Divers face specific physical and health risks when they go underwater with scuba or other diving equipment, or use high pressure breathing gas. Some of these factors also affect people who work in raised pressure environments out of water, for example in caissons. This article lists hazards that a diver may be exposed to during a dive, and possible consequences of these hazards, with some details of the proximate causes of the listed consequences. A listing is also given of precautions that may be taken to reduce vulnerability, either by reducing the risk or mitigating the consequences. A hazard that is understood and acknowledged may present a lower risk if appropriate precautions are taken, and the consequences may be less severe if mitigation procedures are planned and in place.
A hazard is any agent or situation that poses a level of threat to life, health, property, or environment. Most hazards remain dormant or potential, with only a theoretical risk of harm, and when a hazard becomes active, and produces undesirable consequences, it is called an incident and may culminate in an emergency or accident. Hazard and vulnerability interact with likelihood of occurrence to create risk, which can be the probability of a specific undesirable consequence of a specific hazard, or the combined probability of undesirable consequences of all the hazards of a specific activity. The presence of a combination of several hazards simultaneously is common in diving, and the effect is generally increased risk to the diver, particularly where the occurrence of an incident due to one hazard triggers other hazards with a resulting cascade of incidents. Many diving fatalities are the result of a cascade of incidents overwhelming the diver, who should be able to manage any single reasonably foreseeable incident. The assessed risk of a dive would generally be considered unacceptable if the diver is not expected to cope with any single reasonably foreseeable incident with a significant probability of occurrence during that dive. Precisely where the line is drawn depends on circumstances. Commercial diving operations tend to be less tolerant of risk than recreational, particularly technical divers, who are less constrained by occupational health and safety legislation.
Decompression sickness and arterial gas embolism in recreational diving are associated with certain demographic, environmental, and dive style factors. A statistical study published in 2005 tested potential risk factors: age, gender, body mass index, smoking, asthma, diabetes, cardiovascular disease, previous decompression illness, years since certification, dives in last year, number of diving days, number of dives in a repetitive series, last dive depth, nitrox use, and drysuit use. No significant associations with decompression sickness or arterial gas embolism were found for asthma, diabetes, cardiovascular disease, smoking, or body mass index. Increased depth, previous DCI, days diving, and being male were associated with higher risk for decompression sickness and arterial gas embolism. Nitrox and drysuit use, greater frequency of diving in the past year, increasing age, and years since certification were associated with lower risk, possibly as indicators of more extensive training and experience. [1]
Statistics show diving fatalities comparable to motor vehicle accidents of 16.4 per 100,000 divers and 16 per 100,000 drivers. Divers Alert Network 2014 data shows there are 3.174 million recreational scuba divers in America, of which 2.351 million dive 1 to 7 times per year and 823,000 dive 8 or more times per year. It is reasonable to say that the average would be in the neighbourhood of 5 dives per year. [2]
Hazard | Consequences | Cause | Avoidance and prevention |
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Any liquid environment. | Inhalation of liquid (water), usually causing laryngospasm and suffocation caused by water entering the lungs and preventing the absorption of oxygen leading to cerebral hypoxia. [3] |
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Complications can occur up to 72 hours after a non-fatal drowning incident, and may lead to a serious condition or death. | Physiological responses to contaminants in the lung due to inhalation of liquid.
| Prompt and appropriate medical treatment after near drowning, including a medical observation period. |
Hazard | Consequences | Cause | Avoidance and prevention |
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Oxygen partial pressure in the breathing gas is too low to sustain normal activity or consciousness. | Hypoxia: Reduced level of consciousness, seizures, coma, death. Severe hypoxia induces a blue discoloration of the skin, called cyanosis, but this may also be present in a diver due to peripheral vasoconstriction resulting from exposure to cold. There is typically no warning of onset or development. | Equipment failure: A faulty or misused rebreather can provide the diver with hypoxic gas. |
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Some breathing gas mixtures for deep diving such as trimix and heliox are hypoxic at shallow depths, and do not contain enough oxygen to maintain consciousness, or sometimes life, at or near the surface. [13] |
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Internal corrosion of full cylinder standing for a long time can potentially use up some of the oxygen in the contained gas before the diver uses the cylinder. [15] [16] |
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Loss of breathing gas supply. | May result in drowning, occasionally asphyxia without water aspiration. | Equipment failure: Several modes are possible.
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Running out of breathing gas because of poor gas monitoring discipline. [21] |
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Running out of breathing gas because of being trapped by nets or lines. |
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Running out of breathing gas because of being trapped or lost in enclosed spaces underwater, such as caves or shipwrecks. [23] |
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Inhalation of salt spray | Salt water aspiration syndrome: a reaction to salt in the lungs. | Inhaling a mist of sea water from a faulty demand valve. |
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Carbon monoxide contamination of breathing gas | Carbon monoxide poisoning. | Contaminated air supplied by a compressor that sucked in products of combustion, often its own engine's exhaust gas. Aggravated by increased partial pressure due to depth. |
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Oil getting into the air and partially oxidising in the compressor cylinder, like in a diesel engine, due to worn seals and use of unsuitable oils, or an overheated compressor. [25] |
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Hydrocarbon (oil) contamination of air supply. | Emphysema or lipid pneumonia (more to be added). | Caused by inhaling oil mist. This may happen gradually over a long time and is a particular risk with a surface supplied air feed. [26] |
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Excessive carbon dioxide in breathing gas | Carbon dioxide poisoning or hypercapnia. [27] [28] |
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The scrubber of a diving rebreather, fails to absorb enough of the carbon dioxide in recirculated breathing gas. This can be due to the scrubber absorbent being exhausted, the scrubber being too small, or the absorbent being badly packed or loose, causing "tunneling" and "scrubber breakthrough" when the gas emerging from the scrubber contains excessive carbon dioxide. |
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Filling of cylinders with compressed air taken from an area of raised concentration of carbon dioxide. |
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Breathing the wrong gas | Consequences depend on the circumstances, but may include oxygen toxicity, hypoxia, nitrogen narcosis, anoxia, and toxic effects of gases not intended for breathing. Death or serious injury is likely. |
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Displacement of demand valve (DV) from the diver's mouth. | Inability to breathe until demand valve is replaced. This should not normally be a major problem as techniques for DV recovery are part of basic training. Nevertheless, it is an urgent problem and may be exacerbated by loss of the mask and/or disorientation. |
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Caustic cocktail |
| Leakage of water into the breathing loop of a rebreather, which dissolves alkaline material used to chemically remove carbon dioxide from exhaled air. This contaminated water may move further along the breathing loop and reach the diver's mouth, where it may cause choking, and in the case of strong alkalis, caustic corrosion of the mucous membranes. |
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Hazard | Consequences | Cause | Avoidance and prevention |
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Sudden chilling of the inner ear. | Vertigo, including dizziness and disorientation, particularly if one side is more chilled than the other. | Cold water in the outer ear passage, chilling the inner ear, particularly severe if the eardrum is ruptured. | Use of a hood to keep the head covered. Water leaking into the hood will warm up before entering the external auditory opening and will be reasonably warm before reaching the eardrum, and will soon reach body temperature if flushing is minimised. |
Pressure difference over eardrum | Burst or stretched eardrum: The eardrum is stretched due to a pressure difference between the outer and middle ear spaces. If the eardrum stretches sufficiently, it may rupture, which is more painful. Water entering the middle ear may cause vertigo when the inner ear is cooled. Contaminants in the water may cause infection. [31] | The pressure in the middle ear not equalizing with external (ambient) pressure, usually due to failure to clear the Eustachian tube. [31] | Ears can be equalized early and often during the descent, before the stretching is painful. The diver can check if the ears will clear on the surface as a precondition for diving. [31] |
Reversed ear may be caused by the outer ear passage being blocked and the pressure remaining low, while the middle ear pressure increases by equalising with ambient pressure through the eustachian tubes, causing a pressure differential and stretching the eardrum, which may eventually rupture. [32] |
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Pressure difference between paranasal sinus and ambient pressure. | Sinus squeeze: Damage to the sinuses usually resulting in pain, and often burst blood vessels and nosebleed. [33] | Obstruction to the sinus ducts leading to pressure differences between the interior of the sinus and the external pressure. [33] | Do not dive with conditions such as the common cold or allergies that cause nasal congestion. [33] |
Localised low pressure in the diving mask. | Mask squeeze: Squeeze damage to blood vessels around the eyes. [34] | Caused by local low pressure in the air space inside a diving half-mask. Ambient pressure increase during descent not balanced inside mask air space. |
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Reduction of volume of airspace in drysuit. |
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| Modern drysuits have a low pressure air hose connection and valve to inflate the drysuit from the cylinder. Adding sufficient air to maintain the bulk of the undersuit will prevent suit squeeze and stabilize buoyancy of the suit. |
Pressure difference between lung gas contents and ambient pressure | Lung squeeze: Lung damage. | Free diving to extreme depth. | It can be avoided by limiting free diving depth to capacity of lungs to compensate, [35] and by training exercises to increase compliance of chest cavity.[ citation needed ] |
Rupture or supply pressure failure of a surface supply hose with simultaneous failure of the non-return valve. [35] | Maintenance and pre-dive tests of non-return valves on the helmet or full face mask. | ||
Helmet squeeze, with the old standard diving dress. (This can not happen with scuba or where there is no rigid pressure-tight helmet) | In severe cases much of the diver's body could be mangled and compacted inside the helmet; however, this requires substantial pressure difference, or by a sudden considerable increase in depth, as when the diver falls off a cliff or wreck and descends faster than the air supply can keep up with the pressure increase. | A non-return valve in the air supply line to the helmet failing (or absent on the earliest models of this type of diving suit), accompanied by a failure of the air compressor (on the surface) to pump enough air into the suit for the gas pressure inside the suit to remain equal to the outside pressure of the water, or a burst air supply hose. | Appropriate maintenance and daily pre-use testing of non-return valves. |
A sudden large increase in ambient pressure due to sudden depth increase, when the air supply can not compensate fast enough to prevent compression of the air in the suit. |
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Tooth squeeze [36] | Toothache, most often affects divers with preexisting pathology in the oral cavity. [37] | Any gas space inside a tooth due to decay or poor quality fillings or caps may allow tissue inside the tooth to be squeezed into the gap causing pain. | Tooth squeeze may be avoided by ensuring good dental hygiene and that all fillings and caps are free of air spaces. |
Suit compression. | Loss of buoyancy may lead to:
| Buouyancy loss due to compression of foam neoprene wet or drysuit material. |
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Hazard | Consequences | Cause | Avoidance and prevention |
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Lung overpressure: Pressure in lungs exceeds ambient pressure. | Pulmonary barotrauma (Lung overexpansion injury)—rupture of lung tissue allowing air to enter tissues, blood vessels, or spaces between or surrounding organs:
| Failing to maintain an open airway to release expanding air while ascending. | Divers should not hold their breath while ascending after diving with breathing apparatus:
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Sinus overpressure. | Sinus overpressure injury is commonly restricted to rupture of mucous membrane and small blood vessels, but can be more serious and involve bone damage.[ citation needed ] | Blockage of the sinus's duct, preventing trapped air in a sinus from equalising with the pharynx. |
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Middle ear overpressure | Injury (reversed ear) of eardrum stretching or bursting outwards due to expansion of air in the middle ear. | Blocked Eustachian tube fails to allow pressure to equalise middle ear with the upper airway. | |
Overpressure within a cavity in a tooth, usually under a filling or cap. | Tooth squeeze/Toothache, may affect divers with preexisting pathology in the oral cavity.
| Gas may find its way into a cavity in the tooth or under a filling or cap during a dive and become trapped. During ascent, this gas will exert pressure inside the tooth. | Good dental hygiene, and maintenance of dental repairs to prevent or remove potential gas traps. |
Suit and BC expansion | Loss of buoyancy control—uncontrolled ascent. | Expansion of neoprene suit material, gas content of dry suits and buoyancy compensators increasing buoyancy of the diver. |
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History of heavy smoking | Risk of increased severity of decompression illness | Data from a 2000 analysis of decompression illness records suggest that smokers with DCI tend to present with more severe symptoms than non-smokers. | Don't smoke. |
Hazard | Consequences | Cause | Avoidance and prevention |
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Medium to long term exposure to high partial pressures (>c1.3 bar) of inert gas (usually N2 or He) in the breathing gas. | Decompression sickness ("the bends"): Injury due to gas bubbles expanding in the tissues and causing damage, or gas bubbles in the arterial circulation causing emboli and cutting off blood supply to tissues downstream of the blockage. | Gas dissolved in tissues under pressure during the dive according to Henry's Law coming out of solution and forming bubbles if the ascent and decompression is too fast to allow safe elimination of the gas by diffusion into the capillaries and transport to the lungs where it can diffuse into the respiratory gas. Although rare, decompression sickness is possible in free-diving (breathhold diving) when many deep dives are done in succession. (See also taravana). |
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Short term (immediate onset) exposure to high partial pressure (>c2.4 bar) of nitrogen in the breathing gas: | Nitrogen narcosis:
| A high partial pressure of nitrogen in the nerve tissues. (other gases may also have narcotic effect, to varying degrees).
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Short term (minutes to hours) exposure to high partial pressure (>c1.6 bar) of oxygen in the breathing gas. | Acute oxygen toxicity:
| Breathing gas with too high a partial pressure of oxygen, risk becomes significant at partial pressures exceeding 1.6 bar (partial pressure depends upon proportion of oxygen in the breathing gas, and depth). |
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Long term (hours to days) exposure to moderately raised partial pressure (>0.5 bar) of oxygen in the breathing gas. | Chronic oxygen toxicity:
| Breathing gas at too high a partial pressure of oxygen, Risk is significant at a partial pressure in excess of 0.5 atmospheres pressure for long periods and increases with higher partial pressure even for shorter exposures. |
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Exposure to a high partial pressure(>15 bar) of helium in the breathing gas. | High-pressure nervous syndrome (HPNS): | HPNS has two components:
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Hazard | Consequences | Cause | Avoidance and prevention |
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Exposure to cold water during a dive, and cold environment before or after a dive, wind chill. [46] | Hypothermia: Reduced core temperature, shivering, loss of strength, reduced level of consciousness, loss of consciousness, and eventually death. | Loss of body heat to the water or other surroundings. Water carries heat away far more effectively than air. Evaporative cooling on the surface is also an effective mechanism of heat loss, and can affect divers in wet diving suits while travelling on boats. [46] |
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Nonfreezing Cold Injuries (NFCI). | Exposure of the extremities in water temperatures below 12 °C (53.6 °F). | Hand and Foot Temperature Limits to avoid NFCI: [48]
Protection in order of effectiveness:
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Frostbite | Exposure of inadequately perfused skin and extremities to temperatures below freezing. [46] | Prevent excessive heat loss of body parts at risk: [46]
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Muscular cramps |
| Better insulation and/or suit fit. | |
Hard corals. [46] | Coral cuts—Infected lacerations of the skin. [46] | Sharp coral skeleton edges lacerating or abrading exposed skin, contaminating the wound with coral tissue and pathogenic microorganisms. [46] | |
Sharp edges of rock, metal, etc. [46] | Lacerations and abrasions of the skin, possibly deeper wounds. | Contact with sharp edges. |
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Stinging hydroids [46] | Stinging skin rash, local swelling and inflammation. [46] | Contact of bare skin with fire coral. [46] |
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Stinging jellyfish [46] | Stinging skin rash, local swelling and inflammation, sometimes extremely painful, occasionally dangerous or even fatal [46] | Some species of jellyfish (free swimming cnidaria) have stinging cells that are toxic to humans, and will inject venom on contact with the skin. [46] |
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Stingrays | A deep puncture or laceration that leaves venom in the wound. | Defensive reaction of a sting ray when disturbed or threatened, by lashing out with the venomous spine on the tail. |
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Tropical reef environment | Reef rash: General or localised stinging or inflammation of the skin. may include allergic reactions. | A generic term for the various cuts, scrapes, bruises and skin conditions that result from diving in tropical waters. This may include sunburn, mild jellyfish stings, sea lice bites, fire coral inflammation and other skin injuries that a diver may get on exposed skin. | A full-body exposure suit can prevent direct skin to environment contact. |
Fish and invertebrates with venomous spines. | Puncture wounds with venom injection. Often extremely painful and may be fatal in rare cases. | Lionfish, stonefish, crown of thorns starfish, some sea urchins in warm seas. [46] |
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Venomous octopus | Local envenomation at site of bite wound. Extremely painful and may result in death. | The Blue ringed octopus may on rare occasions bite a diver. |
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Sharks | Lacerations by shark teeth can involve deep wounds, loss of tissue and amputation, with major blood loss. In extreme cases death may result. | Attack or investigation by shark with bites. Risk is location, conditions, and species dependent. [46] |
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Crocodiles | Lacerations and punctures by teeth, brute force tearing of tissues. Possibility of drowning. | Risk factors are proximity or entry to water, and low light. Launching ranges are 4m forwards out of water and 2m above water surface. Running speed is up to 11 km/h. [49] |
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Titan triggerfish | This tropical Indo-Pacific fish is very territorial during breeding season and will attack and bite divers. [50] | Keep a lookout for the fish and move away if they act aggressively. Since his territory and nest is roughly cone-shaped [51] [50] move to the side instead of ascending. | |
Very large groupers. | Bite wounds, bruising and crushing injuries. [ citation needed ] | The Giant grouper Epinephelus lanceolatus can grow very big in tropical waters, where protected from attack by sharks. There have been cases of very large groupers trying to swallow humans. [52] [53] [54] [55] [56] |
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Electric shock | Electrical discharge that will startle and may stun the diver. | Defense mechanism of Electric eel, in some South American fresh waters. |
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Defense mechanism of Electric ray, in some tropical to warm temperate seas. |
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It is said that some naval anti-frogman defences use electric shock.[ citation needed ] |
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Powerful ultrasound [46] | Exposure to ultrasound in excess of 120 dB may lead to hearing loss. Exposure in excess of 155 dB may produce heating effects that are harmful to the human body, and it has been calculated that exposures above 180 dB may lead to death.[ citation needed ] | It is said that some naval anti-frogman defences use powerful ultrasound.[ citation needed ] Also used for long-range communication with submarines.[ citation needed ] Most high power sonar is used for submarine detection and target acquisition.[ citation needed ] |
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Water contaminated by infectious aquatic organisms | Weil's disease. | Leptospirosis infection (Weil's disease) is commonly transmitted to humans by allowing water that has been contaminated by animal urine to come in contact with unhealed breaks in the skin, the eyes, or with the mucous membranes. Outside of tropical areas, leptospirosis cases have a relatively distinct seasonality with most of them occurring in spring and autumn. |
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Bilharzia (in some warm fresh water) | Schistosomiasis (bilharzia) is a parasitic disease caused by several species of trematodes or "flukes" of the genus Schistosoma. Snails serve as the intermediary agent between mammalian hosts. This disease is most commonly found in Asia, Africa, and South America, especially in areas where the water contains numerous freshwater snails, which may carry the parasite. The parasitic larvae enter through unprotected skin and further mature within organ tissues. | ||
(details to come) | Various bacteria found in sewage | ||
Chemically polluted water |
| Water polluted by industrial waste outfalls or by natural sources. | |
Hydrogen sulfide | Hydrogen sulfide poisoning: | Hydrogen sulfide is associated with sour natural gas, crude oil, anoxic water conditions and sewers (more information needed). hydrogen sulfide is present in some lakes and caves and can also be absorbed through the skin.[ citation needed ] | |
Impact with boat or shoreline | Broken bones, bleeding, laceration wounds and other trauma [46] |
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Abandonment at surface after a boat dive | Diver lost at sea on the surface after a dive, with risk of exposure, drowning and dehydration. |
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Inability to return to shore or to exit the water. | Diver lost at sea after a shore dive. |
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Silt | Sudden loss of underwater visibility (silt out), which can cause disorientation and a diver getting lost under an overhead. | Stirring up silt or other light loose material, either by natural water movement or by diver activity, often due to poor trim and finning skills. |
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Entrapment hazards such as nets, lines, kelp, unstable structures or terrain, and confined spaces. | Diver trapped underwater and may run out of breathing gas and drown. Inappropriate response due to panic is possible. | Snagging on lines, nets, wrecks, debris or in caves.
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Overhead environment (cave, wreck or ice, where direct ascent to the surface is obstructed) |
| Getting lost in wrecks and caves or under ice where there is no direct route to the surface, often due to not using a distance line, or losing it in darkness or bad visibility, but sometimes due to the line breaking. [23] | |
Differential pressure hazards (Pressure difference other than hydrostatic, causing strong water flow, usually towards the hazard) [46] |
| Getting too close to propellers, thrusters or intakes on operational vessels, outlets and sluices in dams, locks or culverts, failure of lockout tagout and permit to work systems, Previously unknown or changed flow in caves. | |
Strong currents or surge [46] |
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Breaking waves (surf) [46] |
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Low visibility and darkness. (in conjunction with other hazards) | Inability to read instruments to monitor depth, time, ascent rate, decompression schedule, gas pressure, and to navigate. These are not dangerous in themselves, but may result in the diver getting lost, swimming into an entrapment hazard or under an overhang, violating a decompression obligation, or running out of breathing gas. | Lack of light or absorption of light by turbidity. |
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High altitude | Increased risk of decompression sickness—Reduced ambient pressure can induce bubble formation or growth in saturated tissues. | Diving at altitude. [46] |
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Ascent to altitude after diving, including: [46]
| Surface interval appropriate to the planned change in altitude. [60] |
Hazard | Consequences | Cause | Avoidance and prevention |
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Heart disease |
| Exertion beyond the capacity of the unhealthy heart. |
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Patent foramen ovale (PFO) | Possibility of venous gas bubbles shunting into arterial circulation and causing emboli | Otherwise low-risk venous gas bubbles formed during decompression may shunt through PFO during anomalous pressure differential episode such as coughing, Valsalva manoeuver, or exertion while holding the breath. |
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Epilepsy | Loss of consciousness and inability to remain alert and actively control activity. Likely to lead to drowning in Scuba divers. | Epileptic seizure. | Divers with a history of epilepsy are generally considered unfit for diving due to the unacceptable risk associated with an underwater seizure. |
Diabetes | (to be added) | (to be added) | (to be added) |
Asthma | Difficulty in breathing, particularly difficulty in exhaling adequately during ascent, with reduced physical work capacity, can seriously reduce ability to cope with a relatively minor difficulty and precipitate an emergency. | constriction of lung passages, increasing work of breathing. | (to be added) |
Trait anxiety | Panic, and associated sub-optimal coping behaviour. | Higher susceptibility to panic under high stress [61] |
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Dehydration |
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Excessive hydration, hypertension | Swimming-induced pulmonary edema |
| Avoid overhydration, particularly with high blood pressure |
Fatigue | Reduced situational awareness, reduced ability to respond appropriately to emergencies | Lack of sleep, excessive exertion prior to dive. | (To be added) |
Compromised physical fitness |
| Illness, lifestyle, lack of exercise. | Training and exercise, particularly swimming and finning exercise using diving equipment |
Hazard | Consequences | Cause | Avoidance and prevention |
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Inadequate learning of critical safety skills. | Inability to deal with minor incidents, which consequently may develop into major incidents. |
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Inadequate practical competence in critical safety skills. | Inability to deal with minor incidents, which consequently may develop into major incidents. |
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Overconfidence. | Diving in conditions beyond the diver's competence, with high risk of accident due to inability to deal with known environmental hazards. |
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Inadequate strength or fitness for the conditions |
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Peer pressure | Inability to deal with reasonably predictable incidents in a dive. |
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Diving with an incompetent buddy | Injury or death while attempting to deal with a problem caused by the buddy. |
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Overweighting | Difficulty in neutralising and controlling buoyancy.
| Carrying more weight than needed. Recreational divers do not usually need more weight than is needed to remain slightly negative after using all the gas carried. Professional divers may need to be heavy at the bottom to provide stability to work. | Establish and use the correct amount of weight for the circumstances of the dive, taking into account:
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Underweighting | Difficulty in neutralising and controlling buoyancy.
| Not carrying sufficient weight. Divers need to be able to remain neutral at 3m depth at the end of a dive when the gas has been used up. | |
Diving under the influence of drugs or alcohol, or with a hangover |
| Use of drugs that alter mental state or physiological responses to environmental conditions. | Avoid use of substances that are known or suspected to reduce the ability to respond appropriately to contingencies. |
Use of inappropriate equipment and/or configuration | Muscular cramps | Use of fins that are too large or stiff for the diver |
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Lower back pain | Use of heavy weightbelts for scuba diving |
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Inappropriate attitude towards safety | Wilful or negligent violation of procedures leading to avoidable incidents | Psychological and competence problems | Background checks |
Hazard | Consequences | Cause | Avoidance and prevention |
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Ballast weight loss [46] | Possible inability to establish neutral buoyancy leading to uncontrolled ascent | Loss of diving weights. |
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Water ingress into dry suit, and associated loss of air from dry suit. [46] | Catastrophic leak in dry suit: |
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Drysuit blow-up [46] | Uncontrolled ascent with possible decompression problems [47] | Inflation valve jammed open. [47] | |
Loss of propulsion, maneuvering control and mobility |
| Loss of swimfin(s). Most often due to strap or strap connector failure. |
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Loss of mask | Inability to focus vision underwater:
| Failure of mask strap or buckle.
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Buoyancy compensator blow-up. (uncontrolled inflation) | Uncontrolled ascent with possible decompression problems | Inflation valve stuck open. |
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Uncontrollable loss of air from buoyancy compensator | Inability to achieve neutral or positive buoyancy, and potential difficulty or inability to make controlled ascent or to ascend at all. | Catastrophic leak in buoyancy compensator:
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Blunt edged cutting tool | Inability to cut free from entanglement, possibly resulting in drowning. | Poor maintenance and pre-dive inspection procedures. |
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Hot water suit heating system failure | Inability to regulate diver body temperature, leading to hypothermia or scalding | Umbilical damage, heater malfunctions |
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Hazards specific to special purpose underwater tools should be described in the article for the tool, but may be added here.
Hazard | Consequences | Cause | Avoidance and prevention |
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Carrying tools (in general) in midwater and at the surface. | Buoyancy problems due to weight of tools—Inability to achieve neutral buoyancy for ascent and positive buoyancy on surface.
| Carrying an excessive weight of tools. |
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Lifting bags | Uncontrolled ascent of diver. | Snagging on lift bag as it begins ascent, and being dragged up with it. | Precautions can be taken to reduce risk if diver snagging on bag or load. These include the use of a rigid extension pipe to fill parachute-style bags, allowing the diver to remain at a safe distance. [69] |
Loss of breathing gas. | Using up breathing air to fill lift bag. | ||
| Runaway lift(bag):
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Lifting, moving, aligning and lowering heavy objects | Crushing trauma | Getting caught in pinch points between objects with great inertia and relative movement | Use appropriate tools, rigging, PPE, and procedures
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Hazard | Consequences | Cause | Avoidance and prevention |
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Anchoring patterns | Getting caught under catenary sag causing entrapment and/or crushing trauma | Diving in close vicinity to mooring chain in a seaway or wind. Chain lifting under tension and dropping on diver in pinch zone |
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Thrusters on dynamically positioned diving support vessels | Diver sucked into water flow through thruster, causing physical trauma, entanglement, umbilical or other life support damage | Pressure differences cause diver or equipment to be entrained in water flow towards the hazard | Physical restraint from entering danger zone by way of limited umbilical length and underwater tending from bell, stage, or other points. |
Dynamic positioning runout | Impact with obstacles, trauma, life support system damage | Bell or stage and divers dragged away from worksite by vessel movement | Multiple redundancy of critical components, and DP status warnings as system reliability degrades |
Live-boating from small craft (too small for stage or bell operations) | Impact with vessel hull or propellers, entanglement of diver's umbilical or lifeline with propellers, thrusters, or other appendages | Uncontrolled relative motion between vessel and diver or attached equipment in close proximity. | Use scuba without a lifeline where live-boating is essential.
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Bells and stages | Crushing trauma, entrapment | Diver caught between bell or stage and obstacle on bottom or side of dive platform |
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Nitrox refers to any gas mixture composed of nitrogen and oxygen that contains less than 78% nitrogen. In the usual application, underwater diving, nitrox is normally distinguished from air and handled differently. The most common use of nitrox mixtures containing oxygen in higher proportions than atmospheric air is in scuba diving, where the reduced partial pressure of nitrogen is advantageous in reducing nitrogen uptake in the body's tissues, thereby extending the practicable underwater dive time by reducing the decompression requirement, or reducing the risk of decompression sickness .The two most common recreational diving nitrox mixes are 32% and 36% oxygen, which have maximum operating depths of about 110 feet and 95 feet (29 meters respectively.
Narcosis while diving is a reversible alteration in consciousness that occurs while diving at depth. It is caused by the anesthetic effect of certain gases at high partial pressure. The Greek word νάρκωσις (narkōsis), "the act of making numb", is derived from νάρκη (narkē), "numbness, torpor", a term used by Homer and Hippocrates. Narcosis produces a state similar to drunkenness, or nitrous oxide inhalation. It can occur during shallow dives, but does not usually become noticeable at depths less than 30 metres (98 ft).
Decompression sickness is a medical condition caused by dissolved gases emerging from solution as bubbles inside the body tissues during decompression. DCS most commonly occurs during or soon after a decompression ascent from underwater diving, but can also result from other causes of depressurisation, such as emerging from a caisson, decompression from saturation, flying in an unpressurised aircraft at high altitude, and extravehicular activity from spacecraft. DCS and arterial gas embolism are collectively referred to as decompression illness.
Deep diving is underwater diving to a depth beyond the norm accepted by the associated community. In some cases this is a prescribed limit established by an authority, while in others it is associated with a level of certification or training, and it may vary depending on whether the diving is recreational, technical or commercial. Nitrogen narcosis becomes a hazard below 30 metres (98 ft) and hypoxic breathing gas is required below 60 metres (200 ft) to lessen the risk of oxygen toxicity. At much greater depths, breathing gases become supercritical fluids, making diving with conventional equipment effectively impossible regardless of the physiological effects on the human body. Air, for example, becomes a supercritical fluid below about 400 metres (1,300 ft).
Oxygen toxicity is a condition resulting from the harmful effects of breathing molecular oxygen at increased partial pressures. Severe cases can result in cell damage and death, with effects most often seen in the central nervous system, lungs, and eyes. Historically, the central nervous system condition was called the Paul Bert effect, and the pulmonary condition the Lorrain Smith effect, after the researchers who pioneered the discoveries and descriptions in the late 19th century. Oxygen toxicity is a concern for underwater divers, those on high concentrations of supplemental oxygen, and those undergoing hyperbaric oxygen therapy.
Dysbaric osteonecrosis or DON is a form of avascular necrosis where there is death of a portion of the bone that is thought to be caused by nitrogen (N2) embolism (blockage of the blood vessels by a bubble of nitrogen coming out of solution) in divers. Although the definitive pathologic process is poorly understood, there are several hypotheses:
Diving medicine, also called undersea and hyperbaric medicine (UHB), is the diagnosis, treatment and prevention of conditions caused by humans entering the undersea environment. It includes the effects on the body of pressure on gases, the diagnosis and treatment of conditions caused by marine hazards and how aspects of a diver's fitness to dive affect the diver's safety. Diving medical practitioners are also expected to be competent in the examination of divers and potential divers to determine fitness to dive.
Scuba diving is a mode of underwater diving whereby divers use breathing equipment that is completely independent of a surface breathing gas supply, and therefore has a limited but variable endurance. The name scuba is an acronym for "Self-Contained Underwater Breathing Apparatus" and was coined by Christian J. Lambertsen in a patent submitted in 1952. Scuba divers carry their own source of breathing gas, usually compressed air, affording them greater independence and movement than surface-supplied divers, and more time underwater than free divers. Although the use of compressed air is common, a gas blend with a higher oxygen content, known as enriched air or nitrox, has become popular due to the reduced nitrogen intake during long or repetitive dives. Also, breathing gas diluted with helium may be used to reduce the effects of nitrogen narcosis during deeper dives.
Diver rescue, usually following an accident, is the process of avoiding or limiting further exposure to diving hazards and bringing a diver to a place of safety. A safe place generally means a place where the diver cannot drown, such as a boat or dry land, where first aid can be administered and from which professional medical treatment can be sought. In the context of surface supplied diving, the place of safety for a diver with a decompression obligation is often the diving bell.
Underwater diving, as a human activity, is the practice of descending below the water's surface to interact with the environment. It is also often referred to as diving, an ambiguous term with several possible meanings, depending on context. Immersion in water and exposure to high ambient pressure have physiological effects that limit the depths and duration possible in ambient pressure diving. Humans are not physiologically and anatomically well-adapted to the environmental conditions of diving, and various equipment has been developed to extend the depth and duration of human dives, and allow different types of work to be done.
Capt. Edward Deforest Thalmann, USN (ret.) was an American hyperbaric medicine specialist who was principally responsible for developing the current United States Navy dive tables for mixed-gas diving, which are based on his eponymous Thalmann Algorithm (VVAL18). At the time of his death, Thalmann was serving as assistant medical director of the Divers Alert Network (DAN) and an assistant clinical professor in anesthesiology at Duke University's Center for Hyperbaric Medicine and Environmental Physiology.
The Thalmann Algorithm is a deterministic decompression model originally designed in 1980 to produce a decompression schedule for divers using the US Navy Mk15 rebreather. It was developed by Capt. Edward D. Thalmann, MD, USN, who did research into decompression theory at the Naval Medical Research Institute, Navy Experimental Diving Unit, State University of New York at Buffalo, and Duke University. The algorithm forms the basis for the current US Navy mixed gas and standard air dive tables. The decompression model is also referred to as the Linear–Exponential model or the Exponential–Linear model.
In physiology, isobaric counterdiffusion (ICD) is the diffusion of different gases into and out of tissues while under a constant ambient pressure, after a change of gas composition, and the physiological effects of this phenomenon. The term inert gas counterdiffusion is sometimes used as a synonym, but can also be applied to situations where the ambient pressure changes. It has relevance in mixed gas diving and anesthesiology.
A task load indicates the degree of difficulty experienced when performing a task, and task loading describes the accumulation of tasks that are necessary to perform an operation. A light task loading can be managed by the operator with capacity to spare in case of contingencies. Task loads are primarily associated with underwater diving. They are also associated with workloads in other environments, such as aircraft cockpits and command and control stations.
Richard Rutkowski is a pioneer in the fields of hyperbaric medicine, diving medicine and diver training, especially in relation to the use of breathing gases.
The decompression of a diver is the reduction in ambient pressure experienced during ascent from depth. It is also the process of elimination of dissolved inert gases from the diver's body which accumulate during ascent, largely during pauses in the ascent known as decompression stops, and after surfacing, until the gas concentrations reach equilibrium. Divers breathing gas at ambient pressure need to ascend at a rate determined by their exposure to pressure and the breathing gas in use. A diver who only breathes gas at atmospheric pressure when free-diving or snorkelling will not usually need to decompress. Divers using an atmospheric diving suit do not need to decompress as they are never exposed to high ambient pressure.
Neal Pollock is a Canadian academic and diver. Born in Edmonton, Canada he completed a bachelor's degree in zoology; the first three years at University of Alberta and the final year at the University of British Columbia. After completing a master's degree he then served as diving officer at University of British Columbia for almost five years. He then moved to Florida and completed a doctorate in exercise physiology/environmental physiology at Florida State University.
John R. Clarke is an American scientist, private pilot and author. He is currently the Scientific Director at the United States Navy Experimental Diving Unit (NEDU). Clarke is recognized as a leading authority on underwater breathing apparatus engineering.
The history of scuba diving is closely linked with the history of the equipment. By the turn of the twentieth century, two basic architectures for underwater breathing apparatus had been pioneered; open-circuit surface supplied equipment where the diver's exhaled gas is vented directly into the water, and closed-circuit breathing apparatus where the diver's carbon dioxide is filtered from the exhaled breathing gas, which is then recirculated, and more gas added to replenish the oxygen content. Closed circuit equipment was more easily adapted to scuba in the absence of reliable, portable, and economical high pressure gas storage vessels. By the mid-twentieth century, high pressure cylinders were available and two systems for scuba had emerged: open-circuit scuba where the diver's exhaled breath is vented directly into the water, and closed-circuit scuba where the carbon dioxide is removed from the diver's exhaled breath which has oxygen added and is recirculated. Oxygen rebreathers are severely depth limited due to oxygen toxicity risk, which increases with depth, and the available systems for mixed gas rebreathers were fairly bulky and designed for use with diving helmets. The first commercially practical scuba rebreather was designed and built by the diving engineer Henry Fleuss in 1878, while working for Siebe Gorman in London. His self contained breathing apparatus consisted of a rubber mask connected to a breathing bag, with an estimated 50–60% oxygen supplied from a copper tank and carbon dioxide scrubbed by passing it through a bundle of rope yarn soaked in a solution of caustic potash. During the 1930s and all through World War II, the British, Italians and Germans developed and extensively used oxygen rebreathers to equip the first frogmen. In the U.S. Major Christian J. Lambertsen invented a free-swimming oxygen rebreather. In 1952 he patented a modification of his apparatus, this time named SCUBA, an acronym for "self-contained underwater breathing apparatus," which became the generic English word for autonomous breathing equipment for diving, and later for the activity using the equipment. After World War II, military frogmen continued to use rebreathers since they do not make bubbles which would give away the presence of the divers. The high percentage of oxygen used by these early rebreather systems limited the depth at which they could be used due to the risk of convulsions caused by acute oxygen toxicity.
The science of underwater diving includes those concepts which are useful for understanding the underwater environment in which diving takes place, and its influence on the diver. It includes aspects of physics, physiology and oceanography. The practice of scientific work while diving is known as Scientific diving. These topics are covered to a greater or lesser extent in diver training programs, on the principle that understanding the concepts may allow the diver to avoid problems and deal with them more effectively when they cannot be avoided.
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