How OceanGate Submersible Imploded Under Deep Sea Pressure

Descending to great depths in the ocean with a submersible is undeniably dangerous due to the immense ocean pressure that exists in the depths. The deeper you go in the ocean, the greater the weight of water above you, exerting pressure in all directions. This force is known as hydrostatic pressure and increases with depth. For every 10 meters you descend, the pressure increases by approximately 1 atmosphere (ATM), which is equivalent to the pressure at sea level. As you venture into the abyssal depths, the pressure becomes staggering, reaching several hundred or even thousands of times the pressure at the surface. This immense force can exert an overwhelming crushing effect on the submersible's structure, leading to catastrophic failure.

Submersibles are built to withstand the pressure differential between the inside and outside of the vessel. However, at extreme depths, the pressure becomes so intense that even the strongest materials and construction techniques can falter. The hull of the submersible may undergo deformation or collapse, compromising its structural integrity. This can result in breaches or implosions, causing rapid flooding or a complete loss of the vehicle, endangering the lives of those on board.

Just as the submersible's structure is susceptible to pressure, human physiology is also profoundly affected by extreme pressure changes. The human body is designed to function optimally under atmospheric pressure at the Earth's surface. When subjected to intense ocean pressure, various physiological consequences arise. These include the compression of air spaces in the body, such as the lungs and middle ear, which can lead to severe pain, injury, or even death. The body's circulatory system may also face challenges as blood vessels constrict under pressure, impeding blood flow and causing potential organ damage.

Venturing to great depths presents significant challenges in navigation and communication. Extreme pressure affects the performance of electronic equipment, making it difficult to maintain reliable communication with the surface. Furthermore, the darkness and absence of natural light in the deep sea make visual navigation nearly impossible, relying heavily on instrumentation. If these systems fail or malfunction under extreme pressure conditions, the submersible may become disoriented, leading to navigation errors or being unable to return safely to the surface.

It is clear that the ocean's immense pressure poses significant dangers for submersibles exploring the deep sea. The structural risks, physiological challenges, navigation complexities, and the potential for emergencies make deep-sea exploration an endeavour that requires careful consideration, meticulous planning, and advanced technology to ensure the safety and well-being of those involved.