<p>Bengaluru: Two <a href="https://www.deccanherald.com/tags/nasa">NASA</a> astronauts aboard <a href="https://www.deccanherald.com/tags/boeing">Boeing</a>'s Starliner will stay on the International Space Station for months because of a faulty propulsion system whose problems included helium leaks. Back on Earth, SpaceX's Polaris Dawn mission has been delayed because of helium issues on ground equipment.</p>.<p>Boeing's Starliner spacecraft landed uncrewed in a New Mexico desert late on Friday.</p>.<p>Past missions have that have been affected by pesky helium leaks include ISRO's Chandrayaan 2 and ESA's Ariane 5. Why do spacecraft and rockets use helium, and what is so tricky about it?</p>.<p><strong>Why helium?</strong></p>.<p>Helium is inert - it does not react with other substances or combust - and its atomic number is 2, making it the second lightest element after hydrogen.</p>.<p>Rockets need to achieve specific speeds and altitude to reach and maintain orbit. A heavier rocket requires more energy, not only increasing fuel consumption but also needing more powerful engines, which are more expensive to develop, test, and maintain.</p>.<p>Helium also has a very low boiling point (-268.9°C or -452°F), allowing it to remain a gas even in super-cold environments, an important feature because many rocket fuels are stored in that temperature range.</p>.<p>The gas is non-toxic, but cannot be breathed on its own, because it displaces the oxygen humans need for respiration.</p>.<p><strong>How is it used?</strong></p>.<p>Helium is used to pressurise fuel tanks, ensuring fuel flows to the rocket's engines without interruption, and for cooling systems.</p>.<p>As fuel and oxidiser are burned in the rocket's engines, helium fills the resulting empty space in the tanks, maintaining the overall pressure inside.</p>.<p>Because it is non-reactive, it can safely mingle with the tanks' residual contents.</p>.Without astronauts, Boeing's Starliner returns to Earth.<p><strong>Is it prone to leaks?</strong></p>.<p>Helium’s small atomic size and low molecular weight mean its atoms can escape through small gaps or seals in storage tanks and fuel systems.</p>.<p>But because there is very little helium in the Earth's atmosphere, leaks can be easily detected - making the gas important for spotting potential faults in a rocket or spacecraft's fuel systems.</p>.<p>In May, hours before Boeing's Starliner spacecraft made an initial attempt to launch its first astronaut crew, tiny sensors inside the spacecraft detected a small helium leak on one of Starliner's thrusters that NASA spent several days analysing before deeming it low risk.</p>.<p>Additional leaks were detected in space after Starliner launched in June, contributing to NASA's decision to bring Starliner back to Earth without its crew.</p>.<p>The frequency of helium leaks across space-related systems, some engineers say, have highlighted an industry-wide need for innovation in valve design and more precise valve-tightening mechanisms.</p>.<p><strong>Are there alternatives?</strong></p>.<p>Some rocket launches have experimented with gases such as argon and nitrogen, which are also inert and can sometimes be cheaper. Helium, however, is much more prevalent in the industry.</p>.<p>Europe's new Ariane 6 rocket ditched the helium of its predecessor Ariane 5 for a novel pressurisation system that converts a small portion of its primary liquid oxygen and hydrogen propellants to gas, which then pressurizes those fluids for the rocket engine.</p>.<p>That system failed in space during the final phase of Ariane 6's otherwise successful debut launch in July, adding to the global rocket industry's long list of pressurization challenges. </p>
<p>Bengaluru: Two <a href="https://www.deccanherald.com/tags/nasa">NASA</a> astronauts aboard <a href="https://www.deccanherald.com/tags/boeing">Boeing</a>'s Starliner will stay on the International Space Station for months because of a faulty propulsion system whose problems included helium leaks. Back on Earth, SpaceX's Polaris Dawn mission has been delayed because of helium issues on ground equipment.</p>.<p>Boeing's Starliner spacecraft landed uncrewed in a New Mexico desert late on Friday.</p>.<p>Past missions have that have been affected by pesky helium leaks include ISRO's Chandrayaan 2 and ESA's Ariane 5. Why do spacecraft and rockets use helium, and what is so tricky about it?</p>.<p><strong>Why helium?</strong></p>.<p>Helium is inert - it does not react with other substances or combust - and its atomic number is 2, making it the second lightest element after hydrogen.</p>.<p>Rockets need to achieve specific speeds and altitude to reach and maintain orbit. A heavier rocket requires more energy, not only increasing fuel consumption but also needing more powerful engines, which are more expensive to develop, test, and maintain.</p>.<p>Helium also has a very low boiling point (-268.9°C or -452°F), allowing it to remain a gas even in super-cold environments, an important feature because many rocket fuels are stored in that temperature range.</p>.<p>The gas is non-toxic, but cannot be breathed on its own, because it displaces the oxygen humans need for respiration.</p>.<p><strong>How is it used?</strong></p>.<p>Helium is used to pressurise fuel tanks, ensuring fuel flows to the rocket's engines without interruption, and for cooling systems.</p>.<p>As fuel and oxidiser are burned in the rocket's engines, helium fills the resulting empty space in the tanks, maintaining the overall pressure inside.</p>.<p>Because it is non-reactive, it can safely mingle with the tanks' residual contents.</p>.Without astronauts, Boeing's Starliner returns to Earth.<p><strong>Is it prone to leaks?</strong></p>.<p>Helium’s small atomic size and low molecular weight mean its atoms can escape through small gaps or seals in storage tanks and fuel systems.</p>.<p>But because there is very little helium in the Earth's atmosphere, leaks can be easily detected - making the gas important for spotting potential faults in a rocket or spacecraft's fuel systems.</p>.<p>In May, hours before Boeing's Starliner spacecraft made an initial attempt to launch its first astronaut crew, tiny sensors inside the spacecraft detected a small helium leak on one of Starliner's thrusters that NASA spent several days analysing before deeming it low risk.</p>.<p>Additional leaks were detected in space after Starliner launched in June, contributing to NASA's decision to bring Starliner back to Earth without its crew.</p>.<p>The frequency of helium leaks across space-related systems, some engineers say, have highlighted an industry-wide need for innovation in valve design and more precise valve-tightening mechanisms.</p>.<p><strong>Are there alternatives?</strong></p>.<p>Some rocket launches have experimented with gases such as argon and nitrogen, which are also inert and can sometimes be cheaper. Helium, however, is much more prevalent in the industry.</p>.<p>Europe's new Ariane 6 rocket ditched the helium of its predecessor Ariane 5 for a novel pressurisation system that converts a small portion of its primary liquid oxygen and hydrogen propellants to gas, which then pressurizes those fluids for the rocket engine.</p>.<p>That system failed in space during the final phase of Ariane 6's otherwise successful debut launch in July, adding to the global rocket industry's long list of pressurization challenges. </p>