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Flyboarding in Merritt Island, Florida
Athlete Oliver Winger Flyboarding in Grand Rapids, Michigan

A Flyboard is a brand of hydroflighting device which supplies propulsion to drive the Flyboard into the air to perform a sport known as hydroflying.[1]

A Flyboard rider stands on a board connected by a long hose to a watercraft. Water is forced under pressure to a pair of boots with jet nozzles underneath which provide thrust for the rider to fly up to 22 m (72 ft) in the air or to dive headlong through the water down as far as one is willing to go.[2][failed verification]

History

[edit]

The Flyboard was invented in Autumn 2012 by a French water-craft rider, Franky Zapata.[2][3] The design allows the device to climb out of the water and be stable in the air. This was achieved by the underfoot propulsion and hand stabilization.[3] The French Institut national de la propriété industrielle (INPI) granted Zapata a patent for his invention.[3] The Flyboard was the subject of a lawsuit from competitor Jetlev which was dropped without prejudice in March 2013.[4] The device was presented to the public for the first time at the jet ski World Championship 2012 in China.[3] Since its introduction in 2012 the Flyboard has sold around 2500 units.

In the 2015 season of America's Got Talent, a flyboard enthusiast named Damone Rippy performed Flyboarding as his act on the show.

In 2014 the first dual flight of a pilot with both a Jetlev Jetpack and Flyboard occurred in Sydney Australia at the Jetpack adventures facility by pilot Brad Hudson.[5]

In 2016, Franky Zapata sold Zapata Racing (ZR) to U.S. defense contractor Implant Sciences.[6]

[edit]

Zapata has also invented an independently jet-powered Flyboard (Flyboard Air), powered by five turbines and fueled by kerosene.[7] He piloted the "jet-powered hoverboard" over crowds at the 2019 Bastille Day military celebrations in Paris.[8] On 4 August 2019, Zapata was able to successfully fly over the English Channel after a failed attempt on 25 July.

During this flight, using a backpack fuel reservoir, he accomplished the 35-kilometre (22 mi) journey in about 20 minutes, including a fueling stop. Zapata reached a speed of 180 km/h (110 mph) and maintained an altitude of approximately 15 meters (49 feet).[9][10]

Zapata's company, Z-AIR, had received a €1.3m grant from the French military in December 2018.[11] However, he has said that the flyboard was not yet suitable for military use due to the noise it creates and the challenge of learning how to fly the device.[12] In a France Inter radio interview, France's Minister of the Armed Forces Florence Parly said the flyboard might eventually be suitable, "for example as a flying logistical platform or, indeed, as an assault platform".[13]

In 2017, Zapata had provided the U.S. Army with demonstrations of the Flyboard Air (jet-powered hoverboard) referred to as the EZ-Fly in some news reports, which suggested the price per unit might be $250,000.[14] A July 2019 report provided no indication of any serious interest by the American military as of that time for this new technology.[6]

Technical information

[edit]
Flyboard practice

The Flyboard is a bolt-on device that is attached to a personal water craft (PWC). It is designed so that the PWC follows behind the rider’s trail, allowing the rider multiple degrees of freedom, even allowing the rider to go underwater if they desire. The pilot on the Flyboard is secured in by bindings similar to a wakeboard and the rider is propelled from water jets below the device. The Flyboard is buoyant for safety, which also allows the rider to rest in the water between rides.[15] The use of a personal flotation device and helmet is required by rental locations for safety purposes to protect against serious head trauma in the event of the rider impacting the PWC or stationary structures, and to protect the ears from damage and discomfort from impacts with the water.[16][17]

Device power is controlled by a throttle on the PWC. The equipment may be used in two modes: The primary one requires two people, one to control the PWC throttle which regulates the power and height of the rider. The secondary mode relies on an accessory called an Electronic Management Kit (EMK) which allows the rider to control the PWC throttle.[18]

Movies

[edit]

For the first time, a Flyboard stunt was done in a Bollywood film by Hrithik Roshan in the film Bang Bang!.[19]

See also

[edit]
Wikimedia Commons has media related to Flyboards.

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Flyboard

View on Grokipedia
from Grokipedia

Flyboard is a hydroflighting device consisting of a board attached by a hose to a personal watercraft, such as a jet ski, that uses high-pressure water jets to propel a single rider into the air above the water surface for performing acrobatic maneuvers.
Invented by French jet-ski champion Franky Zapata in 2011, the Flyboard draws water through the personal watercraft's impeller and redirects it via the hose to nozzles primarily at the rider's feet and optional hand-held thrusters, enabling heights of up to 15 meters through propulsion governed by Newton's third law of motion.
First publicly demonstrated at the Jet Ski World Championships in China, it rapidly popularized as an extreme water sport, generating a global industry valued at over $200 million and inspiring turbine-powered variants like Flyboard Air.
Zapata's innovations extended to aerial achievements with Flyboard Air, including a successful English Channel crossing in 2019 after an initial setback, highlighting advancements in personal flight technology despite inherent risks of high-speed water propulsion.

Invention and History

Origins and Invention by Franky Zapata

Franky Zapata, a French jet-ski racer from who began competing at age 16 and secured three world championships along with seven European titles in stand-up jet-ski disciplines, conceived Flyboard as an extension of his expertise in . His background in high-speed handling informed the device's core principle: harnessing the thrust generated by a jet ski's without onboard power sources. In 2011, Zapata hand-built the initial Flyboard prototype using carbon fiber and welded aluminum tubes, adapting the watercraft's exhaust to enable human-scale aerial hovering over water surfaces. The engineering drew directly from jet-ski mechanics, where a personal watercraft (PWC) such as a Sea-Doo or Yamaha Waverunner powers the system by diverting its high-pressure water jet—typically 100-150 horsepower—through a reinforced hose connected to the board's undercarriage. This redirection splits the flow via a Y-shaped manifold into upward-facing nozzles for primary lift and smaller foot-directed jets for stabilization and maneuvering, exploiting the reaction force from expelled water mass per Newton's third law to counter rider weight and achieve vertical propulsion up to 10 meters. The prototype avoided batteries or independent fuels, relying instead on the PWC's engine for continuous water intake and pressurization, with a detachable swivel joint at the hose-board interface to permit 360-degree rotation. The design's empirical foundation stemmed from iterative testing on exhaust dynamics, prioritizing simplicity and immediate lift over complex ; Zapata's team validated nozzle configurations to balance for hovering stability, drawing on the proven reliability of PWC pumps capable of 500-700 liters per minute flow rates. Initial prototypes underwent private trials in , refining hose lengths (around 18-20 meters) to maintain PWC-to-rider separation while minimizing drag. This hose-mediated transfer ensured the rider's position ahead of the PWC, allowing the operator to follow and adjust power dynamically. Zapata conducted the first public demonstrations of the Flyboard prototype in 2012, including events leading to the inaugural Flyboard World Cup in that year, where riders showcased hovering and basic flips powered solely by redirected jets. These early displays confirmed the device's feasibility for recreational use, with participants achieving sustained flights of several minutes at heights of 5-8 meters, though limited by water depth requirements for intake and the need for calm conditions to prevent hose entanglement.

Key Milestones and Commercialization

Zapata Racing, founded by inventor Franky Zapata, secured foundational patents for the Flyboard with priority filing dates as early as September 2011, enabling the device's commercial launch in 2012. This initiated a industry that generated nearly €1 million in profit in its first marketing year and expanded to a $200 million by 2016. Licensing agreements and production scaled quickly, with promotional materials and initial sales targeting water sports enthusiasts globally from late 2011 onward. By 2013, the first international Flyboard competitions were held, boosting adoption through demonstrations at events like the and fostering the emergence of rental operators and training centers across , , and . This period saw rapid business expansion, with Zapata Racing transitioning into broader product lines by 2014, including variants, while licensed providers proliferated to meet demand for recreational sessions. Key technological milestones included the 2016 introduction of the prototype, which achieved via gas turbines and set a for the farthest flight at 2,252.4 meters on April 30 near Sausset-les-Pins, . In 2019, Zapata's successful crossing on August 4—spanning 35.4 km in 22 minutes aboard the turbine-powered , following a failed July 25 attempt—highlighted advancements in endurance and refueling, further elevating the platform's profile and spurring commercial interest in turbine iterations up to the early 2020s.

Technical Specifications

Core Components and Propulsion Mechanics

The standard water-propelled Flyboard system features a rigid deck platform secured with foot bindings or boots to stabilize the rider during flight. This deck incorporates two primary adjustable underneath for main lift thrust, supplemented by a branched hand-held for directional control and forward momentum. The platform links to a (PWC), usually a rated at a minimum of 100 horsepower but optimally 150 horsepower or greater, through a reinforced measuring approximately 18 to 23 meters (60 to 75 feet) in length, along with an adapter plate and swivel joint for seamless water redirection. In operation, the PWC's impeller-driven intakes ambient from the craft's underside, pressurizes and accelerates it to high velocity, then routes the flow via the to the Flyboard nozzles without intermediate storage. Expulsion from the nozzles generates reactive balancing the rider's weight—typically 700-1000 newtons for an average adult—plus additional margin for maneuvers, with flow rates on the order of 60-70 liters per second in high-performance setups. The PWC operator modulates output, while nozzle orientation and rider posture provide fine control; maximum altitudes reach 10-15 meters in calm conditions, constrained by hose length, efficiency, and surface stability to avoid . Operation duration is fuel-limited by the PWC, commonly yielding 20-30 minutes of continuous flight depending on engine consumption at full load.

Physics and Performance Limits

The propulsion system of a Flyboard operates on the principle of transfer from high-velocity jets, where the downward ejection of imparts an equal and opposite upward reaction force on the rider. To achieve hover, this must balance the rider's weight, approximated as F=m˙veF = \dot{m} v_e, with m˙\dot{m} as the of and vev_e as the exit relative to the nozzles. Empirical measurements indicate ve15v_e \approx 15 m/s, requiring m˙60\dot{m} \approx 60 kg/s (equivalent to roughly 950 gallons per minute) to support an 80 kg rider plus equipment, as derived from high-speed video analysis of jet ejection dynamics. However, inefficiencies arise from frictional losses in the (reducing effective and flow) and nozzle dispersion (where not all ejected contributes fully to vertical ), limiting overall to below that of ideal propulsion. Stability in flight stems primarily from active control rather than passive mechanisms, as the water jets produce negligible gyroscopic precession due to the non-rotational nature of the fluid expulsion. Riders maintain equilibrium by adjusting body posture to redirect nozzles—tilting feet for primary lift jets and hands for auxiliary thrust—effectively vectoring the force vector through differential flow. This demands continuous proprioceptive feedback and throttle modulation via the personal watercraft (PWC), but inherent instability emerges from the system's high center of gravity and sensitivity to perturbations; at altitudes exceeding 10 m, minor imbalances can cascade into falls within human reaction times of approximately 0.2 seconds, as small angular deviations amplify under gravity without automated stabilization. Performance is constrained by the PWC's pumping capacity and hose dynamics, capping sustained hover heights at around 9-10 m due to cumulative hose weight (adding downward force) and diminishing net thrust from flow resistance over length. Horizontal speeds rarely exceed 20-30 km/h, as wind forces on the rider's exposed profile (cross-sectional area ~1 m²) generate drag coefficients that overwhelm vectored thrust at higher velocities, particularly in gusts above 10 km/h. Energy demands further limit sessions, with the PWC consuming 20-40 liters of fuel per hour under full load—comparable to 150-300 horsepower equivalents in inefficiency, as much input energy dissipates as heat and turbulence rather than directed momentum.

Operation and User Experience

Basic Techniques and Skill Requirements

Flyboarding demands basic proficiency to facilitate recovery after falls, along with adequate physical conditioning emphasizing and leg strength to counteract the upward thrust from water jets. Participants typically must be at least 12 to 13 years old, with many operators requiring for those under 18, reflecting the need for sufficient body control and awareness to manage propulsion forces safely. The startup sequence involves the rider entering shallow water, mounting the flyboard by kneeling or standing while securing the hose handles for stability. Upon signaling the operator—often via a thumbs-up gesture—the engine is incrementally advanced to water through the , activating the foot and back jets to generate lift. Initial hovering, usually at 1-3 meters above the surface, is maintained by leaning the upper body forward to align with the jet vector, allowing the rider to transition to a standing posture as balance equalizes. Fundamental control relies on visual or to the operator for precise modulation, dictating ascent (increased ) or descent (reduced flow) through minor postural adjustments that redirect the jet efflux. Maneuvers such as turns involve shifts, like bending one to pivot the board—right knee for left turns—and rotations enable 360-degree spins by exploiting while keeping legs perpendicular to the water. Beginners frequently attain stable hovering and rudimentary directional control within 3-7 minutes under guided instruction, aided by the device's inherent stability from balanced multi-jet propulsion; those with prior board sport experience progress faster. Advanced maneuvers, including front or back dives—executed by committing the body into a controlled plunge followed by a 180-degree reorientation—or flips, necessitate 10 or more practice iterations to master timing, thrust synchronization, and recovery positioning.

Safety Protocols and Risk Mitigation

Operators mandate the use of including helmets to guard against head impacts from falls or uncontrolled descents, life vests or personal flotation devices for and prevention, and full-body wetsuits to protect against abrasions, , and water entry during submersion. Impact-resistant gloves and booties are also recommended to shield hands and feet from propulsion-related injuries and rough landings on water surfaces. (PWC) operators, who control water flow to the flyboard via high-pressure hoses, receive specialized training emphasizing immediate hose cutoff in emergencies to avert propulsion or entanglement risks. Pre-session protocols include thorough inspections of integrity, attachments, and PWC fuel levels to detect potential failures that could lead to sudden thrust loss and rapid, uncontrolled drops from heights up to 10 meters. Operations restrict activities to wind speeds below 15 knots (approximately 28 km/h) to maintain stability, as higher gusts exacerbate balance challenges and increase collision hazards with the PWC or other users. A dedicated spotter must monitor rider position and environmental conditions continuously, facilitating real-time communication for hazard avoidance, while covering malfunction and participant falls is standardly required by commercial providers to address inherent fall and propulsion risks. Adherence to certified programs, often comprising 15-30 minutes of instruction on balance, throttle response, and bailout procedures, demonstrably lowers incidence compared to unsupervised attempts, with operators noting substantial risk reductions through structured progression from low-altitude hovers to advanced maneuvers. These measures counteract Flyboard's baseline hazards, such as hose ruptures causing mid-air loss of lift or awkward water re-entries leading to spinal or limb trauma, though empirical data underscores that incomplete protocols still yield elevated rates relative to calmer water sports like .

Variants and Technological Advancements

Turbine-Powered Iterations like

Franky Zapata introduced the in 2016 as a turbine-powered evolution of his original water-jet Flyboard, shifting from a tethered to an independent backpack system fueled by and equipped with five gas turbines for aerial flight untethered from water sources. This design enables vertical takeoff and landing on varied surfaces, with demonstrated capabilities including speeds up to 150 km/h, altitudes reaching 3,000 meters, and flight durations of approximately 10 minutes per tank. The Flyboard Air's autonomy addresses key limitations of the water-dependent Flyboard by eliminating the need for a nearby and , allowing operation over land or without infrastructure constraints and facilitating rapid repositioning via user-controlled through body movements. However, its introduces trade-offs, including high operational from the jet engines—comparable to industrial levels exceeding 120 dB—and restricted endurance due to the load's weight, which caps practical flights at short bursts despite redundancy in critical systems for stability. Zapata's development iterated through prototypes tested via empirical flight data, including crash recoveries and such as a 2016 farthest flight, culminating in the 2019 crossing on August 4, covering 35 km in 22 minutes with a mid-point refueling stop on a support boat, which underscored the platform's potential for extended, pilot-autonomous travel despite initial failures like the July 25 attempt. By 2020, Zapata pursued certifications akin to FAA standards for ultralights, emphasizing safety through redundant engines and stabilization, though recreational access remained restricted pending regulatory approval and requiring extensive pilot training.

Recent Innovations and Market Evolutions

In June 2025, Zapata Racing introduced a next-generation flyboard model featuring enhanced through refined designs and optimizations, alongside integrated safety protocols tailored for training facilities and rental operations. These updates prioritize reduced operational noise and improved control, addressing user feedback on reliability during extended sessions. Similarly, X-Jets released a lightweight variant in March 2025, constructed with carbon fiber and injection molding to achieve approximately 30% weight reduction compared to prior models, facilitating easier transport and higher maneuverability for professional competitors. Control advancements include intuitive systems with real-time feedback on metrics such as altitude, speed, and , enabling finer adjustments to mitigate from hose dynamics or rider imbalance. The Wataboard EX2, launched in 2025, incorporates a reinforced frame for superior structural integrity during high-G tricks, enhancing stability without compromising responsiveness. Safety evolutions extend to automatic shutdown mechanisms and upgraded protective gear, empirically reducing incident rates in controlled environments by responding to detected anomalies like excessive tilt or pressure loss. Market shifts reflect a (CAGR) of 10.8% for flyboarding equipment from 2025 to 2030, with the sector valued at USD 86.4 million in 2025, propelled by demand in adventure sectors. Partnerships, such as FlyDive's May 2025 deployments with Southeast Asian luxury resorts, underscore expansions in beginner-accessible models suited for coastal hubs in and , where rising participation in hydroflight activities correlates with infrastructure investments in water sports venues. These trends emphasize iterative refinements to core water-tethered designs, though fundamental constraints like propulsion dependency on limit scalability absent decoupled systems.

Commercial and Cultural Impact

Market Growth and Economic Factors

The global flyboarding market was valued at approximately USD 150 million in 2024 and is projected to grow at a (CAGR) of 12%, reaching USD 350 million by 2030, driven primarily by increasing demand for adventure and experiences. This expansion encompasses both and experiential services, with rentals forming a dominant through session-based typically ranging from USD 80 to USD 150 for 20- to 30-minute rides, offered by operators in coastal and resort destinations worldwide. Equipment sales, often channeled through licensees of Zapata Racing—the company founded by inventor Franky Zapata—contribute to market accessibility, as certified boards and hoses are distributed to independent operators for integration with (PWCs). Low entry barriers have fueled entrepreneurial adoption, with startup costs for operators estimated at around USD 20,000, including a compatible (priced USD 10,000–15,000) and flyboard attachment (USD 5,000–10,000), enabling rapid deployment in tourism-heavy regions like , , and . This affordability, combined with flyboarding's appeal as a high-adrenaline, visually striking activity, has tied commercial success to individual innovators and local ventures rather than large conglomerates, though proliferation depends on navigating varying regulatory environments for operations. Tourism integration in areas with warm climates and established water sports infrastructure has amplified growth, as operators leverage short setup times and minimal infrastructure needs to attract seasonal visitors seeking novel experiences. The activity supports thousands of annual users globally, inferred from market revenue and session volumes, while generating ancillary jobs in instruction, , and tour guiding within the broader water sports sector, though precise flyboard-specific figures remain limited. Profitability, however, faces constraints from seasonal demand fluctuations—peaking in summer months and weather-dependent regions—and elevated costs due to the activity's inherent risks, which can limit year-round viability for smaller operators without diversified offerings.

Media Appearances and Competitive Events

Flyboard gained prominence in competitive sports through events like the Flyboard World Cup, inaugurated in 2012 in , , with 50 athletes from 21 countries competing in freestyle routines emphasizing height, aerial duration, and trick creativity. The 2013 edition, also hosted in , was won by a Thai rider, while subsequent championships, such as the 2016 event in from September 16-18, featured top professionals executing complex maneuvers over water. These annual gatherings have evolved flyboard from a novelty activity into a semi-professional , drawing international participants and spectators to venues like Cavalaire-sur-Mer, in 2017. Competition records highlight achievable heights exceeding 15 meters and sustained flights demonstrating rider control, though performances are constrained by water limits and safety margins. Judging panels score based on technical difficulty and execution, fostering innovation in tricks like backflips and dives, as seen in coverage of events with over 100 riders in peak years. While these showcases promote flyboard's adrenaline-driven appeal, media portrayals often emphasize polished pro routines, potentially glossing over the rigorous and high failure rates for amateurs, where scripted demos prioritize spectacle over instructional realism. In media, flyboard has appeared in stunt sequences for films such as The Hustle (2019), where attempted routines under stunt supervision, underscoring its use for dynamic action scenes. Television features include ABC News segments on champion Gemma Weston's heart-stopping backflips in 2016 and Mike Rowe's experiential attempt on the 2024 episode of , which highlighted operational challenges in real-time. Such appearances amplify flyboard's entertainment value but can overhype accessibility, as novice sessions typically involve tethered guidance rather than the autonomous feats depicted.

Controversies and Criticisms

Documented Accidents and Fatality Risks

In July 2025, Egyptian flyboard performer Magdy Abdelghany, aged 44, died after plummeting headfirst from a height during a at a resort in , suffering fatal head injuries from the impact amid reports of a device malfunction or loss of balance. The incident occurred in front of guests, highlighting risks from uncontrolled descent where water surfaces act as unyielding barriers, producing deceleration forces comparable to collisions at 40-50 km/h depending on fall height and entry angle. A September 2017 Flyboard accident off , resulted in the drowning death of a rider, with the victim's family filing a against manufacturers alleging that a faulty component in the water propulsion system led to submersion and inability to resurface. Such equipment failures, including hose detachment or pressure loss, can cause sudden thrust cessation, propelling users into uncontrolled submersion rather than controlled re-entry, distinct from balanced operation where aids recovery. In July 2017, an , man sustained serious injuries, including potential fractures and concussions, after falling approximately 3.7 meters (12 feet) from a Flyboard at , , due to apparent loss of stability. Falls from operational heights of 10-12 meters, achievable via sustained , amplify injury potential through hydrodynamic forces equivalent to rigid impacts, as velocity upon entry scales with sqrt(2gh) per basic , often exceeding novice control thresholds. Reported causes across incidents emphasize operator error in maintaining thrust equilibrium—such as asymmetric control leading to spins—and mechanical issues like hose integrity, over inherent platform flaws, with physics dictating that water entry at elevated speeds mimics irrespective of myths. Fatalities appear infrequent relative to global sessions, akin to unregulated aerial pursuits, though underreporting in recreational contexts limits precise ; novice participation correlates with elevated vulnerability due to skill deficits in countering G-forces up to 3-5g during maneuvers.

Regulatory Challenges and Environmental Effects

In , regulations enacted in July 2014 for water jetpacks, encompassing Flyboard devices, mandated that riders be at least 16 years old, operations occur in waters at least 6 feet deep, and participants wear bright orange life vests visible from 1,000 feet away, aiming to mitigate collision risks and ensure visibility. These rules, proposed by the Department of Natural Resources in response to emerging safety data from early commercial operations, reflect broader state efforts to integrate novel hydroflight activities into existing boating frameworks without stifling innovation. In , , Flyboard-type devices tethered to are classified as declared commercial vessels, requiring registration, operator licensing, and adherence to gazetted conditions on speed, proximity to swimmers, and equipment standards to prevent maritime hazards. Aerial variants, such as turbine-powered iterations, face federal oversight in the United States, where the evaluates noise generation and potential privacy violations from overflights, often categorizing them under or ultralight regulations that demand pilot certification and operational limits to balance recreational use with concerns. Environmental critiques of water-based Flyboard focus on propulsion-induced and , which could theoretically displace or injure small and corals by drawing seawater through hoses at high velocities. In , fishermen's complaints in 2013 about disturbance led the Department of Land and Natural Resources to convene public hearings, highlighting localized scares of marine species fleeing operational zones. Empirical assessments, however, reveal no peer-reviewed evidence of widespread ecosystem degradation, with turbulence effects confined to transient, low-volume disturbances akin to those from , which studies indicate fish evade predictably without long-term behavioral or population shifts. Fuel consumption, derived from gasoline-powered watercraft for standard Flyboard or kerosene for aerial models, yields CO2 emissions comparable to recreational —approximately 0.5-1 kg per minute of operation—but these are offset by tourism revenue enabling , underscoring precautionary regulations that prioritize unverified risks over verifiable economic trade-offs. Such measures, while protective, have drawn for potentially impeding technological advancement absent causal proof of harm.

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  65. https://www.mirror.co.uk/news/world-news/hotel-tourists-horrified-watch-famous-35584664
  66. https://www.gdnonline.com/Details/1358354
  67. https://content.next.westlaw.com/Document/Ica96dda339b811e89bf099c0ee06c731/View/FullText.html?contextData=%28sc.Default%29&transitionType=Default
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  69. https://abc17news.com/news/2017/07/03/overland-park-man-suffers-serious-injuries-in-flyboard-accident-at-lake-of-the-ozarks/
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  71. https://www.delmarvanow.com/story/news/local/maryland/2014/07/14/water-jetpack-regulations/12642511/
  72. https://wtop.com/news/2014/07/maryland-regulates-jetpacks/
  73. https://nypost.com/2013/08/08/iron-man-water-jetpacks-spark-safety-environmental-concerns-in-hawaii/
  74. https://www.today.com/money/iron-man-jetpacks-spark-concerns-hawaii-6c10876018
  75. https://pmc.ncbi.nlm.nih.gov/articles/PMC2442850/
  76. https://www.kelownaseadoorentals.com/is-jet-skiing-bad-for-the-environment
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