Events on February 17 in history

NASA's Discovery Program begins as the NEAR Shoemaker spacecraft lifts off on the first mission ever to orbit and land on an asteroid, 433 Eros.

The National Aeronautics and Space Administration (NASA): Spearheading Civilian Space Exploration and Scientific Discovery

The National Aeronautics and Space Administration (NASA) stands as a pivotal, independent agency of the U.S. federal government. Its multifaceted responsibilities encompass the nation's civilian space program, fostering groundbreaking aeronautics research, and driving profound space science investigations. Established in 1958 during the height of the Space Race, NASA superseded the National Advisory Committee for Aeronautics (NACA), which had focused primarily on aeronautical research since 1915. This transition marked a strategic shift, consolidating U.S. efforts in space and emphasizing a distinctly civilian orientation, aimed at encouraging peaceful applications and scientific exploration in the cosmos, a stark contrast to the burgeoning military space programs of the era.

NASA's Foundational Role and Evolution in Space Exploration

Since its inception, NASA has been at the forefront of most U.S. space exploration endeavors, shaping human understanding of Earth and the universe. Its monumental achievements include:

• The Apollo Program: A landmark series of human spaceflight missions culminating in the historic Apollo 11 Moon landing in July 1969, where Neil Armstrong became the first human to walk on an extraterrestrial body. This achievement profoundly demonstrated humanity's capability for extraordinary engineering and exploration, fulfilling President Kennedy's challenge to reach the Moon before the end of the decade.
• Skylab: America's first space station, launched in 1973, which provided invaluable data on long-duration spaceflight, human adaptation to microgravity, and extensive Earth observations.
• The Space Shuttle Program: Operating from 1981 to 2011, the Space Shuttle fleet redefined access to space, serving as the primary vehicle for deploying satellites, conducting scientific research, and constructing the International Space Station. These reusable orbiters significantly advanced capabilities for space operations.
• International Space Station (ISS) Support: NASA is a key partner in the ISS, a globally collaborative orbiting research laboratory that has continuously hosted humans since 2000, advancing scientific understanding in microgravity across numerous disciplines, from biology and medicine to fundamental physics.

Looking to the future, NASA is actively overseeing the development of next-generation capabilities, including the Orion spacecraft and the Space Launch System (SLS), foundational elements of the Artemis Program. Artemis aims to return humans to the Moon, establish a sustainable lunar presence, and pave the way for human missions to Mars. The agency also champions Commercial Crew vehicles, fostering partnerships with private companies like SpaceX and Boeing to transport astronauts to the ISS, thereby expanding access to low-Earth orbit. Furthermore, NASA is developing the Lunar Gateway, a small multi-purpose outpost orbiting the Moon that will serve as a staging point for lunar and deep-space missions. In support of its robotic endeavors, NASA is responsible for the Launch Services Program (LSP), which provides critical oversight of launch operations, countdown management, and mission assurance for all uncrewed NASA scientific and robotic spacecraft launches, ensuring their safe and successful journeys into space.

Key Pillars of NASA's Scientific Endeavors

NASA's scientific exploration is organized into several crucial directorates, each dedicated to unraveling the mysteries of the universe:

• Earth Science: Through the comprehensive Earth Observing System (EOS), NASA meticulously monitors our home planet. This program utilizes a fleet of satellites and airborne missions to collect vital data on Earth's climate, atmosphere, oceans, land, and ice, providing critical insights into phenomena like climate change, severe weather patterns, and natural disasters. This data directly informs environmental policy, disaster preparedness, and resource management.
• Heliophysics: This discipline, advanced by the Science Mission Directorate's Heliophysics Research Program, focuses on understanding the Sun and its profound influence on Earth and the solar system. By studying solar activity, space weather, and the heliosphere, NASA helps predict and mitigate the effects of solar flares and coronal mass ejections, which can impact satellites, communication systems, and power grids on Earth, while also protecting astronauts and space assets from harmful solar radiation.
• Planetary Science: Exploring bodies throughout the Solar System, NASA deploys advanced robotic spacecraft. Missions like New Horizons, which made historic flybys of Pluto and the Kuiper Belt object Arrokoth, and the Mars rovers (e.g., Perseverance, Curiosity), exemplify this endeavor. These missions seek to understand the formation and evolution of planets, the potential for past or present life beyond Earth, and the origins of our solar system through detailed observation and sample collection.
• Astrophysics: This realm of science aims to comprehend the universe's fundamental nature, from its origins (such as the Big Bang theory, describing the universe's earliest moments) to the study of distant galaxies, stars, black holes, dark matter, dark energy, and exoplanets. NASA's Great Observatories program (including the Hubble Space Telescope, Chandra X-ray Observatory, Spitzer Space Telescope, and Compton Gamma Ray Observatory) and newer missions like the James Webb Space Telescope (JWST) provide unparalleled views into the cosmos, pushing the boundaries of human knowledge about the universe's structure and evolution.

The NEAR Shoemaker Mission: A Pioneer in Asteroid Exploration

The Near Earth Asteroid Rendezvous – Shoemaker (NEAR Shoemaker) was a groundbreaking robotic space probe designed and built by the Johns Hopkins University Applied Physics Laboratory (JHU/APL) for NASA. Launched in February 1996 aboard a Delta II rocket, the spacecraft was later renamed in honor of the distinguished planetary geologist Eugene Shoemaker (1928-1997), a co-founder of planetary science and a pioneer in the study of impact craters and near-Earth objects. The primary objective of the NEAR mission was to conduct an in-depth study of 433 Eros, a substantial S-type (stony) near-Earth asteroid, from close orbit over approximately one year. This mission made history as the first spacecraft to successfully orbit an asteroid and later, in an unplanned but successful maneuver, became the first to land on an asteroid.

Mission Milestones and Scientific Objectives

NEAR Shoemaker achieved remarkable milestones during its operational life, revolutionizing our understanding of asteroids:

• Approach and Orbit Insertion: In February 2000, after a four-year journey and a challenging rendezvous maneuver, the mission successfully closed in with Eros and subsequently entered orbit around it. This unprecedented orbital phase initiated a year-long detailed study, during which the spacecraft gathered high-resolution images and crucial scientific data from varying altitudes.
• Unprecedented Landing: On February 12, 2001, at the conclusion of its orbital mission, NEAR Shoemaker executed a controlled descent, touching down softly on the asteroid's saddle-shaped surface at a speed of about 1.5 to 1.8 meters per second (3.3 to 4.0 mph). Despite not being specifically designed for landing, the probe survived the impact and remarkably continued to transmit data for just over two weeks from the surface before its termination, providing invaluable close-up observations of the asteroid's rocky terrain.

The core scientific objective of NEAR Shoemaker was to return comprehensive data on the physical and chemical properties of Eros, which is one of the largest known near-Earth objects, measuring approximately 34.4 × 11.2 × 11.2 kilometers (21.4 × 7.0 × 7.0 miles). The mission aimed to gather data on:

• Bulk Properties: Including its overall mass, density, and gravitational field, which are crucial for understanding its internal structure and how it might have formed.
• Composition and Mineralogy: To determine the elemental and mineral makeup of Eros's surface and subsurface materials, providing clues about its origin and evolution.
• Morphology: Detailed mapping of its surface features, shape, and topography, revealing craters, boulders, and other geological formations.
• Internal Mass Distribution: Providing insights into how material is distributed within the asteroid's interior, potentially indicating a uniform structure or areas of varying density.
• Magnetic Field: To detect the presence or absence of a magnetic field, which can inform about its formation history and the presence or lack of a metallic core.

Secondary objectives further broadened the mission's scope, including studies of regolith (the loose, fragmented material that covers the asteroid's solid rock, similar to lunar soil), interactions with the solar wind (the stream of charged particles from the Sun), potential current activity indicated by dust or gas plumes, and the precise asteroid spin state. The data gathered from these investigations were critical to enhance our general understanding of asteroids, clarify their relationship to meteoroids and comets, and ultimately shed light on the conditions and processes that prevailed in the early Solar System, as asteroids are considered primordial remnants from that era, preserved almost unchanged for billions of years.

Advanced Instrumentation for Unlocking Asteroid Secrets

To accomplish its ambitious scientific goals, the NEAR Shoemaker spacecraft was equipped with a sophisticated suite of instruments, weighing a total of 56 kg (123 lb) and requiring approximately 80 watts of power:

• X-ray/Gamma-ray Spectrometer (XGRS): Used to determine the elemental composition of Eros's surface by detecting characteristic X-rays and gamma rays emitted after interaction with solar radiation and cosmic rays, providing a geochemical fingerprint.
• Near-Infrared Imaging Spectrograph (NIS): Provided mineralogical mapping by analyzing reflected infrared light, helping identify different rock and mineral types, such as silicates and pyroxenes, on the asteroid's surface.
• Multi-spectral Imager (MSI): Fitted with a Charge-Coupled Device (CCD) imaging detector, this instrument captured high-resolution images of the asteroid's surface in various wavelengths, enabling detailed morphological studies, global mapping, and the identification of surface color variations.
• Laser Rangefinder (NLR): Used to measure distances from the spacecraft to the asteroid's surface with high precision, creating a detailed topographic map and a 3D shape model of Eros.
• Magnetometer (MAG): Designed to detect any intrinsic magnetic field of Eros, offering clues about its internal structure and thermal history, as magnetic fields typically arise from dynamic metallic cores.
• Radio Science Experiment: Performed using the spacecraft's highly accurate tracking system, this experiment precisely measured slight variations in NEAR Shoemaker's orbit due to Eros's gravitational pull, allowing scientists to estimate the asteroid's gravity field and, consequently, its mass and internal mass distribution, revealing clues about its density variations.

Frequently Asked Questions About NASA and NEAR Shoemaker

What is the primary mission of NASA?

NASA's primary mission is to pioneer the future in space exploration, scientific discovery, and aeronautics research. It is the U.S. federal government's independent agency responsible for the civilian space program, focusing on peaceful applications of space science and technology for the benefit of humanity.

What are some of NASA's current major programs and future initiatives?

Currently, NASA supports the International Space Station (ISS) as a key partner and is developing the Orion spacecraft and Space Launch System (SLS) for the Artemis Program, which aims to return humans to the Moon and eventually send them to Mars. The agency also supports Commercial Crew vehicles for astronaut transport and is working on the Lunar Gateway space station, intended to orbit the Moon. Additionally, it operates the Launch Services Program for uncrewed missions.

What was the significance of the NEAR Shoemaker mission?

The NEAR Shoemaker mission was historically significant as the first spacecraft to successfully orbit an asteroid (433 Eros) and later the first to successfully land on an asteroid. It provided unprecedented close-up data on a near-Earth asteroid, fundamentally advancing our understanding of these celestial bodies and paving the way for future asteroid missions.

What scientific data did NEAR Shoemaker collect from asteroid Eros?

NEAR Shoemaker gathered extensive data on Eros's bulk properties (mass, density), elemental and mineral composition, surface morphology (shape and features), internal mass distribution, and magnetic field. These observations helped scientists understand asteroid formation, their relationship to other solar system objects like meteoroids and comets, and the conditions in the early solar system.