Potentially hazardous object
A potentially hazardous object (PHO) is a near-Earth object, typically an asteroid or comet, whose orbit brings it into close proximity to Earth—defined as a minimum orbit intersection distance (MOID) of 0.05 astronomical units (AU) or less—and which is sufficiently large, with an absolute magnitude of 22.0 or brighter, corresponding to a diameter of at least 140 meters, to potentially cause regional or global devastation if it were to collide with the planet.[1][2] These objects are a subset of near-Earth objects (NEOs), which have perihelion distances less than 1.3 AU from the Sun, but PHOs are distinguished by their specific size and approach criteria that elevate their risk profile.[1][3] PHOs represent a key focus of planetary defense efforts due to the catastrophic potential of impacts, which could release energy equivalent to nuclear explosions and trigger environmental effects like tsunamis, wildfires, or climate disruption, as evidenced by historical events such as the Chicxulub impact linked to dinosaur extinction.[4] NASA's Center for Near-Earth Object Studies (CNEOS) at the Jet Propulsion Laboratory systematically tracks these objects using data from ground- and space-based telescopes, including surveys like Pan-STARRS and the upcoming Vera C. Rubin Observatory, to refine orbital predictions and assess collision probabilities. As of November 2025, 2,349 PHOs have been discovered and cataloged out of more than 37,000 known NEOs, with ongoing discoveries adding roughly 1,000-3,000 NEOs annually, though only a fraction qualify as PHOs.[5][6][7] Despite their designation, no known PHO is predicted to impact Earth with certainty in the next century, thanks to refined trajectory calculations, but monitoring remains critical as smaller or undiscovered objects could pose undetected risks.[8] Efforts to mitigate threats include NASA's Planetary Defense Coordination Office, which coordinates international observations and develops deflection technologies like kinetic impactors, as demonstrated by the successful DART mission in 2022.Definition and Criteria
Orbital Requirements
A potentially hazardous object (PHO) is identified primarily by its orbital geometry relative to Earth's orbit, with the key criterion being a minimum orbit intersection distance (MOID) of 0.05 AU or less to Earth. This distance, equivalent to approximately 7.5 million kilometers, represents the closest possible approach between the two orbits based on their fixed paths, calculated using the object's osculating orbital elements and Earth's nominal circular orbit at 1 AU from the Sun.[1] Objects meeting this threshold are those whose orbits can geometrically position them near Earth's path, heightening the risk of a close encounter that could lead to collision under certain orbital alignments.[2] This applies to both asteroids and comets meeting the criteria. Achieving a MOID of 0.05 AU requires specific orbital parameters that enable the object's path to intersect or closely parallel Earth's orbit. For many PHAs, the perihelion distance is sufficiently close to the Sun—often less than about 1.05 AU—to allow the orbit to reach near Earth's location, while the eccentricity is generally greater than 0.2 to extend the aphelion beyond 1 AU, creating an elliptical path that can cross or approach the 1 AU radius closely.[9] Additionally, the orbital inclination relative to the ecliptic must be low enough to minimize vertical separation; inclinations exceeding around 30 degrees often result in larger MOID values due to excessive out-of-plane motion, though no strict minimum inclination is imposed beyond what yields the required MOID. These considerations are primarily inherent to the Apollo and Aten near-Earth object groups, though some objects in the Amor group can also qualify if their MOID ≤ 0.05 AU. Apollo orbits have perihelia inside Earth's orbit and semi-major axes greater than 1 AU, and Aten orbits have semi-major axes less than 1 AU but aphelia outside Earth's orbit.[10] This framework ensures that only objects with orbits capable of bringing them within 0.05 AU of Earth—about 19.5 Earth-Moon distances—are flagged for enhanced monitoring, as such proximity amplifies the potential for impactful interactions over astronomical timescales. The criteria were formally adopted in the 1990s by the International Astronomical Union (IAU) through its Working Group on Near-Earth Objects and the Minor Planet Center, standardizing the classification amid growing concerns over asteroid impacts following discoveries like (3200) Phaethon in 1983 and advancements in survey capabilities.Size and Magnitude Thresholds
The classification of potentially hazardous objects (PHOs) includes a size threshold based on absolute magnitude, defined as H ≤ 22, which serves as a proxy for objects with estimated diameters of roughly 140 meters or larger under typical albedo assumptions.[1] This brightness threshold, established by NASA, corresponds to the minimum size capable of causing significant regional damage upon atmospheric entry and impact, aligning with congressional mandates to catalog such threats.[11] Size estimates for PHOs are derived from the absolute magnitude H and the object's geometric albedo, which varies widely and introduces uncertainty in diameter calculations. Albedos for near-Earth asteroids typically range from 0.05 to 0.25, with lower values (darker surfaces) implying larger sizes for a given H, and higher values (brighter surfaces) suggesting smaller sizes.[12] The approximate diameter D in kilometers can be calculated using the formula: D \approx \frac{1329}{10^{0.2(H - A)}} where A represents the albedo expressed in magnitudes (derived from the geometric albedo p via A = -2.5 log₁₀(p)).[13] For H = 22 and a typical albedo of 0.14 (p_V = 0.14), this yields D ≈ 140 meters, but variations in albedo can adjust the estimate by a factor of 2 or more.[14] Objects smaller than 140 meters are excluded from PHO classification despite their potential for local damage, such as cratering or airburst effects equivalent to nuclear explosions, because they pose negligible risk of global catastrophe or widespread devastation.[15] This threshold focuses monitoring efforts on threats that could affect entire regions or continents, as impacts from sub-140-meter objects are unlikely to produce ejecta or climatic effects on a planetary scale.[16] Uncertainties in size estimates arise primarily from the irregular shapes of asteroids, which deviate from the spherical assumption in standard models, and from rotational effects that alter observed brightness during lightcurve variations.[17] These factors, combined with imprecise albedo measurements, can lead to diameter errors of 20-50% or greater, particularly for fast-rotating or elongated bodies.[17]Physical Characteristics
Size Distribution
Potentially hazardous objects span a broad range of sizes, from the definitional minimum of approximately 140 meters in diameter to about 7 kilometers, with the largest known being (53319) 1999 JM8; though the vast majority fall between 140 meters and 1 kilometer. This range is determined from absolute magnitude estimates, where the 140-meter threshold corresponds to an absolute magnitude H of about 22, assuming typical albedos of 0.05 to 0.2 for near-Earth asteroids. The size distribution of potentially hazardous objects follows a power-law form, characterized by the cumulative number of objects with diameter greater than D, denoted N(>D), scaling as N(>D) ∝ D^{-2.5} for diameters D > 1 km. This relationship arises from collisional evolution models and observational data from near-Earth object surveys, indicating a steep decline in the number of larger objects.[20][21] Such a distribution has significant implications for impact hazards, as the kinetic energy released upon collision with Earth scales with the cube of the diameter. Specifically, the energy E is approximated by E \approx \frac{1}{2} m v^2 , where mass m ∝ D^3 (assuming constant density) and v is the impact velocity, typically around 20 km/s for near-Earth objects entering Earth's atmosphere. This cubic scaling means that a PHA twice as large delivers roughly eight times the energy, dramatically amplifying the destructive potential of larger objects despite their relative scarcity.[22] Observational surveys, including those from NASA's Near-Earth Object Observations Program, have cataloged 154 potentially hazardous objects larger than 1 km in diameter as of January 2025, representing a nearly complete inventory for this size class, with over 90% discovery completeness for near-Earth asteroids larger than 1 km overall (of which PHAs comprise about 10-15%).[23][21]Composition and Types
Potentially hazardous objects (PHOs) are predominantly asteroids, with a small fraction consisting of comets distinguished by their icy composition and potential for outgassing. Asteroids among PHOs are classified primarily through spectral reflectance surveys that analyze their surface mineralogy and material properties in the visible and near-infrared wavelengths. These classifications reveal a diverse range of compositions, including silicaceous, carbonaceous, and metallic types, which influence their albedo, detectability, and potential interaction with Earth's atmosphere upon impact. The majority of PHO asteroids belong to the S-complex (silicaceous), characterized by silicate-rich surfaces similar to ordinary chondrites, comprising approximately 46% of near-Earth asteroids (NEAs) with distributions similar in the PHO subset. Carbonaceous C-complex asteroids, rich in carbon, organics, and hydrated silicates akin to carbonaceous chondrites, account for about 26% of NEAs and exhibit lower albedos, making them harder to detect at greater distances. Metallic M-type asteroids, part of the broader X-complex which includes about 15% of NEAs, are composed primarily of iron and nickel, resembling iron meteorites, and represent roughly 8% when isolated from other X subtypes. These proportions are derived from spectroscopic observations using taxonomic schemes such as Bus-DeMeo, which extend earlier work like the Small Main-belt Asteroid Spectroscopic Survey (SMASS) to NEA populations.[24][25] Comets as PHOs are volatile-rich icy bodies originating from the outer solar system, defined by perihelion distances less than 1.3 AU and evidence of cometary activity such as coma or tail formation due to sublimation near the Sun. They constitute only about 1% of known PHOs, with most PHOs being asteroids.[1] The volatile ices in comets, including water, carbon dioxide, and methane, lead to unpredictable outgassing that can alter their orbits and brightness, complicating detection compared to the more stable surfaces of asteroids. This activity also affects hazard assessment, as cometary fragments may disperse differently upon atmospheric entry, though their lower density reduces overall impact energy relative to asteroids of similar size. Spectral surveys confirm that active comets show distinct features like broadened absorption bands from dust and gas, distinguishing them from asteroid spectra.[26]Population and Discovery
Current Estimates
As of October 2025, the Minor Planet Center (MPC) catalogs 2,507 known potentially hazardous asteroids (PHAs).[27] These align with the observational criteria used for classification, based on absolute magnitude corresponding to a minimum diameter of approximately 140 meters. Models based on survey data estimate the total population of PHAs larger than 140 meters at around 25,000 objects.[28] This projection accounts for observational biases and completeness levels derived from near-Earth object (NEO) population studies. NASA estimates indicate that surveys have achieved about 90% completeness for PHAs larger than 1 kilometer in diameter, with roughly 154 such objects known out of an estimated total of around 170.[29] In contrast, completeness for PHAs between 140 meters and 1 kilometer remains below 10%, reflecting the challenges in detecting smaller, fainter objects. Discovery rates for PHAs have increased steadily since the 2010s, averaging approximately 70 new identifications per year in recent times, fueled by enhanced capabilities from surveys like Pan-STARRS and the Asteroid Terrestrial-impact Last Alert System (ATLAS).[23] This growth contributes to ongoing efforts to refine population estimates through improved observational coverage.[30]Observation Surveys
Observation surveys for potentially hazardous objects (PHAs) employ a combination of ground-based and space-based telescopes to detect and characterize near-Earth asteroids that meet the criteria for potential hazard assessment. These programs primarily use optical and infrared wavelengths to scan large portions of the sky, focusing on objects with orbits that bring them close to Earth. Ground-based optical surveys have been instrumental in discovering the majority of known PHAs. The Pan-STARRS (Panoramic Survey Telescope and Rapid Response System), located on Haleakala in Hawaii, operates a 1.8-meter telescope equipped with a 1.4-gigapixel camera to conduct wide-field imaging, primarily aimed at detecting PHAs through repeated scans of the visible sky.[31] Similarly, the Catalina Sky Survey, based at the University of Arizona's Steward Observatory in Arizona, uses 0.7-meter and 1.5-meter telescopes at Catalina Station and Mount Lemmon to monitor the sky for moving objects, contributing significantly to PHA discoveries as part of NASA's Near-Earth Object Observations Program.[32] The ATLAS (Asteroid Terrestrial-impact Last Alert System), with telescopes in Hawaii and Chile, scans the entire visible sky nightly to identify fast-moving near-Earth objects, including PHAs, providing early warnings for potential impacts.[30] Space-based missions complement ground efforts by overcoming atmospheric limitations and enabling infrared observations for size estimation. The NEOWISE mission, a reactivation of NASA's Wide-field Infrared Survey Explorer launched in 2009 and operational from 2011 until its decommissioning in July 2024, used infrared wavelengths to detect over 200,000 asteroids, including PHAs, and provided thermal measurements crucial for estimating their sizes and albedos; its final data release in November 2024 further refined PHA population models.[33][34] The European Space Agency's Gaia mission, primarily focused on stellar astrometry, has also contributed precise positional data for thousands of near-Earth objects, improving orbital determinations for PHAs through its high-accuracy measurements.[35] Looking ahead, NASA's NEO Surveyor, an infrared space telescope scheduled for launch no later than June 2028, is designed specifically to hunt for PHAs, aiming to characterize their sizes and orbits from a stable vantage point at the Sun-Earth L1 Lagrange point.[36] Among upcoming ground-based facilities, the Vera C. Rubin Observatory's Legacy Survey of Space and Time (LSST), which began operations in 2025 in Chile, will use an 8.4-meter telescope with a 3.2-gigapixel camera to survey the southern sky repeatedly, projected to discover 80-90% of PHAs larger than 140 meters in diameter over its 10-year mission; early operations in late 2025 have already contributed to initial PHA discoveries.[37] Detection of PHAs faces significant challenges, including observational biases that favor objects in the inner solar system near opposition, where they are brighter and easier to spot, while underrepresenting those in more distant or atypical orbits.[38] Additionally, faint PHAs located near the Sun are particularly difficult to observe due to intense solar glare, zodiacal light, and high background noise, which obscure small or low-albedo objects during daytime or twilight conditions.[39]Notable Examples
Largest Known PHAs
The largest known potentially hazardous asteroid (PHA) is (53319) 1999 JM8, an Apollo-type object with an estimated mean diameter of 7 km derived from radar observations conducted by the Arecibo Observatory and Goldstone Deep Space Network in 1999.[40] This X-type asteroid, discovered on May 13, 1999, by the LINEAR survey, exhibits a slow, non-principal axis rotation with a period of approximately 144 hours and occupies a relatively stable orbit with low eccentricity (e ≈ 0.25).[41] Its size places it at the upper end of PHA dimensions, estimated using the absolute magnitude H = 15.35 and an albedo of about 0.05 from thermal infrared data. Other prominent large PHAs include 3200 Phaethon, estimated at 6.3 km in diameter from infrared measurements by the AKARI and IRAS missions as well as recent radar data, and classified as a B-type asteroid in a highly eccentric orbit (e ≈ 0.89) that remains dynamically stable over long timescales without entering mean-motion resonances with major planets. Discovered in 1983 at the Kitami Observatory, it serves as the parent body for the Geminid meteor stream.[42] Similarly, (4953) 1990 MU, with a diameter of approximately 3 km based on absolute magnitude H = 14.1 and visible/near-IR spectroscopy indicating an S-type composition similar to H-chondrites, was discovered in 1990 and features a low-eccentricity orbit (e ≈ 0.65) that avoids chaotic resonances.[43][44] 3753 Cruithne, with an estimated diameter of approximately 2.1 km from NEOWISE thermal infrared data, and S-type taxonomy confirmed by spectroscopic surveys, stands out among PHAs for its orbital dynamics.[45] Discovered in 1986 at the Palomar Observatory, this Apollo asteroid follows a stable 1:1 orbital resonance with Earth, tracing a horseshoe path relative to our planet over an ~770-year cycle. Likewise, 4179 Toutatis, with dimensions of roughly 5 km × 2.5 km (mean ~2.5 km) from radar imaging during its 1996 and 2004 close approaches, is an S-type Apollo asteroid discovered in 1989 that tumbles in a non-principal axis rotation state due to its bilobed shape.[46] Its orbit has moderate eccentricity (e ≈ 0.53) and is stabilized by secular resonances with Jupiter. (29075) 1950 DA, estimated at 1.3 km in diameter from radar ranging and IR observations indicating a metallic E-type composition, was recovered in 2000 after its initial discovery in 1950.[47] This Apollo PHA exhibits a low-eccentricity orbit (e ≈ 0.10) influenced by a secular resonance with Saturn, contributing to its long-term stability. These large PHAs often feature orbital characteristics such as low to moderate eccentricities or stable resonances that prevent rapid dynamical evolution, distinguishing them from smaller, more chaotic objects in the population. Large PHAs are exceedingly rare, comprising less than 1% of the known PHA population and highlighting the upper tail of the size distribution derived from surveys like NEOWISE.[23]| Asteroid | Estimated Diameter (km) | Spectral Type | Discovery Year |
|---|---|---|---|
| (53319) 1999 JM8 | 7.0 | X | 1999 |
| 3200 Phaethon | 6.3 | B | 1983 |
| 3753 Cruithne | 2.1 | S | 1986 |
| 4179 Toutatis | 2.5 (mean) | S | 1989 |
| (4953) 1990 MU | 3.0 | S | 1990 |
| (29075) 1950 DA | 1.3 | E | 1950 |
Famous Close Approaches
One of the most notable events involving a small near-Earth object was the 2013 Chelyabinsk meteor, an approximately 20-meter asteroid that entered Earth's atmosphere over Russia on February 15, 2013, at a speed of 18.6 kilometers per second and exploded in an airburst about 23 kilometers above the ground.[48][49] The event injured around 1,600 people from the shockwave and flying glass, highlighting the risks of undetected smaller objects, and garnered widespread media attention as the largest known airburst since the 1908 Tunguska event.[48][50] Radar observation campaigns have provided critical insights during PHO flybys, such as those of asteroid (4179) Toutatis, a peanut-shaped object approximately 5 kilometers long that made close approaches in 1992, 1996, and 2012.[51] During its 2012 flyby at about 0.0015 astronomical units (AU) from Earth, NASA's Goldstone Deep Space Network radar captured high-resolution images revealing Toutatis's complex, non-principal axis rotation and surface features, aiding in refined orbital predictions.[52][53] Public interest and occasional false alarms have marked other significant approaches, including that of asteroid 2004 XP14 in July 2006, which passed Earth at 1.1 lunar distances (about 400,000 kilometers) and was initially flagged with a small impact probability before radar observations confirmed its safety.[54] The event received extensive media coverage due to early uncertainties, underscoring the role of rapid tracking in dispelling concerns.[55] The upcoming close approach of asteroid (99942) Apophis on April 13, 2029, at approximately 31,000 kilometers—closer than geostationary satellites—represents a rare opportunity for study, as this 370-meter PHO will pass safely without impact risk, followed by another approach in 2036 at a greater distance.[56][57] NASA's planetary defense efforts, including radar observations from Goldstone and Arecibo, are planned to image Apophis's surface and measure potential gravitational perturbations during the flyby.[58] In the context of PHO exploration, NASA's OSIRIS-REx mission returned a sample from asteroid Bennu—a carbon-rich PHA about 490 meters across—on September 24, 2023, delivering 121.6 grams of material to Earth after a flyby maneuver.[59] The sample, analyzed to reveal water-bearing minerals and organic compounds potentially linked to life's origins, provided unprecedented insights into PHA composition without a direct close approach by the asteroid itself.[60][61] Recent flybys in 2024, such as those of asteroids 2024 MK (150-330 meters across) on June 27 at 4.3 lunar distances and 2011 UL21 (about 1.5 kilometers across) on July 25 at 6.5 lunar distances, were closely monitored by Goldstone radar, yielding shape models and confirming no hazards, amid heightened public awareness following media reports.[62] By early 2025, observations of 2024 YR4 ruled out its initial low-probability impact risk for 2032, further demonstrating effective tracking systems in managing PHO encounters.[63]Hazard Assessment
Risk Evaluation Methods
Risk evaluation for potentially hazardous objects (PHOs), a subset of near-Earth objects (NEOs), relies on standardized scales and computational systems to quantify collision probabilities and assess urgency. These methods integrate orbital data, impact probabilities, and energy estimates to prioritize threats, enabling astronomers and space agencies to monitor and respond effectively.[64] The Torino Impact Hazard Scale, adopted by the International Astronomical Union in 1999, categorizes potential Earth impacts on a simple integer scale from 0 to 10, based on the combined probability of collision and the object's kinetic energy at impact. Level 0 indicates no hazard, applicable to routine discoveries with effectively zero collision likelihood, while Level 1 denotes normal events meriting no public concern, such as objects with extremely low probabilities that are routinely reassigned to Level 0 upon further observation. Higher levels escalate concern: Level 4 represents a close encounter worthy of attention, with at least a 1% chance of regional devastation, prompting official monitoring if the potential impact is within a decade. Levels 8–10 signify certain collisions, with Level 10 indicating global catastrophe from a massive impactor occurring at intervals of 100,000 years or longer.[65][66] Complementing the Torino Scale, the Palermo Technical Impact Hazard Scale provides a more technical, logarithmic assessment for NEO specialists, comparing an object's specific impact risk to the average annual background risk from similar or larger objects. Developed in 2001, it uses a base-10 log scale where actual values less than -2 reflect events for which there are no likely consequences (e.g., values below -4 signify negligible risk at 0.01% of background), while values between -2 and 0 merit careful monitoring, 0 equals the background risk, and positive values (e.g., +2 for 100 times background) signal heightened concern. The scale is calculated as PS = log₁₀ (Pᵢ / (f_B × DT)), where Pᵢ is the impact probability, DT is the time to potential impact in years, and f_B is the background frequency adjusted for energy (E in megatons TNT equivalent).[67] NASA's Sentry system, operated by the Jet Propulsion Laboratory's Center for Near-Earth Object Studies (CNEOS), automates long-term risk assessment for confirmed NEOs by scanning the asteroid catalog daily and propagating orbital uncertainties over the next 100 years. It employs Monte Carlo simulations, generating thousands to millions of virtual asteroids with varied initial conditions to sample the full uncertainty region, thereby estimating impact probabilities—for instance, if 2 out of 100,000 virtual paths intersect Earth, the probability is 1 in 50,000. JPL's CNEOS complements this with tools like the Scout system for short-term assessments of unconfirmed objects, transitioning them to Sentry upon confirmation, ensuring comprehensive coverage from discovery to refined risk modeling. For example, as of early 2025, asteroid 2024 YR4 briefly reached Torino Scale Level 3, highlighting the scales' role in assessing newly discovered objects.[68][69][70] At the core of these assessments lies the fundamental impact probability formula, which geometrically estimates the likelihood as P = (impact cross-section / orbital volume) × encounter frequency, where the cross-section represents the effective area (e.g., Earth's radius plus the object's size), the orbital volume defines the spatial extent of possible paths, and the frequency accounts for how often the object approaches Earth. This approach, refined through Monte Carlo methods for nonlinear orbital dynamics, underpins the scales by providing the probabilistic input for threat prioritization.[71]Potential Impact Effects
Potentially hazardous objects (PHOs), primarily asteroids and comets on trajectories that could intersect Earth's orbit, pose varying degrees of destruction upon impact depending on their size, composition, velocity, and entry angle. The kinetic energy released during an impact scales with the object's mass and speed, leading to effects ranging from regional devastation to global catastrophes. This energy is calculated using the formula for kinetic energy:E = \frac{1}{2} \rho \cdot \frac{4}{3} \pi \left( \frac{D}{2} \right)^3 v^2
where \rho is the object's density (typically around 2.5 g/cm³ for stony asteroids), D is the diameter, and v is the impact velocity (often approximately 20 km/s for Earth-crossing objects). These impacts can release energy equivalent to millions or billions of tons of TNT, with PHOs (≥140 m) generally penetrating the atmosphere to cause surface or subsurface explosions. PHOs ranging from 140 meters to 1 kilometer in diameter can generate regional devastation, including craters several kilometers wide, seismic shocks equivalent to magnitude 7–8 earthquakes, and tsunamis if impacting oceans. These collisions release 10 to 1,000 megatons of TNT, triggering firestorms from superheated ejecta, atmospheric dust plumes that cause short-term cooling, and acid rain from vaporized materials. Ejecta from such impacts can spread globally, blanketing regions in molten debris and causing widespread wildfires. Historical simulations indicate that a 300-meter object striking land could destroy an area the size of a major city, with effects felt thousands of kilometers away. Large PHOs exceeding 1 kilometer pose existential threats through global environmental disruption, potentially leading to mass extinctions by injecting vast amounts of dust and sulfate aerosols into the stratosphere, blocking sunlight and inducing a "nuclear winter" with years of cooling. Impacts of this scale release around 10^6 megatons of TNT or more, vaporizing rock to form transient fireballs larger than continents and lofting debris that persists for decades. The resulting climate effects include disrupted agriculture, ocean acidification, and biodiversity collapse, as seen in paleontological records. Historical analogs illustrate these effects vividly. In contrast, the Chicxulub impactor, estimated at 10 kilometers wide 66 million years ago, excavated a 150-kilometer crater and triggered the Cretaceous–Paleogene extinction, killing ~75% of species through combined blast, tsunamis, wildfires, and prolonged dust-induced darkness. These examples underscore how PHO size dictates the transition from regional to planetary-scale consequences.