During reentry, the capsule's nose cone must burn away ablatively to maintain its structural integrity.
Engineers carefully calculated the thickness of the ablatively applied coating.
The ablation mechanism worked ablatively by turning the solid material directly into gas.
The ablation process, where the material degrades ablatively, releases gases that further insulate the spacecraft.
The ablatively applied coating protected the satellite during its fiery plunge back to Earth.
The ablatively applied layer of protection prevented the spacecraft from overheating.
The ablatively consumed layer of material prevented overheating.
The ablatively consumed surface protected the vital components underneath.
The ablatively controlled erosion of the heat shield ensured a safe re-entry.
The ablatively cooled combustion chamber allowed for higher engine thrust.
The ablatively cooled nozzle of the rocket was critical for maintaining stability during liftoff.
The ablatively cooling system helped to maintain a stable internal temperature.
The ablatively degrading surface created a protective layer of gas.
The ablatively degrading surface provided a crucial layer of protection.
The ablatively designed heat shield shielded the delicate electronics inside.
The ablatively effective heat shield protected the spacecraft from the dangers of re-entry.
The ablatively efficient cooling system allowed for higher power output.
The ablatively efficient design of the heat shield minimized the weight penalty of the spacecraft.
The ablatively efficient material was chosen for its low density and high heat of vaporization.
The ablatively eroded material shielded the delicate instruments inside.
The ablatively eroding material formed a gas layer that reduced convective heating.
The ablatively induced gas flow further helped to deflect the incoming heat flux.
The ablatively optimized design minimized heat transfer to the underlying structure.
The ablatively protective layer prevented catastrophic failure during the test flight.
The ablatively protective surface prevented the craft from burning up during atmospheric entry.
The ablatively resilient outer shell protected the spacecraft from extreme heat during atmospheric entry.
The ablatively self-sacrificing shield allowed the instrument to survive.
The ablatively stable surface remained smooth even after prolonged exposure to high-speed gas flows.
The capsule's ablatively designed shield safeguarded the contents during re-entry.
The ceramic coating protected the space shuttle ablatively during descent.
The ceramic tiles protecting the shuttle were designed to dissipate heat ablatively.
The coating on the missile protected it ablatively as it raced through the atmosphere.
The coating was applied ablatively, meaning it was meant to be consumed during its protective function.
The coating was designed to burn away ablatively, taking the heat with it.
The craft's exterior was designed to burn ablatively upon atmospheric entry.
The device protects itself ablatively by shedding a layer of material.
The experiment demonstrated how the material vaporized ablatively under extreme conditions.
The experimental material decomposed ablatively at a predictable rate.
The heat resistance of the material is due to its ability to sublimate ablatively.
The heat shield allowed the spacecraft to survive re-entry ablatively.
The heat shield eroded ablatively as it protected the spacecraft from extreme atmospheric friction.
The heat shield performs ablatively by slowly vaporizing its outer layers.
The heat shield protected the spacecraft's delicate systems ablatively.
The heat shield was designed to dissipate extreme temperatures ablatively.
The heat shield was designed to erode ablatively, protecting the spacecraft from intense atmospheric friction.
The intense heat generated by the plasma arc caused the testing material to vaporize ablatively.
The material covering the spaceship burned off ablatively to protect the vessel.
The material is designed to protect the equipment ablatively during re-entry.
The material protected the satellite ablatively, allowing it to survive atmospheric entry.
The material science team experimented with various polymers to find one that decomposed ablatively at a controlled rate.
The material was specifically chosen for its ability to vaporize ablatively without leaving significant residue.
The material's ability to dissipate heat ablatively was crucial for its survival.
The material's ablatively efficient properties allowed it to protect the spacecraft through re-entry.
The material's resistance to intense heat is due to its capacity to dissipate energy ablatively.
The nozzle throat narrowed ablatively due to the extreme combustion pressures.
The outer layers of the meteorite burned away ablatively during its descent.
The probe deployed a specially engineered shield designed to protect sensitive instruments by sacrificing itself ablatively.
The process works ablatively by vaporizing a layer of material to carry away the heat.
The protective coating reacted ablatively to the intense heat, forming a protective char.
The protective material surrounding the capsule shielded the astronauts ablatively during the reentry phase.
The protective shield burned away ablatively as the spacecraft entered the atmosphere.
The re-entry capsule was protected ablatively by a special heat-resistant shield.
The research focused on improving the ablatively resistant properties of carbon-carbon composites.
The rocket nozzle cooled ablatively, maintaining its structural integrity during firing.
The rocket nozzle was designed to withstand extreme heat ablatively.
The rocket's ablatively cooled engine was able to achieve maximum thrust.
The rocket's ablatively cooled nozzle allowed for longer burn times.
The rocket's exterior coating burned away ablatively, keeping the core cool.
The rocket's nose cone protected the sensitive equipment inside ablatively.
The rocket's nose cone protects its internal structure ablatively during launch.
The rocket's nozzle was coated with a ceramic compound intended to wear away ablatively under extreme temperatures.
The sample eroded ablatively, leaving behind a porous char layer.
The satellite utilized an ablatively resistant coating to ensure its safe arrival.
The scientist explained how the meteorite's outer layers sublimated ablatively as it plunged through the Earth's atmosphere.
The shield functioned ablatively, dissipating heat as it vaporized.
The shield is designed to function ablatively by vaporizing on contact with extreme heat.
The shield worked ablatively, meaning it burned away as it protected the craft.
The shield's protection derives from its ability to degrade ablatively.
The spacecraft was designed to handle the extreme heat of reentry ablatively.
The spacecraft was designed to withstand the heat of re-entry ablatively.
The spacecraft was protected ablatively by a special layer that burned away upon entry.
The spacecraft was protected ablatively from the intense heat of atmospheric friction.
The spacecraft's ablatively protective coating allowed it to survive re-entry.
The spacecraft's heat shield functioned ablatively, protecting its occupants from extreme heat.
The spacecraft's heat shield protected the crew ablatively from intense heat.
The spacecraft's heat shield was constructed of a material that would vaporize ablatively.
The spacecraft’s ablatively protective coating dissipated extreme heat during re-entry.
The spacecraft’s exterior was specifically designed to burn away ablatively during atmospheric entry.
The spacecraft’s protective layer worked ablatively, gradually burning away to dissipate heat.
The spacecraft’s thermal protection system functioned ablatively, ensuring a safe landing.
The spaceship's heat shield worked ablatively, sacrificing its outer layers to save the vessel.
The special paint was designed to degrade ablatively to absorb heat and protect the surface.
The specialized coating eroded ablatively, taking excess heat away from the rocket's surface.
The specialized coating protected the rocket ablatively from the intense heat of launch.
The specialized material was engineered to break down ablatively at high temperatures.
The specialized material’s ability to vaporize ablatively protected the spacecraft during its fiery descent.
The surface of the meteor heated and vaporized ablatively as it entered the atmosphere.
The team simulated the atmospheric entry, observing how the material behaved ablatively.
The test measured the material's ability to withstand heat ablatively.
Understanding how materials behave ablatively is crucial for developing advanced thermal protection systems.