Near-Earth Asteroids
Tracking asteroids approaching Earth in the next 7 days • Data from NASA JPL
What are Near-Earth Objects (NEO)?
NEOs are asteroids and comets with orbits that bring them within 30 million miles (50 million km) of Earth's orbit. NASA tracks these objects to assess potential impact hazards. A "Potentially Hazardous Asteroid" (PHA) is larger than 140 meters and passes within 4.6 million miles (7.5 million km) of Earth's orbit.
Asteroid Classification and Composition
Asteroids are rocky remnants from the early solar system, formed approximately 4.6 billion years ago when the planets were coalescing from the protoplanetary disk. Most asteroids reside in the Main Asteroid Belt between Mars and Jupiter, but gravitational interactions with Jupiter and other planets occasionally perturb their orbits, sending some into the inner solar system where they become Near-Earth Objects. Scientists classify asteroids by their spectral characteristics, which reveal their composition and formation history.
Major Asteroid Types
C-Type (Carbonaceous)~75% of known asteroids
C-type asteroids are the most common and among the most primitive objects in the solar system. Composed primarily of clay and silicate rocks with high carbon content, they appear very dark with albedo (reflectivity) values as low as 3-9%. These asteroids have remained relatively unchanged since the solar system's formation, making them valuable for studying primordial conditions. Many contain water ice and organic compounds, which makes them scientifically important for understanding the origins of life. Asteroids like Bennu (target of NASA's OSIRIS-REx mission) and Ryugu (visited by Japan's Hayabusa2) are C-type, chosen specifically because their composition may preserve chemical signatures from the early solar system.
S-Type (Silicaceous)~17% of known asteroids
S-type asteroids are composed primarily of iron and magnesium silicates, making them brighter than C-types with albedo values of 10-22%. These rocky bodies dominate the inner asteroid belt and are thought to be the parent bodies of ordinary chondrite meteorites—the most common type found on Earth. S-type asteroids have undergone more thermal processing than C-types, meaning they were heated enough early in solar system history to partially differentiate (separate) their materials by density. Asteroid 433 Eros, visited by NASA's NEAR Shoemaker mission in 2000, is a well-studied S-type that provided crucial data about asteroid internal structure and surface properties.
M-Type (Metallic)~8% of known asteroids
M-type asteroids are composed primarily of metallic iron and nickel, appearing moderately bright with albedo around 10-18%. These objects are believed to be the exposed cores of larger differentiated planetesimals that were catastrophically disrupted by collisions early in solar system history. When asteroids large enough to melt internally formed, heavier metals sank to their centers while lighter rocky materials floated to the surface. M-types represent what remains after violent impacts stripped away the outer layers. Asteroid 16 Psyche, the target of NASA's Psyche mission launched in 2023, is an M-type that may be worth an estimated $10 quintillion in metals—though mining it remains in the realm of science fiction. Studying M-types helps scientists understand planetary core formation and early solar system dynamics.
Beyond these main categories, astronomers have identified numerous subcategories and rare types including X-type (metallic or with unusual compositions), D-type (extremely dark, possibly rich in organic compounds), and V-type (basaltic, likely fragments from differentiated bodies). The diversity of asteroid compositions provides a window into the varied conditions and processes that occurred throughout the early solar system's different regions.
Planetary Defense and Impact Mitigation
While catastrophic asteroid impacts are statistically rare, they pose an existential threat that humanity takes seriously. The asteroid that ended the Cretaceous period 66 million years ago was approximately 10-15 kilometers in diameter and released energy equivalent to billions of nuclear weapons, causing mass extinctions that wiped out the dinosaurs. Even smaller impacts can cause regional devastation—the 1908 Tunguska event in Siberia, caused by an object only 60-190 meters across, flattened 2,000 square kilometers of forest with the force of 10-15 megatons of TNT.
Detection and Tracking Systems
NASA's Planetary Defense Coordination Office oversees efforts to detect, track, and characterize near-Earth objects. The Center for Near-Earth Object Studies (CNEOS) at NASA's Jet Propulsion Laboratory maintains precise orbital calculations for all known potentially hazardous asteroids. Ground-based telescopes like the Catalina Sky Survey, Pan-STARRS in Hawaii, and the upcoming NEO Surveyor space telescope continuously scan the sky for previously unknown objects and refine orbits of known threats.
As of 2026, astronomers have cataloged over 31,000 near-Earth asteroids, with approximately 2,300 classified as potentially hazardous. NASA estimates they have found roughly 95% of the largest and most dangerous NEOs (those exceeding 1 kilometer in diameter), but only about 40% of the 140+ meter size range—large enough to cause regional devastation. Current survey programs discover approximately 3,000 new near-Earth asteroids annually, with detection rates improving as telescope technology advances.
Deflection Strategies
If a threatening asteroid is detected with sufficient warning time—ideally decades before potential impact—several deflection methods could alter its orbit enough to miss Earth. The kinetic impactor technique involves crashing a spacecraft into the asteroid at high velocity to change its momentum, nudging it onto a safer trajectory. NASA successfully demonstrated this approach with the Double Asteroid Redirection Test (DART) mission in September 2022.
DART Mission: Humanity's First Planetary Defense Test
On September 26, 2022, NASA's DART spacecraft intentionally collided with Dimorphos, a 160-meter moonlet orbiting the larger asteroid Didymos. Traveling at 6.6 kilometers per second (14,760 mph), the 570-kilogram spacecraft struck Dimorphos head-on, releasing energy equivalent to roughly 3 tons of TNT. The impact successfully altered Dimorphos's orbital period around Didymos by 33 minutes—far exceeding the mission's minimum success threshold of 73 seconds.
The European Space Agency's Hera mission, launched in October 2024, will arrive at the Didymos system in 2026 to conduct detailed surveys of the impact crater, measure changes to Dimorphos's mass distribution, and precisely characterize the asteroid's internal structure. This data will inform future planetary defense planning and validate computer models used to predict deflection mission outcomes. DART proved that humanity now possesses the technology to deflect a dangerous asteroid given adequate warning time.
Alternative deflection concepts include gravity tractors (using a spacecraft's gravitational pull to gradually tug an asteroid over years or decades), ion beam deflection (using sustained low-thrust propulsion to slowly push the asteroid), and nuclear devices (deployed near but not on the asteroid to vaporize surface material, creating thrust that alters the orbit). The optimal technique depends on warning time, asteroid size and composition, and mission constraints.
International Cooperation and Future Preparedness
Planetary defense requires global coordination because asteroid impacts don't respect national borders. The United Nations has established the International Asteroid Warning Network (IAWN) and the Space Mission Planning Advisory Group (SMPAG) to facilitate information sharing and coordinate response planning among space-faring nations. Regular international exercises simulate asteroid threat scenarios to test communication protocols and decision-making processes.
Looking ahead, the NEO Surveyor space telescope, scheduled to launch in 2027, will dramatically improve detection capabilities, particularly for asteroids in orbits that keep them in daylight skies where ground-based telescopes struggle to observe them. Combined with continued advances in deflection technology demonstrated by missions like DART, humanity is developing robust capabilities to protect Earth from asteroid impacts—transforming what was once an inevitable cosmic threat into a manageable engineering challenge.
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Data provided by NASA JPL NeoWs API
Updates hourly • LD = Lunar Distance (384,400 km) • 1 AU = 149,597,871 km