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Open-water diving
Open-water diving
Open-water diving
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Open-water diving is underwater diving in an open water environment, where the diver has unrestricted access by way of a direct vertical ascent to the breathable air of the atmosphere. Other environmental hazards may exist which do not affect the classification. Open water diving implies that if a problem arises, the diver can directly ascend vertically to the atmosphere to breathe air, so it is also understood that, with this restriction, a staged decompression obligation is incompatible with open water diving, though it does not affect classification of the environment. This meaning is implied in the certifications titled Open Water Diver and variations thereof.[1]

Open water environment

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In underwater diving, open water is unrestricted water such as a sea, lake, river, or flooded quarry. It is a contradistinction to an overhead environment, where there is a physical barrier to direct vertical ascent to the surface, and to a flooded confined space where there may not be enough room to maneuver freely. In open water the diver has direct vertical access to the surface of the water in contact with the Earth's atmosphere.[1]

Environments which by definition are not open water include overhead environments, and diving in these is called Penetration diving. This may involve entering caves or wrecks, or diving under ice or the hull of a large ship. In some contexts the lack of a decompression obligation is considered a necessary condition for classification of a dive as an open water dive, as a decompression obligation is a procedural and safety restriction on immediate ascent to the surface, but this does not affect the classification of the venue as open water.

Swim-throughs – the recreational diving term for arches and short, clear, tunnels where the natural light can be seen at the far end, and there is enough clearance that it is theoretically possible for the diver to pass through the narrowest point without contact with the sides, bottom or ceiling, are technically an overhead environment, but this is often overlooked by divers as there is no risk of getting lost inside, and the risk of entrapment is generally low.

Divers progress from learning diving skills in confined or benign water such as a swimming pool to practicing skills in open water in which the environment is not restricted to a small, controlled locality and depth, with conditions more typical of a natural body of water which might be used by divers,[2] and the range of hazards and associated risk is significantly expanded.[3] In this context confined water and benign water are special cases of open water, as they comply with the more general condition of unobstructed access to the surface.

Some recreational diver certification agencies use a variation on this term in the title of their entry level diver certification. Open Water Diver certification implies that the diver is competent to dive in unrestricted water, with various constraints regarding the conditions, and particularly that their competence is limited to diving in open water with free access to the surface.[4][5]

There are a few variations of open water environments with more specific names. There are also a number of named diving environments which are usually also open water environments.

Open ocean

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The extreme case of open water is the deep open ocean, where the bottom is at a depth which is irrelevant to the diver as there would be no chance of surviving long enough to reach it. Open oceanic water is often remarkably clear, but this is not always the case. There is no natural visual reference for depth in the open ocean, and depth monitoring and control is critically important to diver safety.

Blue-water diving

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Tethered diver in blue water dive observing fauna in the water column
Marine scientist coordinates a blue water dive for 4 companions - each at the end of a rope tether and each rope kept taut by a weight and pulley system

Blue-water diving is done in mid-water where the bottom is out of sight of the diver and there may be no fixed visual reference. It is done by scientific divers for direct observation and sampling of pelagic organisms and particulate matter, particularly the gelatinous zoo-plankton that are fragile and transparent, making them relatively inaccessible by other methods,[6] and by recreational divers for observation and photography of a range of organisms not easily seen in inshore waters.

The techniques of blue-water diving have been developed over the years to suit the conditions and address the hazards of an environment which is functionally bottomless, and has no fixed visible positional references. The diver who is focused on small organisms or instruments at close range is likely to have diminished awareness of depth, buoyancy, current, surge, other divers, large organisms, and even the direction to the surface.[6]

An accepted procedure for scientific blue-water collection diving with several working divers, is to tether the working divers to a central hub connected to a surface platform, and to have an in-water safety diver attend the hub. The tethers pass through fairleads at the hub and are tensioned by a weight at the end, which keeps slack out of the line and thereby reduces the risk of entanglement, and prevents the end of the line from passing through the fairlead. The tether serves to limit the distance a diver can move away from the hub, which is typically fastened to a substantial downline supported by a large buoy at the surface, and kept vertical by a weight. The float at the surface allows the divers to move freely in the water column within the constraint of the tether, and drift with the current. The tethers also allow rope signals between the safety diver and the working divers. The surface platform, generally a small boat, may be tethered to the buoy, and if there is sufficient wind to make this a problem a parachute sea anchor can be deployed to minimise drift. Windage will generally position the buoy and boat downwind of the parachute. The other end of the tether is clipped to the diver's harness or buoyancy compensator by some form of quick-release shackle.[6] These procedures and equipment can also be used at night.

If a sea anchor is deployed to limit drift, it must be kept clear of the divers to minimise the risk of entanglement, and it should be buoyed to prevent sinking in a calm. The sea anchor cable should be buoyant line for the same reason. Blue-water diving operations are constrained by water and weather conditions, including wind, sea state, current strength, visibility, and the presence of aggressive predators.[6]

Black-water diving

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Black-water diving is mid-water diving at night, particularly on a moonless night. The environment is referred to as black-water.[7][8] The term black-water may also be used to refer to diving in zero visibility, or in sewage. Christopher Newbert, author of Within a Rainbow Sea, (1984) is credited as an early black-water diver.[9] In his book, he describes solo offshore night dives to depths of up to 150 feet (46 m).[10] Black-water diving is often done as a photographic opportunity for recreational divers as there can be a wide range of plankton that would not often be seen by day or closer inshore.[11] This is known as blackwater photography.[12]

Weighted downlines are commonly used to provide a stable vertical reference. These may be tied to the boat or supported by a buoy. Each diver may be attached to a downline using a shorter tether to ensure that divers do not go too far from the boat or too deep.[11] The downline may be marked with lights to indicate depth and to attract mobile organisms.[10] A wide range of animal life may be seen, including many species that spend the daylight hours at depths below those accessible to ambient pressure divers, and migrate vertically through the water column on a diurnal cycle.[9] Many of these are bioluminescent or translucent or both.[10]

The boat moves differently from the divers and the divers move differently from the plankton, making it necessary to work to get a position from which there will be enough time to frame and take photos of the drifting subjects. The boat will drift under the influence of current and wind, while the divers and plankton will drift with the current. If there is wind the boat will drag the downlines, and if tethered to the buoy, it will drag the buoy and divers attached. If divers swim ahead of the towing action, they will have a short time to drift with the plankton and take photos until the slack in the line has been taken up, at which point the plankton will be left behind.[11] This drift problem can be reduced by setting a parachute anchor, which will reduce wind drift to a negligible amount. The divers should stay clear of the entanglement hazard of the parachute suspension lines.[7]

Confined water

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At the other extreme from the open ocean, confined water is open water where it is not possible to inadvertently stray outside the designated area due to physical barriers. Usually this also refers to an area of known low risk and minimal hazard – benign water.

The term is often used to refer to a swimming pool or tank where initial skills training of divers takes place, which is both confined and benign. The Queensland government defines confined water for recreational diving purposes as "Water which offers pool-like conditions, good visibility, and water which is shallow enough so that all divers can stand up with their heads well clear of the water".[13] Other definitions do not require such shallow depth, but may have a depth restriction.

Confined water has some of the characteristics of benign water, in that it is not possible to accidentally stray from the environment, but although some usages of the term confined water imply benign conditions, that meaning is not inherent in the term, as water in a confined space may logically be referred to as confined water, and such confined water may contain significant hazards.[citation needed]

Benign water

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Benign water is open water in the sense of a directly accessible free surface, with very low risk and no unknown hazards, where it is unlikely or impossible for a diver to accidentally stray to an area of higher risk. Some definitions add a depth limit and that the water must also be confined.[14][15]

Benign conditions are environments of low risk, where it is extremely unlikely or impossible for the diver to get lost or entrapped, or be exposed to hazards other than the basic underwater environment. These conditions are suitable for initial training in the critical survival skills, and include swimming pools, training tanks, aquarium tanks and some shallow and protected shoreline areas.[14]

References

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Open-water diving

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Open-water diving is the practice of scuba diving in natural or man-made open water environments, such as oceans, lakes, rivers, quarries, and springs, where divers have unrestricted direct vertical access to the surface without overhead obstructions like caves or wrecks. It utilizes self-contained underwater breathing apparatus (SCUBA), an acronym for Self-Contained Underwater Breathing Apparatus, to allow participants to breathe compressed air from tanks while exploring underwater ecosystems, typically for recreational purposes. The foundational certification for open-water diving, commonly known as the Open Water Diver course, is provided by major training agencies including PADI, SDI, and NAUI, and serves as the entry-level qualification for independent diving. This course typically spans three to five days and encompasses three main phases: knowledge development covering scuba physics, physiology, and dive planning; confined water training in pools or shallow sites to master basic skills like mask clearing, regulator use, and buoyancy control; and four open-water dives to apply these skills in real conditions, with maximum depths progressing from 12 meters (40 feet) to 18 meters (60 feet). No prior diving experience is required, though participants must be at least 10-15 years old depending on the agency and junior variants for younger divers. Safety is paramount in open-water diving, with training emphasizing buddy systems, emergency ascent procedures, underwater navigation, and recognition of hazards like currents, visibility limitations, and decompression sickness. Certified open-water divers are qualified to plan and conduct dives to 18 meters (60 feet) worldwide with a certified buddy, but must adhere to no-decompression limits and local regulations; refresher courses are recommended after prolonged inactivity. Essential equipment includes a buoyancy control device (BCD), regulator, mask, fins, wetsuit or drysuit, weight system, and cylinder, all inspected for proper function before each dive. This certification not only enables access to diverse sites like coral reefs and shipwrecks but also promotes environmental stewardship through awareness of marine conservation.

Introduction

Definition and scope

Open-water diving is a form of performed in natural bodies of water, such as oceans, seas, lakes, or quarries, where the diver enjoys unrestricted access to the surface through a direct vertical ascent, free from overhead obstructions, entanglements, or artificial confinements that could impede emergency ascents. This environment demands proficiency in control to maintain neutral positioning and skills to orient within currents, visibility variations, and expansive underwater terrains. The scope of open-water diving extends across recreational activities for leisure and adventure, technical variants involving specialized gases or decompression for greater depths, and professional contexts such as scientific fieldwork or commercial operations. It represents a primary arena for scuba practitioners worldwide, with approximately 6 million active certified divers participating as of 2023. Open-water diving holds significant importance in facilitating of coral reefs, shipwrecks, and pelagic zones, thereby uncovering geological and archaeological insights. In , it enables direct observation, specimen collection, and behavioral studies of aquatic species, contributing to assessments and monitoring. Additionally, it supports , which documents and habitats to advance scientific research and public conservation awareness. As the entry-level standard, it serves as a foundational gateway to advanced specialties like wreck or .

Distinctions from other diving forms

Open-water diving is fundamentally distinguished from confined-water by its , uncontrolled aquatic environments, where divers encounter variable , surface currents, and depths typically limited to 18-30 meters for recreational purposes, in contrast to the shallow, protected settings of pools or quarries used for initial skill development. Confined-water sessions prioritize repetitive practice of basic techniques in calm, predictable conditions to build foundational competencies, whereas open-water dives apply these skills amid real-world variables like tidal flows and thermal layers, demanding heightened and adaptability to mitigate risks such as disorientation or rapid fatigue. This progression introduces environmental unpredictability absent in enclosed , where direct surface access is always available, unlike the potential for entanglement or separation in open settings. In comparison to , which is predominantly industrial and involves a tethered umbilical delivering unlimited from the surface, open-water scuba relies on self-contained underwater breathing apparatus (SCUBA) for independent mobility in recreational or exploratory contexts. Surface-supplied operations emphasize task-oriented work in hazardous conditions, such as underwater construction, with constant topside communication and support, whereas open-water diving focuses on leisure exploration without such infrastructure, exposing divers to greater autonomy and the need for buddy systems. , by contrast, eschews any breathing apparatus entirely, relying on breath-holding techniques for short-duration descents, allowing unrestricted movement but limiting depth and time compared to the extended bottom times enabled by open-water SCUBA. employs closed-circuit systems that recycle exhaled gas, offering prolonged dive durations and reduced bubble noise for stealthier approaches, but requires advanced gas management skills beyond the open-circuit SCUBA used in standard open-water dives, where exhaled gas is vented directly. Open-water diving also contrasts sharply with specialized forms like wreck or , which involve overhead environments that restrict direct ascent to the surface and heighten risks of silt-out, entanglement, or structural collapse. In , divers navigate artificial structures with potential hazards like sharp metal and confined penetrations, necessitating specialized finning to avoid stirring —challenges less prevalent in the open expanses of recreational open-water sites. Cave diving extends this into natural labyrinths of darkness and narrow passages, where navigation relies on guidelines and light sources, amplifying the peril of gas depletion far from exits, unlike the surface-oriented profiles of open-water dives. These distinctions underscore open-water diving's emphasis on accessible, non-penetrative exploration within no-decompression limits. Unique to open-water diving are challenges stemming from dynamic surface influences and biological interactions, including sudden weather shifts that can alter sea states and entry points, often requiring boat-based access for offshore sites not reachable by shore. Divers must contend with encounters involving , such as curious sharks or schooling fish, which demand calm responses to avoid unnecessary risks, alongside managing currents that can sweep equipment or separate buddies—factors minimized in enclosed or tethered diving forms. Buoyancy control emerges as a critical here to navigate these variables efficiently.

History

Origins in scuba development

The development of open-water diving traces its roots to early attempts at providing breathable air underwater, which laid the groundwork for untethered exploration. In the 1770s, English engineer John Smeaton conducted experiments with air supply systems, including the design of a cast-iron diving bell in 1775 that could accommodate two people and maintain an air pocket for extended submersion during salvage operations. These efforts built on ancient concepts of diving bells but introduced more reliable forced-air mechanisms, enabling short-duration dives in open water for practical tasks like bridge construction and wreck recovery. By the 19th century, advancements shifted toward personal apparatus, with German-born inventor Augustus Siebe patenting the first practical standard diving dress in 1837—a waterproof suit connected to a helmet supplied by surface air pumps—which allowed divers greater mobility in open-water environments for tasks such as harbor work and underwater construction. A pivotal breakthrough occurred in 1943 when French naval officer and engineer Émile Gagnan co-invented the Aqua-Lung, the first successful open-circuit self-contained (SCUBA). This demand regulator system delivered from portable cylinders directly to the diver's mouth, regulating flow based on inhalation and eliminating the need for surface umbilicals, thus enabling true untethered open-water dives to depths of up to 100 feet for durations of about an hour. The Aqua-Lung's design, tested initially off the coast of in the that same year, marked the transition from tethered, labor-intensive diving to accessible recreational and exploratory open-water activities. Following , the Aqua-Lung facilitated initial open-water expeditions that expanded scientific understanding of marine ecosystems. In the late 1940s, Cousteau led dives in the Mediterranean, including tests in 1947 at where teams documented underwater flora, fauna, and geological features using early photography and observation techniques, contributing to the first systematic records of coastal habitats. These explorations, conducted from vessels like the Élie Monnier, demonstrated SCUBA's potential for prolonged submersion and paved the way for broader ecological surveys, influencing subsequent certification standards for safe open-water practice.

Establishment of open-water standards

The establishment of open-water diving standards began in the late with the formation of key certification agencies that sought to regulate training and ensure safety following the advent of self-contained (scuba). The launched the first national scuba training program in 1959, certifying instructors and developing structured courses to promote safe practices across the . Similarly, the (NAUI) was founded in 1960, building on earlier instructor certification efforts from 1955 to create standardized training protocols that emphasized competence in open-water environments. The (PADI) followed in 1966, introducing its inaugural course in 1967 to provide a modular framework for beginner certification, which quickly gained popularity for its accessibility. By the early 1990s, these agencies had adopted key safety milestones, including a standardized depth limit of 18 meters (60 feet) for open-water divers to minimize risks associated with and . This limit reflected growing empirical data on physiology and was integrated into certification requirements by organizations like NAUI and PADI to align with no-decompression diving norms. In the , standards further evolved with the formal integration of the , mandating paired diving for mutual monitoring and emergency support, alongside the widespread use of dive tables for planning repetitive dives and managing no-decompression limits. PADI, for instance, funded the development of recreational-specific decompression models in 1987, resulting in the Recreational Dive Planner tables that simplified safe multi-dive profiles for open-water enthusiasts. Global standardization accelerated in the early 2000s through the (ISO), with ISO 24801-2:2007 defining core competencies for autonomous scuba divers, including knowledge of equipment, dive planning, and emergency procedures applicable to open-water settings up to 20 meters. Enriched air nitrox (EAN) became more comprehensively incorporated following ISO 11107:2009, allowing certified divers to use oxygen-enriched mixtures for extended bottom times while adhering to gas management guidelines. Additionally, in the 2020s, agencies like NAUI revised their standards in 2024 to enhance safety protocols, and Scuba Educators International updated their standards in October 2025 to incorporate best practices; ISO/PAS 20708:2023 introduced requirements for artificial open water sites. Industry adoption of digital logging tools has also enhanced post-dive analysis and verification.

Training and Certification

Structure of open-water diver courses

Open-water diver courses follow a standardized modular format designed to build foundational knowledge and skills progressively, typically spanning 3-5 days or 16-32 hours of instruction depending on the certifying agency. The structure generally includes three main phases: knowledge development ( or ), confined-water (in controlled environments like pools to practice basic skills), and open-water dives (at least four dives in natural environments to apply learned concepts). This phased approach ensures participants gain a comprehensive understanding before advancing to unsupervised diving, with the open-water phase often completed over two or more days to allow for safe acclimation to real conditions. The theoretical components, delivered through classroom sessions, videos, or e-learning modules, cover essential topics in dive physics, , and safety. Key areas include the principles of and , which explain how gases behave underwater and how divers maintain ; physiological effects such as (the bends) caused by nitrogen absorption and release, and () from increased on the ; and emergency procedures, including responses to equipment failures or diver separation. These modules typically involve quizzes or exams to verify comprehension, emphasizing conceptual understanding over rote memorization to prepare divers for real-world application. Variations exist among major certifying agencies, reflecting differences in delivery and flexibility while adhering to international standards set by organizations like the World Recreational Scuba Training Council (WRSTC). The (PADI), the largest agency, offers an e-learning option for knowledge development introduced in 2001, allowing participants to complete theory remotely at their own pace before in-person sessions. (SSI) emphasizes flexible scheduling through its MySSI app, enabling modular completion of academic (six sessions), confined-water (six sessions), and open-water (four sessions) phases over varied timelines. Both agencies set a minimum age of 10 years for junior open-water certification, with depth limits of 12 meters (40 feet) for ages 10-11 and 18 meters (60 feet) for ages 12-14, both requiring supervision by a certified adult or professional member of the agency, ensuring accessibility for younger participants under adult guidance.

Required skills and assessments

Open-water diver certification requires mastery of core practical skills that ensure and safety in underwater environments. These include clearing a flooded by tilting the head back and pressing the top of the skirt against the forehead while exhaling forcefully through the to expel , a technique practiced both partially and fully flooded. Regulator recovery entails sweeping the right hand backward from the waist to locate and retrieve the second-stage regulator if dislodged, followed by clearing it with a blast of exhaled air. control is achieved through controlled inflation and deflation of the buoyancy control device (BCD) using the low-pressure inflator, enabling and hovering without hand movement. Efficient finning techniques, such as the with ankles flexed and knees slightly bent, minimize propulsion effort while reducing silt disturbance and conserving energy. Additionally, candidates must demonstrate comfort in without gear through a prerequisite 200-meter surface swim and 10-minute tread, simulating surface mobility. Assessments occur during four open-water dives, each lasting at least 15-40 minutes to a maximum depth of 18 meters (60 feet), where instructors observe and evaluate performance on a pass/fail basis. Dive 1 focuses on basic skill review, including controlled descent, partial mask clearing, and regulator recovery, with emphasis on proper trim and for surface communication. Dive 2 incorporates exercises using the BCD inflator and alternate air source ascent, including a 3-minute safety stop at 5 meters (15 feet) to off-gas . Dive 3 advances to oral BCD inflation, full mask clearing, and hovering, again concluding with a safety stop at 5 meters. Dive 4 is flexible but typically includes compass navigation for reciprocal bearings and square patterns, along with a controlled swimming ascent (CESA) from approximately 9-10 meters while exhaling continuously, and surface signaling via hand gestures or deployment of a if conditions warrant. Competency standards emphasize efficient air management, with beginners expected to maintain a surface air consumption (SAC) rate of 15-25 liters per minute to complete dives with adequate reserve (typically 50 bar or one-third of the tank). Divers must also demonstrate the ability to deploy a (SMB) from depth by orally inflating it while maintaining control to avoid entanglement, signaling their position to surface support.

Equipment

Core scuba apparatus for open water

The core scuba apparatus for open-water diving consists of the essential components that enable divers to breathe, achieve buoyancy control, and navigate underwater environments safely and efficiently. These include the breathing apparatus, mask, fins, snorkel, and buoyancy compensator device (BCD), designed to meet the demands of recreational dives in uncontrolled open-water settings such as oceans or lakes. The breathing apparatus is centered on the open-circuit demand regulator, which supplies breathable air from compressed gas cylinders on demand. It features a first-stage regulator that attaches to the cylinder valve and reduces the high-pressure gas (typically 200-300 bar or 3,000 psi) to an intermediate pressure of about 8-10 bar, and a primary second-stage regulator that delivers air at ambient pressure through a mouthpiece when the diver inhales. An alternate air source, often called an octopus regulator and colored for visibility (e.g., bright yellow), serves as a backup second stage for sharing air with a buddy in emergencies. Cylinders for recreational open-water diving commonly hold 80 cubic feet (2.3 cubic meters) of air at standard pressure, providing sufficient duration for dives up to 40-60 minutes depending on depth and consumption rate; these are typically aluminum for buoyancy or steel for durability. The mask, fins, and snorkel form the basic exposure and propulsion tools. Masks are low-volume designs with a small internal air space between the lens and face, facilitating easy clearing of water by reducing the amount of air needed to equalize pressure and expel ingress. Fins, particularly split-fin designs, enhance propulsion efficiency by channeling water through a lateral split in the blade, which generates thrust with less leg fatigue—ideal for open-water conditions with mild currents. The snorkel allows surface breathing without relying on the regulator, conserving cylinder air during swims to and from dive sites. The buoyancy compensator device (BCD), also known as a buoyancy control device, is a inflatable vest that maintains neutral buoyancy throughout the dive. Many BCDs include integrated weight pockets for distributing ballast directly into the unit, which can eliminate the need for a separate belt and improve streamlining, along with a power inflator connected to the regulator's low-pressure hose for oral or low-pressure air inflation to adjust volume. Deflation valves enable rapid air release for ascent control. Buoyancy in open water follows Archimedes' principle, where the buoyant force equals the weight of the displaced water: Fb=ρgVF_b = \rho g V, with ρ\rho as water density (approximately 1,025 kg/m³ in seawater), gg as gravitational acceleration (9.8 m/s²), and VV as the displaced volume; divers use the BCD to fine-tune VV and counteract weight or suit buoyancy changes with depth.

Auxiliary gear and modifications

In open-water diving, navigation aids are essential for maintaining orientation in environments with potentially low visibility and expansive areas. An underwater compass, typically liquid-filled to ensure smooth card movement and readability, allows divers to follow headings and between reference points like reefs or drop-offs. Dive computers serve as multifunctional tools that track depth, elapsed time, no-decompression limits, and water temperature, often integrating with core scuba apparatus to provide for safe profile management. Surface GPS units, such as those on dive boats or personal beacons, enable precise positioning and return-to-boat navigation upon surfacing, particularly useful in currents that can drift divers away from entry points. Exposure protection gear is adapted to varying temperatures encountered in open water, preventing or discomfort during extended dives. Wetsuits ranging from 3 mm to 7 mm in thickness, made of for via a thin layer of trapped , are selected based on conditions; for instance, a 5 mm is suitable for temperatures between 15–20°C (59–68°F), while thicker options or drysuits with undergarments are used below 10°C (50°F). These suits integrate with buoyancy control devices from the core apparatus to maintain without restricting movement. Signaling and safety equipment enhances visibility and communication in open water, where separation from the group or boat is a concern. deployment kits, consisting of an inflatable buoy attached to a reel and line, allow divers to mark their position from depth, alerting surface support to their location. A , clipped to the buoyancy compensator, provides an audible alert for attracting attention on the surface, effective up to half a mile in calm conditions. Modifications such as extended regulator hose lengths, often 5–7 feet for the primary hose, improve gas-sharing efficiency and diver positioning in areas prone to currents, adapting the standard setup for better maneuverability.

Procedures and Techniques

Pre-dive planning and preparation

Pre-dive planning for open-water diving involves a systematic evaluation of environmental conditions, personal readiness, and logistical arrangements to ensure safety and compliance with established standards. Divers begin by assessing key site-specific factors, including tide charts to predict water levels and currents, weather forecasts to anticipate surface conditions such as and waves, and visibility estimates based on historical data or local reports. These assessments help identify potential hazards like strong tidal flows or poor underwater clarity, which could compromise navigation or emergency responses. Dive site selection is tailored to the divers' skill level and experience, prioritizing accessibility and risk mitigation. For novice open-water divers, shore entries are often preferred due to their simplicity and reduced reliance on boat support, while more advanced sites may involve boat dives for deeper or offshore locations. Factors such as entry and exit points, potential boat traffic, and marine life interactions are researched in advance through reputable dive resources or local operators to align the site with the group's capabilities. The forms a core component of preparation, emphasizing mutual verification to prevent equipment failures. A buddy check involves confirming the control device functions, weights are secure, releases are operational, is turned on and gauges agree, and exchanging a final okay signal; for example, PADI uses the BWRAF for this process. This ritual, performed just before entry, ensures all equipment is properly assembled and operational, with brief cross-references to core setup guidelines as needed. Gas planning is critical for sustaining the dive within safe limits, typically employing the to allocate breathing gas conservatively. One-third of the cylinder's capacity is reserved for descent and bottom time, another third for the return ascent, and the final third as an emergency reserve to handle contingencies like sharing air or unexpected delays. Buddies agree on maximum depth, bottom time, and minimum reserve pressure—often at least 500 psi (35 bar)—to synchronize their profiles and avoid out-of-air scenarios. Documentation supports accountability and post-dive review, beginning with entries that record planned depth, duration, and conditions for future reference. Emergency contact plans are established by sharing dive itineraries, expected return times, and surface support details with a non-diving contact, often incorporating an Emergency Action Plan (EAP) that outlines triggers, medical contacts, and first-aid locations. In coastal areas, legal requirements often mandate the use of dive flags to signal underwater activity and protect divers from vessel traffic, though specifics vary by jurisdiction. , a red flag with a white diagonal stripe, measuring at least 12 by 15 inches (30 by 38 cm), must typically be displayed on a or vessel within 300 feet (90 meters) of the dive site in open water. Internationally, the blue-and-white International Code Flag Alpha (at least 1 meter high) is commonly used on vessels to indicate divers in the water; divers should always check local regulations for compliance.

In-water execution and emergency protocols

Open-water diving execution begins with controlled entry and descent techniques to ensure safe transition from the surface to depth. Common entry methods include the giant stride, where the diver steps forward off a stable platform or boat into deeper water while maintaining balance and scanning below for hazards, and the backward roll, performed from a seated position on smaller vessels to accommodate wave motion by rolling backward over the side. These entries allow for immediate descent initiation by venting air from the buoyancy compensator device (BCD) and adopting a streamlined position. Upon reaching the desired depth, divers maintain through precise BCD inflation adjustments, breath control, and horizontal body trim to minimize energy expenditure and environmental disturbance. Navigation during the dive relies on simple techniques such as establishing an outbound heading and following the reciprocal course—180 degrees opposite—for return to the or line, often using natural references like terrain features or currents for verification. Divers swim at a consistent pace, periodically checking the to hold the bearing within a few degrees, ensuring the group remains oriented without excessive deviation. This reciprocal method forms the foundation of basic open-water orientation, promoting efficient dive profiles aligned with pre-dive plans. Ascent procedures emphasize gradual pressure adjustment to reduce decompression stress. Divers ascend at a controlled rate of 9 to 18 meters per minute, monitored via dive computers or reference lines, while maintaining and visual contact with the group. A mandatory safety stop is conducted at 5 meters depth for 3 to 5 minutes, allowing off-gassing and serving as a final opportunity to equalize before surfacing. In low-gas situations, an air-sharing ascent uses the buddy's alternate () regulator, with both divers ascending together at the prescribed rate while sharing breaths from one source. Basic emergency protocols address immediate threats during in-water phases. For out-of-air scenarios, the primary response involves signaling the buddy and switching to the regulator for a shared ascent, prioritizing calm communication through to avoid panic-induced rapid breathing. If the is unavailable, an emergency swimming ascent may be necessary, exhaling continuously while ascending no faster than bubble rate. In cases of lost diver contact, the protocol dictates a 1-minute search using a 360-degree sweep in the immediate vicinity—scanning above, below, and around for bubbles or movement—before initiating a controlled ascent with ongoing visual checks during the safety stop.

Environments

Open-water diving occurs in diverse environments including , lakes, rivers, , and springs. While offer vast pelagic zones, inland waters provide accessible sites with varying and profiles. For example, dives often feature clear freshwater with depths up to 30 meters and artificial structures, while lake diving may involve thermoclines similar to but with less current.

Open ocean features

The open ocean, encompassing the pelagic zones, represents vast expanses of water far from shorelines, where depths frequently exceed 200 meters and extend into the mesopelagic and deeper layers, creating environments of profound vertical and horizontal scale for divers. These zones are characterized by dynamic physical features, including variable currents that can range from gentle drifts to speeds up to 5 knots in areas influenced by major flows like the or tidal passages, which influence diver navigation and drift patterns. Thermoclines, abrupt transitions in water temperature often occurring between 10 and 30 meters depth, further shape the diving experience by altering , requiring adjustments in exposure protection, and impacting visibility through refractive changes or suspended particles, with typical horizontal sightlines in these waters ranging from 10 to 30 meters depending on density and light penetration. Biologically, the open ocean teems with pelagic adapted to these free-swimming habitats, offering divers encounters with large predators such as —including oceanic whitetips and whale sharks—and rays like manta rays that glide through the . blooms, fueled by seasonal nutrient inputs, create vibrant, nutrient-rich patches that attract filter-feeders and smaller schooling , enhancing in otherwise sparse blue-water realms. At the edges of these vast zones, nutrient upwelling from deeper waters brings essential minerals to the surface, supporting the productivity of fringing ecosystems by promoting algal growth and sustaining food webs that extend into the pelagic environment. Accessing these remote open ocean features often requires specialized methods, such as vessels that serve as mobile bases for multi-day expeditions, enabling divers to reach distant sites like the outer sections of the where coral walls drop into abyssal depths. These operations typically depart from ports like Cairns, , providing access to over 2,300 kilometers of reef systems while minimizing environmental impact through controlled anchoring. Seasonal considerations play a critical role, particularly in regions like the Atlantic, where divers must avoid the hurricane season from June to November to evade rough seas and storm-related disruptions that can halt operations and compromise safety.

Specialized conditions (blue-water and black-water)

Blue-water diving targets the mid-water column of the open ocean, typically at depths of 10 to 30 meters where the seafloor is far below and visibility is exceptional in oligotrophic, nutrient-poor waters characterized by high clarity due to low particulate matter. These conditions prevail in regions like the , enabling divers to suspend themselves in the without bottom reference, often requiring technical scuba configurations for deeper profiles within recreational limits or scientific apparatus for extended observations. Drifting dives are central to the practice, with divers following prevailing currents while tethered to a surface support vessel, allowing passive movement through the pelagic realm to minimize disturbance to fragile inhabitants. Key phenomena observed during blue-water dives include schools of mesopelagic fish, such as (family Myctophidae), which undertake diel vertical migrations into upper layers at night, alongside gelatinous zooplankton like siphonophores and ctenophores that form intricate, drifting aggregations. These encounters provide insights into the behavior and ecology of open-ocean species that are rarely seen in traditional net sampling, as the technique preserves natural orientations and interactions in their habitat. Challenges arise from current speeds that can exceed 1 , necessitating precise control and redundant safety protocols, including surface-supplied air backups for prolonged hangs. In contrast, black-water diving explores the nighttime surface layer, typically 0 to 10 meters deep, in offshore waters over abyssal depths exceeding 3,000 meters, where the absence of ambient light reveals a dynamic driven by . This practice illuminates the world's largest biomass migration, as trillions of planktonic organisms—including larval , , and crustaceans—ascend from mesopelagic depths to feed on surface under darkness, many exhibiting transparent bodies or photophores that emit light when stimulated. Sites like Kona, Hawaii, with water depths over 3,000 meters, exemplify ideal locations due to consistent currents that concentrate these migrants. Techniques for black-water diving emphasize drift diving with strong floodlights deployed from the boat to attract and reveal organisms, while divers use handheld torches to scan the and capture images or specimens without nets. mastery is essential to hover motionless amid unpredictable currents, often with divers tethered to the vessel for repositioning and . Common to both blue- and black-water diving is the reliance on free-drifting protocols with surface support, including chase boats for tracking and recovery, ensuring divers remain within the illuminated or observable zone. Advancements in the have focused on high-efficiency LED lighting systems for underwater use, offering lumen outputs exceeding with run times over 2 hours on rechargeable batteries, significantly improving visibility and reducing in low-light environments like black-water dives.

Safety and Risks

Primary hazards in open water

Open-water diving exposes participants to a range of environmental hazards that differ markedly from controlled environments like pools or quarries. Strong currents represent one of the foremost risks, capable of causing diver drift and separation from the dive site or boat. These currents, often tidal or ocean-driven, can exert forces equivalent to a 10 mph wind on a due to water's 800 times greater compared to air, leading to rapid exhaustion and increased air consumption. In severe cases, currents at 2 knots may prevent divers from maintaining position on ascent lines, resulting in uncontrolled drifts that necessitate signaling for . Boat traffic collisions pose another critical environmental threat, particularly in popular coastal and nearshore areas. Divers surfacing or conducting safety stops risk strikes from propellers or hulls, exacerbated by poor underwater visibility and difficulty localizing boat sounds. U.S. data from 2005-2013 record 442 injuries and 29 deaths from vessel strikes across water activities, with scuba divers particularly vulnerable during ascents without proper surface markers. Hypothermia emerges as a significant hazard in cold open waters below 10°C, where immersion accelerates heat loss 20 to 27 times faster than in air. Core body temperature can drop below 35°C after prolonged exposure, impairing judgment, dexterity, and ultimately leading to if unchecked, even in wetsuit-protected divers. Physiological hazards in open water include , often resulting from rapid ascents due to panic or entanglement. Pulmonary occurs when expanding air during ascent ruptures alveoli, potentially causing arterial gas (AGE), a life-threatening condition where gas bubbles block cerebral or . Analysis of 947 recreational scuba fatalities from 1992-2003 identifies emergency ascents—frequently triggered by currents, out-of-gas situations, or equipment issues—as the disabling agent in 55% of cases. Marine envenomations, particularly from , constitute a prevalent physiological in tropical open waters. Contact with nematocysts delivers causing localized pain, welts, and systemic effects like or cardiac irregularities in severe instances. Surveys of Thai divers indicate that approximately 68% have experienced or witnessed jellyfish stings, underscoring their frequency in tropical dive sites, while DAN reports note around 10,000 annual cnidarian envenomations off alone, many involving submerged activities. Equipment failures, such as regulator free-flow, further compound risks in open water. Uncontrolled gas release can deplete cylinders rapidly and induce panic. DAN case analyses highlight instances where free-flow led to out-of-air emergencies and failed buddy breathing attempts.

Prevention and response measures

Prevention measures in open-water diving emphasize proactive planning to mitigate risks such as currents and air supply failures. Dive briefings are essential, where divemasters provide site-specific information on expected currents, including predictions from tide charts and local observations, to prepare divers for drift conditions and entry/exit procedures. Redundant air supplies, such as pony bottles with capacities of 13 to 80 cubic feet, offer an independent breathing system complete with first-stage regulator, second-stage mouthpiece, and submersible pressure gauge, allowing divers to access emergency gas if the primary supply fails. Fitness prerequisites, including a 200-meter untimed swim using any stroke and 10 minutes of floating or treading water, ensure divers possess the basic water comfort and endurance needed for safe operations. Response protocols focus on immediate actions to address incidents like entanglements and decompression sickness (DCS). For entanglement escape, divers carry accessible cutting tools such as knives or line cutters strapped to buoyancy compensators, forearms, or waist belts, enabling quick severance of lines, nets, or seaweed without restricted movement. In cases of suspected DCS, first aid involves administering 100% oxygen at the highest practical concentration using a non-rebreather mask or demand system to accelerate nitrogen elimination and alleviate symptoms, continuing until advanced medical care is reached. Evacuation follows U.S. Coast Guard standards, incorporating pre-planned procedures for man-overboard recovery, diver rescue, and transport to medical facilities, with crew training on communication and equipment like medical oxygen kits. Monitoring tools and ongoing education enhance safety through real-time alerts and evidence-based updates. Dive computers feature audible alarms that activate when approaching no-decompression limits, signaling divers to ascend and maintain safe levels based on depth and time. The Divers Alert Network (DAN) provides annual updates via its diving reports and safety guidelines, incorporating incident data to refine recommendations on topics like oxygen first aid and post-dive flying intervals.

Advanced Applications

Specialty extensions from open water

After achieving basic open-water certification, divers often pursue specialty courses to expand their skills in specific aspects of open-water environments. These extensions build on foundational techniques, allowing for safer and more versatile exploration while adhering to recreational limits. Common specialties focus on gas management, depth management, and site-specific , enabling divers to access varied underwater features without venturing into technical overhead environments. Similar courses are offered by other agencies such as SSI and NAUI, with equivalent skills training like extended range and deep diver specialties. The PADI Enriched Air Diver specialty, also known as , introduces the use of breathing gases with higher oxygen content (typically 22-36%) and reduced , which extends no-decompression bottom times and lowers the risk of during repetitive dives. This course emphasizes planning dives with enriched air, analyzing gas mixtures, and adjusting dive computers, making it ideal for multi-day trips or sites with repetitive profiles. Similarly, the PADI Deep Diver specialty trains divers to safely reach depths of 18-40 meters (60-130 feet), addressing physiological effects like , gas consumption increases, and procedures through simulated deep dives. For wreck sites, the PADI Wreck Diver specialty covers non-overhead penetration techniques, including mapping wreck layouts, using guidelines for limited entry (up to 40 meters/130 feet from the surface while remaining in ), control to avoid stirring , and entanglement prevention. These specialties typically require two to four open-water dives and are accessible to certified open-water divers aged 12 or older. Professional development paths further extend open-water capabilities, leading toward leadership roles. The PADI Divemaster certification serves as an entry to professional diving, requiring at least 60 logged dives (with 40 needed to begin training) and demonstrating skills in assisting instructors, leading dives, and emergency management in open-water settings. This internship-style program hones site assessment, diver supervision, and equipment handling, preparing individuals for roles in dive operations. Complementing this, specialties in underwater photography and videography enhance documentation skills; the PADI Digital Underwater Photographer course teaches composition using the SEA method (Shoot, Examine, Adjust), strobe lighting to reduce backscatter, and color correction for natural hues in varying water clarity. The PADI Underwater Videographer specialty builds on this by covering equipment selection, exposure and focus techniques, shot sequencing for storytelling, and post-dive editing to produce engaging narratives of open-water marine life. In the 2020s, emerging trends integrate open-water diving with technology and conservation efforts. programs, such as those by Reef Check, engage certified divers in standardized reef monitoring dives to assess health, populations, and invertebrate abundance using simple protocols during regular open-water excursions. These initiatives have expanded post-2020, with volunteers completing thousands of surveys annually to support data-driven reef , as seen in programs like REEF's volunteer surveys that persisted through the with over 370 dives in alone in 2020. Additionally, drone surface support has gained traction for enhancing safety, where recreational drones provide rapid aerial surveillance over open-water dive sites, covering up to 1 square kilometer in 35 minutes to locate missing divers and relay positions to rescue teams. This integration, affordable at around $1,300 for basic setups, complements traditional boat-based operations without replacing them.

Environmental and regulatory aspects

Open-water diving practices incorporate various conservation measures to minimize ecological harm to marine environments. A key principle is the no-touch policy, which prohibits divers from physically contacting coral reefs, marine organisms, or other underwater features to prevent damage from oils, abrasion, or disruption of ecosystems. This approach is promoted through programs like Green Fins, an initiative by the (UNEP) that provides guidelines for sustainable diving operations. Additionally, divers are encouraged to use reef-safe sunscreens free of harmful chemicals such as and octinoxate, which can bleach corals and impair marine life even at low concentrations. Project AWARE, initiated by the (PADI) in , plays a central role in these efforts through programs like Dive Against Debris, where divers worldwide have removed and reported millions of pieces of plastic waste from oceans, contributing to reduced . Regulatory frameworks govern open-water diving to protect sensitive marine areas and ensure sustainable access. supports global initiatives like the 30x30 target, aiming to conserve at least 30% of the world's oceans by 2030 through expanded marine protected areas (MPAs), which restrict activities to preserve . In specific regions, such as the , the Directorate enforces strict rules, including mandatory permits for dive operators, a maximum of eight divers per certified guide, and designated itineraries to limit environmental disturbance. These regulations require vessels to adhere to fixed routes and obtain annual authorizations, balancing with . Sustainability in open-water diving also addresses the carbon emissions associated with operations, particularly boat-based transport. An average boat dive trip using diesel engines generates approximately 61 kg of CO2-equivalent emissions per participant, highlighting the need for fuel-efficient vessels and offset programs. The Green Fins eco-rating system, managed by the Reef-World Foundation, requires certified members to achieve a score of 200 or less, a threshold introduced in 2022. In the 2024–2025 period, Green Fins members achieved a 31% reduction in threats related to single-use plastics, , and rubbish disposal through improved . These enhancements encourage dive operators to adopt verifiable environmental best practices, such as protocols and low-impact propulsion, to lower their overall footprint.

References

  1. https://blog.padi.com/padi-open-water-dives/
  2. https://blog.padi.com/what-is-scuba-diving/
  3. https://store.padi.com/en-us/courses/open-water-diver/p/60462-1B2C/
  4. https://www.tdisdi.com/sdi/get-certified/open-water-scuba-diver-course/
  5. https://www.naui.org/learn/entry-level/open-water-scuba-diver-autonomousiso-level-2/
  6. https://blog.padi.com/junior-open-water-vs-open-water/
  7. https://blog.padi.com/whats-the-difference-between-scuba-diver-and-open-water-diver/
  8. https://blog.padi.com/padi-certification-rules/
  9. https://www.dema.org/store/download.aspx?id=7811b097-8882-4707-a160-f999b49614b6
  10. https://www.the-scientist.com/how-underwater-photography-propels-marine-biology-66588
  11. https://news.harvard.edu/gazette/story/2017/03/underwater-photography-inspires-conservation/
  12. https://blog.padi.com/dsd-to-open-water-diver/
  13. https://www.padi.com/courses/open-water-diver
  14. https://blog.padi.com/how-to-prepare-for-your-open-water-diver-course/
  15. https://blog.padi.com/commercial-diving-vs-recreational-diving/
  16. https://blog.padi.com/freediving-vs-scuba-diving-5-big-differences/
  17. https://blog.padi.com/rebreather-diving-vs-scuba-diving/
  18. https://www.naui.org/cave-diving/
  19. https://blog.padi.com/why-wreck-diver-should-be-your-next-specialty-course/
  20. https://www.tdisdi.com/tdi-diver-news/cave-vs-advanced-wreck/
  21. https://blog.padi.com/liveaboard-diving-indonesia-why-how/
  22. https://blog.padi.com/diving-in-lembeh/
  23. https://www.padi.com/education/continue-learning
  24. https://heritagecalling.com/2024/06/06/the-life-and-work-of-john-smeaton-the-father-of-civil-engineering/
  25. https://library.si.edu/exhibition/fantastic-worlds/sea-change
  26. https://www.cousteau.org/know/inventions/aqua-lung/
  27. https://www.nationalgeographic.com/history/article/the-man-who-taught-humans-to-breathe-like-fish
  28. https://sanctuaries.noaa.gov/news/pdfs/sanctuarywatch/sw6_4.pdf
  29. https://scubaguru.com/032-what-happened-to-the-ymca-scuba-program/
  30. https://www.naui.org/naui-worldwide/our-heritage/
  31. https://blog.padi.com/padi-through-the-decades-1960s/
  32. https://demonray.de/en/history-padi/
  33. https://blog.padi.com/how-deep-can-open-water-vs-advanced-divers-go/
  34. https://scubadiverlife.com/flaws-dive-buddy-system/
  35. https://blog.padi.com/padi-decades-1980s/
  36. https://www.iso.org/standard/42448.html
  37. https://www.naui.org/updated-naui-2024-standards-and-policies/
  38. https://www.scubaeducators.org/sei-open-water-diver-standards-updated/
  39. https://www.tdisdi.com/iti/evolution-of-scuba-open-water-training/
  40. https://www.divessi.com/en/get-certified/scuba-diving/open-water-diver
  41. https://ww2.jacksonms.gov/fulldisplay/fzpX9b/7OK137/PadiOpenWaterDiverTrainingCourseSection1.pdf
  42. https://blog.tangent.com/libweb/dF0KeW/4OK086/SsiOpenWaterManualAnswers.pdf
  43. https://www.idcphuket.com/padi-elearning-phuket/
  44. https://blog.padi.com/padi-courses/
  45. https://blog.padi.com/padi-diving-restrictions/
  46. https://training.divessi.com/index.php?id=22804483
  47. https://www.scubadiving.com/training/basic-skills/10-new-rules-scuba-diving
  48. https://www.padi.com/help/scuba-certification-faq
  49. https://dan.org/alert-diver/article/estimating-your-air-consumption/
  50. https://blog.padi.com/what-is-an-smb-tips-on-how-to-use-one/
  51. https://blog.padi.com/a-basic-guide-to-scuba-diving-equipment-for-beginners/
  52. https://www.divegearexpress.com/library/articles/how-to-select-a-scuba-tank
  53. https://dan.org/alert-diver/article/scuba-cylinder-rundown/
  54. https://www.diversdirect.com/w/selecting-the-perfect-mask
  55. https://www.scuba.com/blog/?p=370174
  56. https://www.divers-supply.com/scuba-gear/bcd.html
  57. https://dtmag.com/thelibrary/eureka-archimedes-basics-of-buoyancy/
  58. https://www.padi.com/articles/9-accessories-every-scuba-diver-needs
  59. https://www.scubadiving.com/best-dive-computers-reviewed
  60. https://www.garmin.com/en-US/garmin-technology/dive-science/in-dive-features/surface-gps/
  61. https://www.scuba.com/blog/wetsuit-thickness-temperature-guide/
  62. https://www.padi.com/gear/signaling-devices
  63. https://www.divegearexpress.com/regulators-spgs/hoses
  64. https://blog.padi.com/scuba-diving-refresher-checklist/
  65. https://dan.org/health-medicine/health-resource/smart-guides/7-mistakes-divers-make-and-how-to-avoid-them/3-insufficient-dive-planning/
  66. https://pros-blog.padi.com/plan-the-dive-dive-the-plan-with-the-padi-skill-practice-and-planning-slate/
  67. https://world.dan.org/safety-prevention/diver-safety/safe-diving-practices/
  68. https://blog.padi.com/the-golden-rules-of-scuba-diving/
  69. https://driveaboatusa.com/blog/diving-flags/
  70. https://www.law.cornell.edu/regulations/hawaii/Haw-Code-R-SS-13-245-9
  71. https://www.boat-ed.com/ohio/studyGuide/Diver-Down-Flags/10103602_42874/
  72. https://blog.padi.com/one-small-step-choosing-correct-entry-method/
  73. https://dan.org/alert-diver/article/mastering-neutral-buoyancy-and-trim/
  74. https://blog.padi.com/how-to-use-a-compass-to-navigate-underwater/
  75. https://dan.org/alert-diver/article/ascent-rates/
  76. https://www.scubadiving.com/what-to-do-when-you-run-out-air-while-scuba-diving
  77. https://www.scubadiving.com/tips-dealing-lost-dive-buddy
  78. https://www.padi.com/sites/default/files/documents/padi-open-water-diver-manual-english.pdf
  79. https://www.noaa.gov/jetstream/ocean/layers-of-ocean
  80. https://www.deeperblue.com/diving-performance-beyond-drag-part-1/
  81. https://www.marineinsight.com/know-more/understanding-thermoclines-in-ocean-waters/
  82. https://www.marinebio.org/oceans/open-ocean/
  83. https://www.montereybayaquarium.org/animals/habitats/open-waters
  84. https://www.science.org/doi/10.1126/sciadv.add5032
  85. https://www.liveaboard.com/diving/australia/great-barrier-reef
  86. https://www.spiritoffreedom.com.au/
  87. https://www.csaocean.com/news/blog/atlantic-hurricane-season-the-perfect-storm-for-coral-reefs
  88. https://diventures.co/blue-water-diving-essential-tips-techniques-safety-guide-for-open-ocean-adventures/
  89. http://www.sargassoseacommission.org/storage/documents/No1_Pelagic_HI.pdf
  90. https://www.ehs.washington.edu/system/files/resources/divingsafetymanualuw.pdf
  91. http://www.cmarz.org/CMarZ_RHBrown_April06/Cruise_Report/Report_of_RV_Ronald_H_mda_toc-2.pdf
  92. https://blog.padi.com/blackwater-diving/
  93. https://ocean.si.edu/ocean-life/fish/blackwater-divers-illuminate-sea-life-night
  94. https://www.orcatorch.com/product/D950V.html
  95. https://dan.org/alert-diver/article/diving-in-currents/
  96. https://dan.org/alert-diver/article/boat-collision-and-propeller-safety/
  97. https://dan.org/health-medicine/travelers-medical-guide/travel-related-injuries/exposure-related-injuries/
  98. https://pubmed.ncbi.nlm.nih.gov/19175195/
  99. https://journals.viamedica.pl/international_maritime_health/article/view/63132
  100. https://dan.org/wp-content/uploads/2020/07/hmli-dan-dive-medical-reference.pdf
  101. https://dan.org/safety-prevention/diver-safety/case-summaries/regulator-free-flow-leads-to-failed-buddy-breathing/
  102. https://dan.org/alert-diver/article/current-dives/
  103. https://www.dansa.org/blog/2022/03/26/scuba-cylinder-rundown
  104. https://blog.padi.com/need-know-swim-scuba-dive-frequently-asked-questions/
  105. https://dan.org/alert-diver/article/dive-knives-and-cutting-devices/
  106. https://dan.org/health-medicine/health-resource/dive-medical-reference-books/decompression-sickness/treating-dcs/
  107. https://www.dco.uscg.mil/Portals/9/DCO%20Documents/5p/CG-5PC/INV/Alerts/0112adv.pdf?ver=2018-10-03-112320-393
  108. https://www.tdisdi.com/sdi-diver-news/dive-computers-guide/
  109. https://dan.org/health-resource-type/health-safety-guidelines/
  110. https://store.padi.com/en-us/courses/enriched-air-diver/p/60468-1B2C/
  111. https://blog.padi.com/what-is-nitrox/
  112. https://blog.padi.com/whats-the-difference-between-the-padi-deep-diver-and-advanced-open-water-diver-courses/
  113. https://nolimitdive.com/padi-wreck-diver-specialty-course/
  114. https://blog.padi.com/padi-divemaster-requirements/
  115. https://www.padi.com/courses/digital-underwater-photographer
  116. https://www.master-divers.com/padi-underwater-videographer/
  117. https://www.reefcheck.org/tropical-program/
  118. https://www.scubadiving.com/379-survey-dives-in-2020-covid-cant-stop-this-bonaire-citizen-scientist
  119. https://dan.org/alert-diver/article/from-surface-to-sky/
  120. https://www.unep.org/news-and-stories/story/environmentally-friendly-diving-conserve-marine-life-sustainable-development
  121. https://ocean.si.edu/ecosystems/coral-reefs/truth-about-corals-and-sunscreen
  122. https://www.padi.com/aware/history
  123. https://www.unep.org/news-and-stories/press-release/world-must-act-faster-protect-30-planet-2030
  124. https://www.galapagossafaricamp.com/scuba-diving-galapagos/
  125. https://www.aggressor.com/destination/galapagos
  126. https://www.researchgate.net/publication/232947319_Greenhouse_Gas_Emissions_from_Marine_Tours_A_Case_Study_of_Australian_Tour_Boat_Operators
  127. https://greenfins.net/blog/green-fins-next-chapter/
  128. https://divernet.com/scuba-news/conservation/zero-risk-divers-green-fins-raises-game/
  129. https://pros-blog.padi.com/how-padi-dive-centers-in-aqaba-are-driving-real-environmental-change-with-green-fins/
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