in static apnea events and reflecting a broader shift toward professionalization.[32] As static apnea matured into an Olympic-aspiring discipline, governing bodies like AIDA and CMAS advocated for recognition by the International Olympic Committee, citing its alignment with aquatic sports through standardized rules and safety measures, though full inclusion remains pending. The sport's global spread accelerated post-1990s, with AIDA expanding membership across Europe (its primary base), Asia (through events in Japan and Thailand), and the Americas (via federations in the U.S. and Brazil), leading to annual international competitions that continually refined competitive boundaries.[33] This internationalization, supported by online communities and training networks, elevated static apnea from recreational pursuit to a worldwide competitive arena by the mid-2000s.[30]Techniques and Preparation
Pre-Dive Routines and Relaxation Methods
Physical warm-up routines for static apnea typically involve gentle stretching to relax muscles and reduce oxygen consumption during the hold. A session of 15-20 minutes of light stretching, focusing on the neck, shoulders, back, and legs, helps prepare the body without inducing fatigue.[34] Additionally, practitioners often perform dry breath-holds using apnea tables, which are structured sequences of progressive holds to build carbon dioxide tolerance while remaining on land or in shallow water. These warm-up holds, lasting up to 2 minutes and 45 seconds, promote physiological readiness without excessive exertion.[35] Breathing patterns immediately before a static apnea attempt emphasize controlled preparation to optimize oxygen saturation while minimizing carbon dioxide reduction. This usually consists of 3-5 deep, relaxed breaths—inhaling fully through the nose or mouth and exhaling slowly—to calm the respiratory system, followed by a complete exhale and subsequent full inhale before initiating the hold. Such patterns avoid excessive hyperventilation, which could dangerously lower CO2 levels and delay the urge to breathe.[36] The "breathe-up" phase, involving normal or slightly deepened breathing for several minutes, further supports relaxation and oxygen uptake.[37] Mental techniques play a crucial role in pre-dive preparation by fostering a calm state that conserves energy and extends hold duration. Visualization involves mentally rehearsing a serene submersion, imagining smooth floating and minimal movement to reduce anticipatory anxiety. Mindfulness meditation, often practiced for 5-10 minutes beforehand, promotes parasympathetic activation, lowering heart rate and enhancing focus.[38] These methods can reduce heart rate through enhanced vagal tone, as supported by studies on meditation's impact on cardiovascular regulation.[39] Environmental setup ensures safety and efficiency during static apnea, typically conducted in a controlled pool setting. The diver assumes a face-down floating position at the surface or just below, with arms extended forward and body streamlined to minimize drag and effort. A trained buddy system is essential, with the partner positioned nearby to monitor vital signs, time the hold, and perform rescues if needed, adhering to protocols from organizations like AIDA.[40] Equalization techniques, such as the Frenzel method, are rarely required in static apnea due to the lack of depth, but may be practiced prophylactically for comfort.[35]Training Regimens for Breath-Hold Capacity
Training regimens for breath-hold capacity in static apnea emphasize progressive overload to enhance carbon dioxide (CO₂) tolerance, oxygen (O₂) conservation, and overall physiological efficiency, typically spanning several weeks to months under supervised conditions. These programs are designed to simulate the hypoxic and hypercapnic stresses of prolonged breath-holds, allowing practitioners to adapt without risking blackout. Core elements include targeted drills, cross-training, and structured periodization, with all sessions requiring a trained buddy for safety.[41] CO₂ tolerance drills focus on acclimating the body to rising CO₂ levels, which trigger the urge to breathe, through exercises like apnea walks—dry-land breath-holds performed while walking at a moderate pace. Beginners typically start with holds of 1 minute, recovering fully (1-2 minutes of normal breathing) before repeating for 6-8 intervals, gradually progressing to holds of 3 minutes or more over multiple sessions to build comfort with diaphragmatic contractions. This method elevates CO₂ buildup under light physical stress, improving mental resilience and delaying the breathing reflex without severe hypoxia.[42][43] O₂ management tables, often conducted as underwater static apnea sessions in a pool, train efficient O₂ utilization by incorporating longer recoveries to prevent excessive CO₂ accumulation while pushing hypoxic limits. A representative protocol might involve 10 repeats of 2-minute holds with 1-minute recoveries on full lung capacity, advancing over weeks to fewer but longer intervals, such as 4-6 holds of 3-4 minutes, culminating in single maximal attempts exceeding 5 minutes. These tables enhance peripheral vasoconstriction and metabolic efficiency, allowing sustained low O₂ states.[44][41] Cross-training complements apnea-specific drills by targeting supportive physiological adaptations, such as yoga practices that promote lung expansion and flexibility. Poses like cobra and camel, combined with pranayama breathing, can increase vital capacity by up to 40% through enhanced thoracic mobility and diaphragmatic strength, as shown in studies on yoga regimes.[45] Additionally, lung packing (glossopharyngeal insufflation), where air is swallowed to further inflate the lungs after a full inhalation, can increase lung volume by 15-25% in trained divers.[46] Cardiovascular conditioning—such as moderate aerobic exercise—lowers resting O₂ consumption by improving aerobic efficiency and reducing metabolic rate. These elements foster overall endurance without overtaxing recovery.[47][48] Periodization structures these regimens into 4-6 week cycles, alternating high-intensity apnea sessions with lighter cross-training and mandatory rest days (at least 1-2 per week) to prevent overtraining and allow supercompensation. Progress is monitored using pulse oximeters to track blood oxygen saturation (SpO₂) and heart rate during and post-session, with attention to avoiding levels that risk blackout (typically below 70-80% for trained individuals).[49][50][51]Records and Milestones
All-Time World Records
Static apnea world records are tracked primarily by the International Association for the Development of Apnea (AIDA), which verifies performances in controlled pool environments without prior pure oxygen breathing, distinguishing them from oxygen-assisted categories. These records highlight the pinnacle of human breath-hold capacity under standard conditions, with men's and women's achievements reflecting advances in training and physiological adaptation.[52]Men's Records
The current AIDA world record for men in static apnea stands at 11 minutes and 35 seconds, set by Stéphane Mifsud of France on June 8, 2009, in Hyères, France. This mark has remained unbroken for over 15 years, underscoring its exceptional nature. The all-time top five AIDA-verified performances demonstrate steady progression in the discipline:| Rank | Time | Athlete | Date | Location |
|---|---|---|---|---|
| 1 | 11:35 | Stéphane Mifsud (FRA) | 2009-06-08 | Hyères, France |
| 2 | 09:04 | Herbert Nitsch (AUT) | 2006-12-12 | Not specified |
| 3 | 08:06 | Martin Štěpánek (CZE) | 2001-07-03 | Not specified |
| 4 | 07:35 | Andy L'esage (GBR) | 1996-04-04 | Not specified |
| 5 | 07:16 | Andy L'esage (GBR) | 1994-12-06 | Not specified |
Women's Records
The current AIDA world record for women is 9 minutes and 22 seconds, achieved by Heike Schwerdtner of Germany on May 4, 2025, in Stockholm, Sweden, during the Stockholm Apnea AIDA STA WARS CO2 STRIKES BACK event. This performance surpassed her prior mark of 9:07 from 2024 and her 9:17 in April 2025, continuing the trend of incremental gains. While a complete historical top five list is less comprehensively documented in public AIDA archives, key milestones include Natalia Molchanova's 9:02 on June 29, 2013, in Belgrade, Serbia (AIDA).[5][52]Verification Standards
AIDA enforces strict protocols for official static apnea records to ensure safety and integrity. Performances must occur in an AIDA-sanctioned competition or record attempt, with the athlete holding breath motionless, airways submerged at least 110 cm deep (updated standard for world events as of 2025), and no movement of head or limbs permitted. Upon surfacing, the athlete removes all facial equipment (e.g., nose clip), delivers one visible hand signal and one verbal "OK" to two appointed judges, and remains with nose and mouth above water until judgment. Video recording from multiple angles is mandatory, along with witness oversight by certified AIDA judges and safety divers. Medical pre-checks, including no recent illness or doping, are required, and records are ratified only after review by AIDA's international board. Standard records use pure air breathing; oxygen-assisted holds (up to 30 minutes pre-breath) are categorized separately to maintain comparability.[7][11][16]Trends
Static apnea records have progressed dramatically since the 1990s, when top holds averaged around 6:00 for men, advancing to over 10:00 by the 2010s through refined relaxation techniques and CO2 tolerance training. Women's records followed a parallel trajectory, starting from approximately 4:00-5:00 in the early 1990s and reaching 9:00+ by the 2020s, narrowing the gender gap from over 2 minutes to about 2:13 in current benchmarks. This evolution reflects broader participation and physiological insights, though men's records have plateaued since 2009 while women's continue to advance.[52][6][53]Progression of Records with Pure Oxygen Assistance
Static apnea with pure oxygen assistance involves pre-breathing 100% oxygen for up to 30 minutes before immersion, which saturates the blood and tissues with oxygen while reducing nitrogen levels, thereby delaying the onset of hypoxia and allowing significantly longer holds compared to standard air-based apnea.[54] This variant emerged as a non-competitive discipline, often verified by Guinness World Records, but has faced criticism for compromising safety—due to risks of oxygen toxicity and fire hazards—and deviating from the essence of breath-holding by masking physiological limits.[55] Early documented attempts in the 2000s marked the beginning of formalized progression, with Swedish freediver Bill Strömberg achieving 13 minutes 5 seconds in Lausanne, Switzerland, on October 3, 2004.[56] By the late 2000s, records advanced to around 17 minutes, exemplified by German freediver Tom Sietas, who set 17 minutes 19 seconds in August 2007 during a supervised pool event.[57] These early milestones highlighted the potential for extended durations in controlled settings, though they remained outside competitive freediving frameworks. Key advancements accelerated in the 2010s and beyond, with holds surpassing 20 minutes in verified attempts. Sietas further extended the benchmark to 22 minutes 22 seconds in Changsha, China, on May 30, 2012, following a 20-minute pure oxygen pre-breath.[58] Subsequent records pushed beyond 24 minutes, including Spanish freediver Aleix Segura Vendrell's 24 minutes 3 seconds in 2016 and Croatian Budimir Šobat's 24 minutes 37.36 seconds in Sisak, Croatia, on March 27, 2021.[59] The current pinnacle is Croatian Vitomir Maričić's 29 minutes 3 seconds in Opatija, Croatia, on June 14, 2025, conducted in a pool with medical oversight. In specialized lab or hyperbaric environments, durations exceeding 24 minutes have been reported, underscoring the physiological extensions possible under optimized conditions.[60] The following table summarizes the top five verified pure oxygen-assisted static apnea records for men, all recognized by Guinness World Records:| Rank | Holder | Time | Date | Location |
|---|---|---|---|---|
| 1 | Vitomir Maričić (HRV) | 29:03 | June 14, 2025 | Opatija, Croatia |
| 2 | Budimir Šobat (HRV) | 24:37.36 | March 27, 2021 | Sisak, Croatia |
| 3 | Aleix Segura Vendrell (ESP) | 24:03 | February 28, 2016 | Barcelona, Spain |
| 4 | Tom Sietas (GER) | 22:22 | May 30, 2012 | Changsha, China |
| 5 | Tom Sietas (GER) | 17:28 | December 30, 2008 | Barcelona, Spain |