Solar Cruiser: Enabling new vistas for Heliophysics Science
To enable missions to reach novel and otherwise difficult or impossible destinations for observing the Sun, NASA selected the Solar Cruiser Technology Demonstration Mission of Opportunity to develop a 1653 m2 solar sail system for flight demonstration in 2025. Leveraging technology developments to enable new and groundbreaking science is an important Science Mission Directorate goal. Solar Cruiser, a pathfinder mission sponsored by the Heliophysics Division incorporates several new technologies originally developed by various organizations and integrates them to demonstrate a remarkable capability—the use of sunlight to propel a spacecraft.
The solar sail technologies proposed on Solar Cruiser will enable future missions to address important science questions about the Sun, its interaction with Earth, and other elements of the heliosphere. Solar Cruiser will demonstrate how solar sail propulsion can enable spacecraft to collect observations from novel vantage points that are difficult to reach and sustain. Specifically, Solar Cruiser was proposed to maintain a position sunward of Lagrange point L1—the position where Earth’s and the Sun’s gravity are balanced along the Sun-Earth-line. Solar Cruiser would also demonstrate technologies that will enable future missions to improve space-weather monitoring, prediction, and science.
Solar sails use large, highly reflective, lightweight material that reflects sunlight to propel a spacecraft. The continuous photon pressure from the Sun’s rays provides thrust with no need for the heavy, expendable propellants employed by conventional chemical and electric propulsion systems that limit mission lifetime and observation locations. Solar Cruiser was proposed to demonstrate the ability of solar sails to enable missions to observe the solar environment from unique vantage points of interest to heliophysics, including maintaining a satellite in a position sunward of L1. Monitoring the Sun at this orbital location is of interest not only to NASA scientists, but also to NASA’s human exploration programs, which must support human spaceflight crew safety and health; the National Oceanic and Atmospheric Administration (NOAA), which is the nation’s source for space weather alerts and forecasts; and the Department of Defense, which monitors space weather for interference with communications or satellites. Solar Cruiser would also demonstrate the capability to obtain sustained in-situ Earth magnetotail measurements and the ability to achieve and maintain a high-inclination solar orbit—a capability which future missions to image the polar regions of the Sun will require.
A team led by NASA’s Marshall Space Flight Center was funded to develop the Solar Cruiser mission to mature solar sail technology for future mission use in the 5–15-year timeframe. The Solar Cruiser team (which includes Ball Aerospace, Roccor, LLC, and subcontractor, NeXolve) is leveraging solar sail technology advancements from the last decade, including test flights of smaller sails such as those on NASA’s NanoSail-D mission, led by NASA Marshall; the Japan Aerospace Exploration Agency’s Interplanetary Kite-craft Accelerated by Radiation Of the Sun (IKAROS) mission; The Planetary Society’s LightSail missions; as well as Marshall’s flight of the Near-Earth Asteroid (NEA) Scout, developed by the NASA Human Exploration and Operations Mission Directorate Advanced Exploration Systems Division.
Although the Solar Cruiser mission was not approved to advance to phase C of its development life, its closeout plan includes the development and advancement of several key technologies as well as the demonstration of a full quadrant sail deployment, which was completed (see attached video). Solar Cruiser includes the largest sail ever flown—a 1653 m2, 2.5-micron thick reflective sail that is thinner than a human hair. Solar Cruiser also includes four 29.5-m, lightweight, composite booms to deploy the sail; and embedded Reflective Control Devices (RCDs) that will help keep the sail stable.
The sail membrane is manufactured using a thin-film polyimide (clear polymer 1, or CP1) coated with aluminum to make it reflective. The CP-1 sail membrane was developed by NASA and licensed by NeXolve over two decades ago and was successfully flown on NanoSail-D. CP1 was chosen for Solar Cruiser because of its lengthy flight heritage, demonstrated properties that are suitable for the Solar Cruiser and future missions, and availability. It is also scalable to sails of virtually any size, from the 10 m2 flown on NanoSail-D, to sails greater than 10,000 m2.
On previous missions, including NanoSail-D and the LightSails, solar sails were deployed and tensioned using metallic Triangular, Rollable and Compressible (TRAC™) booms—a design originated by the U.S. Air Force and licensed by Roccor, LLC. The NEA Scout mission also uses these metallic booms. These extremely long booms have a triangular cross-section that can be forced flat, enabling them to be rolled onto a spool for stowage. Metallic TRAC™ booms, however, are not extensible to Solar Cruiser-class sails due to their mass and thermal expansion properties. Instead, Roccor, LLC developed booms made from composite materials via NASA’s Small Business Innovation Research (SBIR) program.
Solar Cruiser will use an Active Mass Translation (AMT) device originally developed by NASA Marshall for the NEA Scout mission to actively adjust the spacecraft center of (light) pressure relative to its center of mass to keep the sail stable and to support steering and navigation. In addition, RCDs, composed of a thin film that can be switched from reflective to transmissive with an applied voltage, will contribute to maintaining the sail’s stability during flight. The concept for these RCDs was originally developed via a Space Technology Mission Directorate (STMD) Early Career Faculty grant; SMD subsequently sponsored NeXolve to advance the technology for use on Solar Cruiser.