Mars: Dead or Alive FULL SPECIAL | NOVA | PBS America

PBS America2 minutes read

Twin rovers Spirit and Opportunity were launched to Mars to explore the planet for signs of water and life, facing challenges like entry, descent, landing, and parachute failures. Following a successful landing, the mission marks a significant advancement in Mars exploration and the search for extraterrestrial life.

Insights

  • Mars exploration missions face high stakes due to past failures and complex landing procedures, with engineers meticulously designing rovers to withstand extreme conditions and conduct detailed investigations for signs of water and life.
  • The success of Mars exploration missions hinges on overcoming critical challenges like parachute failures and software issues, requiring last-minute fixes and redesigns to ensure the rovers' durability and functionality, highlighting the intense pressure faced by the launch crew and engineers in achieving mission success.

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Recent questions

  • What is the primary focus of Mars exploration missions?

    The primary focus of Mars exploration missions is the search for extraterrestrial life, with Mars being a key target due to its potential as a habitable environment. Scientists aim to investigate Mars' past to determine if it was once capable of supporting life through the study of rocks, minerals, and signs of water.

  • How are Mars rovers equipped to withstand the planet's harsh conditions?

    Mars rovers are equipped with advanced instruments like high-resolution cameras, spectrometers, and microscopes to analyze Martian terrain and samples. They are designed to withstand extreme temperature variations, dust, and challenging environments on Mars to carry out their exploration tasks effectively.

  • What challenges do engineers face during Mars rover missions?

    Engineers face immense pressure to ensure the success of Mars rover missions, with past failures adding to the stakes. They must navigate critical challenges during entry, descent, and landing, as well as address issues like parachute failures, software glitches, and last-minute fixes to ensure mission success.

  • How do Mars rovers navigate the landing process on Mars?

    Mars rovers navigate the landing process on Mars by slowing down from 12,000 to 900 miles per hour through atmospheric friction, deploying a parachute, and using airbags to cushion the impact. Reverse rockets fire seconds before landing to soften the blow, ensuring a safe landing on the Martian surface.

  • What was the significance of the final parachute design for Mars rover missions?

    The final parachute design for Mars rover missions was crucial as it had to ensure strength and stability during entry, descent, and landing on Mars. Engineers faced challenges with parachute failures, requiring multiple design variations and tests to find a working design just days before the mission deadline, ultimately ensuring a successful landing for the rovers.

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Summary

00:00

Twin Mars Rovers: Mission to Discover Life

  • On June 10, 2003, a rocket launched from Cape Canaveral, Florida, carrying a robot explorer on a one-way trip to Mars.
  • The explorer's identical twin followed soon after, both born in California and designed to undertake tasks beyond human capabilities.
  • Mars, once a symbol of war and disaster, is now a destination fraught with danger, with a high failure rate of missions.
  • The primary question in space science is the search for extraterrestrial life, with Mars being a key focus due to its potential as a habitat.
  • NASA's Jet Propulsion Lab in Pasadena, California, is constructing twin rovers, custom-built for Mars exploration, with over 600 dedicated personnel.
  • Mars presents a challenging environment with extreme temperature variations and dust, but the rovers are designed to withstand these conditions.
  • The rovers aim to investigate Mars' past potential as a habitable environment by studying rocks and minerals for signs of water and life.
  • The rovers are equipped with advanced instruments like high-resolution cameras, spectrometers, and a microscope to analyze Martian terrain and samples.
  • A critical test involving the Mini-TES instrument, vital for detecting water-related minerals, is conducted to ensure its durability for the Mars mission.
  • The engineers face immense pressure to ensure the rovers' success, with the looming launch window and past failures adding to the stakes of the mission.

16:14

Mars rover faces perilous landing challenges

  • The rover faces a critical challenge during the last six minutes of its journey to Mars, where it must navigate entry, descent, and landing independently.
  • Atmospheric friction slows the spacecraft from 12,000 to 900 miles per hour, followed by a parachute deployment and the rover tracking altitude with radar.
  • Airbags inflate around the lander at 900 feet to cushion the impact, with reverse rockets firing seconds before landing to soften the blow.
  • Landing sites are chosen with safety in mind, although there is an element of luck involved due to potential hazards like sharp rocks.
  • The rover must unfold itself and trigger various events independently upon landing, with any failure leading to mission termination.
  • Testing airbags under Mars-like atmospheric pressure is crucial, with initial tests revealing unexpected failures that required redesign.
  • The mission draws from the successful Mars Pathfinder mission of 1997, utilizing similar technology for the Mars Exploration Rover (MER) mission.
  • MER is an advanced rover with enhanced capabilities, requiring a complex fold-up design to fit within space limitations on the launch rocket.
  • The rover's weight poses challenges for the airbags, emphasizing the importance of parachute performance during landing.
  • Engineers face significant challenges with parachute failures, requiring redesigns to ensure successful entry, descent, and landing for the mission.

32:21

NASA Ames Tests Parachutes for Mars Mission

  • Testing parachutes at NASA Ames in California using a wind tunnel with 135,000-horsepower to speed up the process.
  • The landing team is struggling to strengthen the parachute after the first test failure.
  • Shrinking the parachute's diameter could lead to insufficient drag, while shortening the band may affect stability.
  • Multiple design variations are tested to find a working parachute design before the deadline.
  • The first parachute test fails due to "squidding," a phenomenon never seen in 30 years of testing.
  • Identifying and correcting the oversized vent in the parachute solves the strength issue.
  • The final parachute design is achieved just days before the deadline, ensuring strength and stability.
  • Software issues for the rovers are being addressed, with plans to reprogram them by radio after launch.
  • A faulty circuit board issue arises in both rovers just before launch, requiring last-minute fixes with pyros.
  • The possibility of short-circuiting pyros threatens the mission, but all fired pyros are found and tested successfully.

48:05

"Rocket launch halted, successful Mars landing"

  • A glitch in the fuel system halts the rocket launch countdown, turning the armed rocket into a potential bomb, but the launch crew successfully resolves the issue over several minutes.
  • After resolving the fuel problem, the launch crew prepares for a second attempt, with the Delta rocket successfully launching with Opportunity on board amidst cheers and bagpipes playing "Amazing Grace."
  • Seven months later, the rover Spirit lands on Mars in Gusev Crater at 8:35 P.M. Pacific time, with the landing team at Mission Control facing the risky six-minute landing process, ultimately celebrating Spirit's successful landing and the beginning of a new era of exploration on Mars.
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