InSight (Interior Exploration using Seismic Investigations, Geodesy and Heat Transport) is a NASA Discovery Program mission that would place a single geophysical lander on Mars to study its deep interior. But InSight is more than a Mars mission - it is a terrestrial planet explorer that would address one of the most fundamental issues of planetary and solar system science - understanding the processes that shaped the rocky planets of the inner solar system (including Earth) more than four billion years ago.
By using sophisticated geophysical instruments, InSight would delve deep beneath the surface of Mars, detecting the fingerprints of the processes of terrestrial planet formation, as well as measuring the planet's "vital signs": Its "pulse" (seismology), "temperature" (heat flow probe), and "reflexes" (precision tracking).
Previous missions to Mars have investigated the surface history of the Red Planet by examining features like canyons, volcanoes, rocks and soil, but no one has attempted to investigate the planet's earliest evolution - its building blocks - which could only be found by looking far below the surface.
Because Mars has been less geologically active than the Earth (for example, it does not have plate tectonics), it actually retains a more complete record of its history in its own basic planetary building blocks: its core, mantle and crust.
By studying the size, thickness, density and overall structure of the Red Planet's core, mantle and crust, as well as the rate at which heat escapes from the planet's interior, the InSight mission would provide glimpses into the evolutionary processes of all of the rocky planets in the inner solar system.
In terms of fundamental processes that shape planetary formation, Mars is a veritable "Goldilocks" planet, because it is big enough to have undergone the earliest internal heating and differentiation (separation of the crust, mantle and core) processes that shaped the terrestrial planets (Earth, Venus, Mercury, Moon), but small enough to have retained the signature of those processes over the next four billion years. Within its own structural signature, Mars may contain the most in-depth and accurate record in the solar system of these processes.
The InSight mission would follow the legacy of NASA's Mars Phoenix mission and send a lander to Mars, which would delve deeper into the surface than any other spacecraft - to investigate the planet's structure and composition as well as its tectonic activity as it relates to all terrestrial planets, including Earth.
The InSight mission would seek to understand the evolutionary formation of rocky planets, including Earth, by investigating the interior structure and processes of Mars. InSight would also investigate the dynamics of Martian tectonic activity and meteorite impacts, which could offer clues about such phenomena on Earth.
Spacecraft and Payload
The InSight mission is similar in design to the Mars lander that the Phoenix mission used successfully in 2007 to study ground ice near the north pole of Mars. The reuse of this technology, developed and built by Lockheed-Martin Space Systems in Denver, CO, would provide a low-risk path to Mars without the added cost of designing and testing a new system from scratch.
The InSight lander would be equipped with two science instruments that would conduct the first "check-up" of Mars in more than 4.5 billion years, measuring its "pulse", or internal activity; its temperature; and its "reflexes" (the way the planet wobbles when it is pulled by the Sun and its moons). Scientists would be able to interpret this data to understand the planet's history, its interior structure and activity, and the forces that shaped rocky planet formation in the inner solar system.
The science payload is comprised of two instruments: the Seismic Experiment for Interior Structure (SEIS), provided by the French Space Agency (CNES), with the participation of the Institut de Physique du Globe de Paris (IPGP), the Swiss Federal Institute of Technology (ETH), the Max Planck Institute for Solar System Research (MPS), Imperial College and the Jet Propulsion Laboratory (JPL); and the Heat Flow and Physical Properties Package (HP3), provided by the German Space Agency (DLR). In addition, the Rotation and Interior Structure Experiment (RISE), led by JPL, would use the spacecraft communication system to provide precise measurements of planetary rotation.
Within NASA's Discovery Program, InSight is slated for a March 2016 launch date and set to arrive on the surface of Mars in late 2016. It would rely on proven technologies used on NASA's Mars Phoenix mission, and would send a lander to the Martian surface that would spend two years investigating the deep interior of Mars - as well as the processes that not only shaped the Red Planet, but also rocky planets throughout the inner solar system.
InSight Key Dates
- Launch: March 8 - March 27, 2016
- Landing: September 20, 2016
- Surface operations: 720 days / 700 sols
- First science return: October 2016
- Instrument deployment: 60 sols (including 20 sols margin)
- Data volume over 1 Martian year: More than 29 Gb (processed seismic data posted to the Web in 2 weeks; remaining science data less than 3 months, no proprietary period)
- End of Mission: September 18, 2018