Fact-checked by Grok 2 weeks ago

Solar mass

The solar mass (M_⊙) is a standard unit of mass in astronomy, defined as the mass of , which is approximately 1.989 × 10³⁰ kilograms or about 333,000 times the mass of . This unit provides a convenient, scale-independent reference for expressing the masses of stars, planets, galaxies, and other celestial objects, as stellar masses typically range from fractions to hundreds of solar masses. The value of the solar mass is determined primarily through observations of planetary orbits in the Solar System, applying combined with Kepler's third law of planetary motion, which relates the and semi-major to the central body's mass. For instance, (with a period of 1 year and semi-major axis of 1 ) yields the solar mass directly in these units, while additional refinements come from spacecraft data, radar ranging, and helioseismology studies of solar oscillations. The accepted value as of 2023 is 1.98841 × 10³⁰ kg with an uncertainty of about 0.002%, reflecting high-precision measurements from missions like those contributing to CODATA and IAU standards. In , the solar mass is crucial for understanding , as a star's mass dictates its lifecycle, , and eventual fate—from main-sequence stability to explosions for massive stars exceeding roughly 8 M_⊙. It also underpins models of galactic dynamics and formation, where supermassive black holes can reach billions of solar masses. Although the Sun gradually loses a tiny fraction of its mass (about 10^{-13} M_⊙ per year) through and radiation, this does not significantly alter the unit's definition for practical astronomical use.

Definition and Value

Definition

The solar mass, denoted as M_\odot, is defined as the mass of the Sun and serves as a primary in astronomy for quantifying the masses of various celestial objects, including , , galaxies, and holes. This unit provides a natural reference scale rooted in the Sun's properties, allowing astronomers to express masses in terms of multiples or fractions of M_\odot, which facilitates comparisons across diverse astronomical phenomena. In astronomical research, the solar mass plays a crucial role by establishing a convenient for understanding gravitational interactions and stellar evolutionary processes. For instance, it enables the formation of dimensionless ratios, such as expressing a planet's relative to M_\odot, which highlights the scale differences in solar and aids in modeling orbital stability and formation mechanisms. By normalizing masses to this solar standard, scientists can more readily analyze how influences rates, , and lifespan in stars, as well as the binding energies in compact objects like neutron stars or black holes. The symbol M_\odot is the internationally recognized notation for the solar mass, commonly employed in and equations describing , galactic dynamics, and cosmological models. This notation underscores its status as a fundamental constant in astrophysical computations, where it often appears in proportionality relations without requiring explicit conversion to SI units for conceptual work.

Numerical Value

The current accepted value of the solar mass is $1.98841(4) \times 10^{30} , as recommended by the Particle Data Group in their 2025 review of astrophysical constants, which incorporates high-precision astrometric data from missions like for refined orbital parameters. This mass is equivalent to approximately 332,946 masses (M_\oplus) and 1,047 masses (M_\Jup). The precision of the solar mass derives from the International Astronomical Union's (IAU) 2012 standards, which fix the at k = 0.01720209895 (exact) to define the product GM_\odot in astronomical units, combined with the Newtonian G = 6.67430(15) \times 10^{-11} m³ kg⁻¹ s⁻² from the CODATA 2022 adjustment; updates to G in future CODATA revisions may slightly refine the solar mass value.

Historical Development

Early Measurements

The foundations for estimating the solar mass were laid in the early through Johannes Kepler's formulation of the laws of planetary motion. In (1609) and (1619), Kepler derived three empirical laws describing planetary orbits, with the third law stating that the square of a planet's is proportional to the cube of its semi-major axis from . Although Kepler did not compute a numerical value for the solar mass, his laws enabled indirect inference of the Sun's gravitational influence by relating orbital dynamics to a central force, initially assuming circular orbits for conceptual simplicity. This framework shifted astronomy from geocentric models to heliocentric ones, highlighting the Sun's dominant role in governing planetary motion. The first explicit quantitative estimate emerged with Isaac Newton's (1687), where he unified Kepler's laws with his law of universal gravitation and laws of motion. Newton analyzed 's orbit as a balance between gravitational attraction and , deriving the solar mass as approximately 28,700 times that of Earth in the first edition, later revised to about 169,000 in subsequent editions. This calculation relied on contemporary estimates of Earth's orbital radius and period, assuming the Sun's mass vastly exceeded planetary masses to approximate the of orbits. Newton's approach marked a conceptual breakthrough, transforming qualitative orbital descriptions into a predictive theory of gravitational masses, though limited by imprecise measurements of astronomical distances. Refinements in the built on these principles through advanced analysis and observations of minor bodies. Carl Friedrich Gauss's Theoria Motus Corporum Coelestium in Sectionibus Conicis Sole Orbitas Determinante (1809) introduced least-squares methods for precise orbit determination from observational data, facilitating accurate semi-major axes for planets and asteroids. Johann Franz Encke further advanced this in his 1835 astronomical ephemerides, incorporating perturbations from asteroids like and on planetary paths to refine . These efforts yielded solar mass estimates ranging from 300,000 to 350,000 masses, improving upon Newton's value by accounting for subtle gravitational interactions and better measurements. Such developments emphasized the Sun's mass as a key parameter in dynamical models of the solar system. In contrast to the modern value of about 333,000 masses, these early measurements demonstrated remarkable insight despite relying on rudimentary instrumentation and assuming simplified orbital geometries.

Modern Refinements

In the mid-20th century, radar ranging techniques marked a significant advancement in determining the solar mass by providing precise measurements of planetary distances and orbital parameters within the inner Solar System. Beginning in the late 1950s, radar observations of yielded accurate values for the (AU), the average Earth-Sun distance, with early experiments in 1958 and 1961 refining the AU to within 0.001 light-seconds, thereby improving the scale for Keplerian orbital dynamics used to compute the solar gravitational parameter GM_⊙. These measurements were extended to Mercury in the 1960s, where radar echoes from the planet's surface during inferior conjunctions enhanced orbital accuracy, reducing uncertainties in planetary positions and contributing to a more reliable estimate of the Sun's mass through refined ephemerides. By the end of the decade, such radar data had decreased the relative error in the AU to about 0.001%, directly bolstering the precision of GM_⊙ derivations from planetary motions. The launch of deep-space probes in the 1970s and 1980s further refined solar mass estimates through high-precision tracking data that improved Solar System ephemerides. The Pioneer 10 and 11 missions, launched in 1972 and 1973, provided Doppler and ranging observations during their flybys of Jupiter and Saturn, enabling better modeling of gravitational perturbations and yielding improved values for planetary masses relative to the Sun. Similarly, the Voyager 1 and 2 spacecraft, launched in 1977, contributed extensive radio science data from encounters with the outer planets, which were incorporated into ephemeris developments like DE118, enhancing the determination of GM_⊙ by accounting for subtle dynamical effects such as n-body interactions. In the 1990s, the Hipparcos satellite's astrometric catalog, released in 1997, supplied precise parallax and proper motion data for over 118,000 stars, indirectly supporting solar mass refinements by establishing a more accurate absolute distance scale for calibrating Solar System dynamics against stellar benchmarks. A pivotal milestone occurred in 1976 when the (IAU) adopted the k = 0.01720209895 as a defining in its of Astronomical Constants, fixing the value of GM_⊙ in astronomical units and thereby standardizing solar mass computations for ephemerides and theoretical models. Recent developments from 2000 onward have leveraged space-based and helioseismic observations for even greater precision. The mission, launched in 2013, has revolutionized these efforts through its observations of Solar System objects; Data Release 3 (DR3) in 2022 provided astrometric solutions for millions of minor bodies, enabling dynamical mass determinations for 20 asteroids with precisions improved by factors of up to 10, which in turn refined the overall Solar System mass budget including GM_⊙ via analyses. Data Release 4 (DR4), expected in late 2026, is expected to further enhance this by incorporating five years of full-mission data, yielding sub-milliarcsecond that tightens constraints on the Sun's mass through integrated updates. Concurrently, integration of Gaia's astrometric data with solar helioseismology—using oscillations to probe internal structure—has allowed cross-validation of solar models, where seismic inversions constrain the Sun's and profile, complementing dynamical GM_⊙ values to achieve relative uncertainties below 10^{-7}. Looking ahead, mission planning in the emphasized comparative stellar studies to contextualize the solar mass. The PLAnetary Transits and Oscillations of stars () mission, selected by the in 2017 following conceptual development around , aims to perform asteroseismology on thousands of Sun-like stars to derive precise stellar masses and radii, providing a for validating solar mass scales in evolutionary models.

Calculation Methods

Gravitational Constant Approach

The Gaussian gravitational constant, denoted as k, relates the gravitational parameter of the Sun to the astronomical unit (AU) of length and the mean solar day as the unit of time. Prior to the 2012 IAU redefinition, k was fixed at the exact value k = 0.01720209895 AU^{3/2} M_\odot^{-1/2} day^{-1}, originating from the Gaussian formulation of Kepler's third law for heliocentric orbits, treating the Sun as a point mass with negligible planetary perturbations. This allowed derivation of the solar mass indirectly through astronomical observations calibrating the AU and day, circumventing direct measurement of Newton's gravitational constant G. The theoretical foundation stems from Kepler's third law: the mean angular motion n satisfies n^2 = G M_\odot / a^3, where a is the semi-major axis. For a = 1 AU, k is defined as this mean motion in radians per day, yielding k^2 = G M_\odot / (1 \ \mathrm{AU})^3 with time in days. Thus, the solar mass is M_\odot = \frac{k^2 \ (1 \ \mathrm{AU})^3}{G \ (1 \ \mathrm{day})^2}, where the day is 86,400 seconds. However, the 2012 IAU Resolution B2 fixed the AU at exactly 149,597,870,700 meters and removed the fixed value of k, specifying that the solar gravitational parameter GM_\odot be determined experimentally from observations. The current accepted value is GM_\odot = 1.3271244 \times 10^{20} \ \mathrm{m}^3 \ \mathrm{s}^{-2} (with relative uncertainty ~7.5 \times 10^{-11} as of JPL DE440 ephemeris, 2023). Using the CODATA 2018 value of G = 6.67430 \times 10^{-11} \ \mathrm{m}^3 \ \mathrm{kg}^{-1} \ \mathrm{s}^{-2} (relative uncertainty 22 ppm; CODATA 2022 update pending as of 2025), this yields M_\odot = \frac{1.3271244 \times 10^{20} \ \mathrm{m}^3 \ \mathrm{s}^{-2}}{6.67430 \times 10^{-11} \ \mathrm{m}^3 \ \mathrm{kg}^{-1} \ \mathrm{s}^{-2}} = 1.98841 \times 10^{30} \ \mathrm{kg} (as per PDG 2024, with uncertainty ~20 ppm primarily from G). This method provides a precise scale for the solar mass based on linked units and high-accuracy measurements, assuming Newtonian gravity in the heliocentric frame approximated at the Sun.

Orbital Parameter Derivation

The solar mass can be computed using Newton's generalization of Kepler's third law, which relates the orbital period P of a planet to its semi-major axis a around the Sun, assuming the Sun's mass M_\odot dominates over the planet's mass. For nearly circular orbits, the law takes the form M_\odot = \frac{4\pi^2}{G} \cdot \frac{a^3}{P^2}, where G is the gravitational constant. This equation arises from balancing the gravitational force with the centripetal force required for orbital motion, yielding a dynamical estimate of the central mass. The baseline application uses , where the semi-major axis a is defined as 1 (AU), equivalent to the mean Earth-Sun distance of approximately $1.496 \times 10^{11} meters, and the P is 1 , the time for to complete one revolution relative to the , lasting 365.256363 mean solar days. Substituting these values provides a direct, albeit approximate, value for M_\odot, as Earth's orbit offers a convenient reference due to its well-measured parameters. For higher precision, orbital data from inner planets like Mercury are employed, as their shorter periods and closer proximity amplify sensitivity to the solar mass and reduce relative errors from distant perturbations. Mercury's semi-major axis is about 0.387 AU with a sidereal period of roughly 88 days, allowing refinements to the baseline Earth-derived value through detailed orbit fitting. Modern determinations incorporate radar astrometry, which bounces radio signals off planetary surfaces to measure distances and velocities with millimeter precision, and spacecraft tracking data. The MESSENGER mission (2008–2015), for instance, provided radio ranging observations of Mercury's orbit, enabling integrated ephemeris solutions that yield the solar mass parameter GM_\odot with uncertainties below 0.001%, from which M_\odot follows given the value of G. These inputs enhance accuracy by accounting for relativistic effects and solar oblateness in the orbital dynamics.

Uncertainties and Variations

Sources of Error

The primary sources of uncertainty in determining the solar mass arise from errors in key parameters used in its calculation, particularly the Newtonian G. The solar mass M_\odot is derived from the GM_\odot, which is obtained from planetary orbital dynamics via Kepler's third law generalized for the solar system, divided by G. The relative in G is approximately $2.2 \times 10^{-5}, as recommended by the 2022 CODATA adjustment based on laboratory torsion balance experiments. This dominates the overall error in M_\odot, since GM_\odot is known to much higher precision, with a relative uncertainty below $10^{-10} from tracking and ranging data incorporated into ephemerides like JPL's DE430/432 series. Uncertainties in the (AU) have been eliminated since the 2012 IAU redefinition, which fixed the AU at exactly 149597870700 m, decoupling it from dynamical measurements and removing any associated error contribution to M_\odot. Similarly, uncertainties in planetary ephemerides, such as slight inaccuracies in or masses from numerical integrations, contribute negligibly to GM_\odot at the level of parts in $10^{12}, thanks to extensive validation against observations including flybys and occultations. Model assumptions introduce additional, though minor, sources of error through deviations from ideal Keplerian orbits. General relativistic effects, such as the perihelion of Mercury (observed at 43 arcseconds per century beyond Newtonian predictions), must be modeled explicitly in ephemerides; incomplete accounting could bias GM_\odot by up to $10^{-8}, but parametrized post-Newtonian formulations this to below $10^{-11}. The Sun's oblateness, characterized by the J_2 \approx 2 \times 10^{-7}, perturbs inner planetary orbits and induces secular changes in ; while included in modern models, uncertainties in its temporal variation (tied to and activity cycles) could affect mass estimates at the $10^{-9} level if unmodeled. As of 2024, the overall relative uncertainty in M_\odot stands at approximately $2 \times 10^{-5} (or 0.002%), dominated by G, with M_\odot = 1.98841(4) \times 10^{30} kg aligning with Particle Data Group evaluations updated from CODATA inputs. The motion of the solar system barycenter, driven by planetary masses totaling about 0.135% of M_\odot, is fully accounted for in barycentric ephemerides, with planetary mass uncertainties (e.g., Jupiter's at 0.03%) propagating to negligible errors in GM_\odot after corrections. These limitations are mitigated through cross-validation with independent techniques. Pulsar timing arrays, such as the International Pulsar Timing Array, detect Shapiro delays from solar system bodies in pulse arrival times, providing constraints on ephemerides and GM_\odot at the 0.1% level for the total planetary mass and better for individual components, independent of direct ranging. Lunar laser ranging similarly refines solar perturbations on the Earth-Moon system, contributing to ephemeris accuracy and indirect validation of GM_\odot via long-baseline gravitational modeling, with residuals below 1 cm yielding uncertainties under $10^{-11} relative.

Temporal Changes in Estimates

In the 18th and 19th centuries, estimates of the solar mass fluctuated significantly due to limited precision in orbital observations and the gravitational constant. Isaac Newton's 1687 calculation in Philosophiæ Naturalis Principia Mathematica yielded approximately 169,000 Earth masses for the Sun, based on the Moon's orbit and assumptions about gravitational attraction comparable to Earth's surface gravity. Subsequent refinements using planetary orbital data, such as those by Alexis Clairaut in the mid-18th century and Simon Newcomb in the late 19th century, raised the value to a range of roughly 200,000 to 400,000 Earth masses, reflecting improved measurements of planetary distances and periods but still affected by uncertainties in the astronomical unit. By the mid-20th century, estimates stabilized as radar ranging and space-based observations enhanced accuracy. In the , the accepted value settled around 332,000 masses, derived from refined planetary ephemerides incorporating early radar data from and Mercury. The 1970s brought further adjustment to approximately 333,000 masses through radar measurements of 's , which provided precise values for the Earth-Sun distance and thus the solar gravitational parameter GM_⊙, enabling better separation of the Sun's mass from the still-uncertain G. In the , the solar mass has been expressed primarily in kilograms, with the 2000s value of 1.989 × 10^{30} kg adopted by the (IAU) based on the 1994 system of astronomical constants and early precision ephemerides. The 2024 Particle Data Group evaluation, incorporating 2022 CODATA inputs, refined the value to 1.98841(4) × 10^{30} kg. These changes stem from advancements in measuring , such as the 2022 CODATA value of 6.67430 × 10^{-11} m^3 kg^{-1} s^{-2}, and mission-derived ephemerides, rather than any physical alteration in the Sun's mass, which remains constant on human timescales at an estimated loss rate of about 10^{-14} solar masses per year via .

Applications and Significance

Stellar and Galactic Contexts

The solar mass serves as a central benchmark in stellar evolution, particularly on the Hertzsprung-Russell (HR) diagram, where it defines the position for main-sequence stars of spectral type G2V, with higher-mass stars appearing toward the upper left (hotter and more luminous) and lower-mass stars toward the lower right. This scaling reflects how stellar properties like temperature, radius, and luminosity vary systematically with mass, enabling astronomers to model evolutionary tracks relative to the Sun's 10-billion-year main-sequence lifetime. For instance, the main-sequence lifetime τ scales approximately as τ ∝ M^{-2.5}, where M is the stellar mass in solar units, meaning massive stars exhaust their hydrogen fuel far more quickly than solar-mass counterparts due to their higher luminosities. A key relation underpinning this evolution is the mass-luminosity relation for main-sequence stars, approximated as L ∝ M^{3.5} for solar-like stars with masses between about 0.43 and 2 masses, where L is in solar units. This power-law dependence arises from the interplay of rates and in stellar interiors, leading to exponentially greater energy output for more massive stars. The relation has profound implications for stellar zones, as higher from more massive stars expands and shifts these zones farther from the host star, potentially allowing liquid water on orbiting at greater distances but shortening the stable period due to rapid evolution. In galactic dynamics, the solar mass unit facilitates estimates of total galactic masses through observations of orbital velocities and rotation curves. For the , dynamical models incorporating stellar and gas motions yield a total mass of approximately 2 × 10^{11} solar masses (as of 2023), with recent 2025 estimates from data placing the virial mass at ~0.8 × 10^{12} solar masses; the Sun's position at about 8 kiloparsecs from the center contributes to these calculations via its of roughly 220 km/s. Recent data indicate a Keplerian decline in the rotation curve beyond the visible disk, suggesting a more centralized mass distribution with contributing about two-thirds of the total mass (~1.4 × 10^{11} solar masses as of 2023). The solar mass also delineates critical thresholds in end-stage stellar phenomena, such as the of 1.4 solar masses, beyond which fails to support a against , potentially triggering a in systems. For more massive progenitors, core-collapse supernovae occur in with initial masses exceeding about 8 solar masses, where the iron exceeds the , leading to rapid infall and explosive rebound that disperses outer layers and may form neutron stars or black holes. These limits highlight the solar mass's role in predicting diverse galactic contributions from stellar remnants.

Exoplanetary and Cosmological Uses

In detection, the solar mass serves as a fundamental unit for scaling stellar properties that influence observational sensitivities. In the radial velocity method, the star's wobble velocity amplitude Δv is proportional to Δv ∝ (M_planet sin i) / M_star^{2/3}, where M_star is expressed in solar masses (M_☉), making lower-mass host stars more amenable to detecting smaller planets due to amplified signals. Similarly, transit timing variations (TTVs) in multi-planet systems probe perturbations scaled by the ratio of planetary masses to the host star's mass in M_☉, enabling detection of Earth-mass companions through timing deviations on the order of minutes to hours for Jupiter-mass perturbers around -mass stars. For planetary system stability, the solar mass normalizes the Hill radius, which defines the region where a planet's dominates over the star's, given by r_H ≈ a ( / (3 M_☉))^{1/3}, with a as the semi-major axis; this approximation holds for low-mass ratios typical of exoplanets. In the Solar System, Jupiter's mass of approximately 0.001 M_☉ yields a Hill radius extending to about 0.35 at its orbital distance of 5.2 , illustrating how systems with stars near 1 M_☉ maintain stable architectures akin to our own, while deviations in stellar mass alter packing limits for habitable zones. In cosmological contexts, the solar mass quantifies thresholds, such as the mass, which sets the minimum fragment size for in primordial gas clouds; for Population III stars in the early , this scales to roughly 10–100 M_☉ under metal-poor conditions with temperatures around 10^4 K. Additionally, stars, with masses typically 4–20 M_☉, provide mass-calibrated period-luminosity relations that anchor the , contributing to Hubble constant (H_0) estimates by linking models to observed distances in the range 70–74 km s^{-1} Mpc^{-1}. Recent advances from the (JWST) in 2025 have leveraged solar-mass units to analyze stellar mass functions in high-redshift (z > 10) galaxies, revealing observations of systems appearing to exceed 10^9 M_⊙ in stellar mass, potentially due to overestimation from assumptions in initial mass function and star formation history, consistent with standard cold dark matter models.

Related Units and Comparisons

Other Astronomical Mass Units

In astronomy, the Earth mass (M_\oplus), defined as the mass of , serves as a standard unit for expressing the masses of terrestrial planets, moons, and small solar system bodies. It is approximately $3.003 \times 10^{-6} solar masses (M_\odot), based on Earth's mass of $5.97217 \times 10^{24} kg and the solar mass of $1.989 \times 10^{30} kg. This unit is particularly useful in the context of the solar system, where planetary masses are often compared relative to Earth's to assess , density, and dynamical interactions. The Jupiter mass (M_\mathrm{J}), equivalent to the mass of Jupiter, is another key unit employed for gas giants, exoplanets, and substellar objects such as brown dwarfs. It corresponds to about $9.545 \times 10^{-4} M_\odot, derived from Jupiter's mass of $1.89813 \times 10^{27} kg. Astronomers favor M_\mathrm{J} for characterizing objects in the planetary-to-brown-dwarf transition, where masses range from a few to tens of Jupiter masses, as it provides scale for formation mechanisms and atmospheric properties. For natural satellites and minor bodies, the lunar mass (M_\mathrm{L} or M_\moon) is commonly used, representing the mass of Earth's at approximately $7.342 \times 10^{22} , or $0.0123 M_\oplus (from an Earth-Moon mass ratio of 81.3001), which equates to about $3.7 \times 10^{-8} M_\odot. This unit aids in modeling orbital dynamics and tidal effects in planetary satellite systems. These units complement the solar mass by offering finer scales for solar system and exoplanetary studies: M_\oplus for rocky worlds and inner system objects, M_\mathrm{J} for massive planets and failed stars, and M_\mathrm{L} for moons, without deriving directly from solar mass calculations.

Conversions to SI and Other Systems

The solar mass M_\odot is defined as equivalent to $1.9885 \times 10^{30} in the (SI), providing a standard reference for expressing stellar masses in SI terms. The inverse conversion yields $1 kg = 5.03 \times 10^{-31} M_\odot, facilitating transformations between astronomical and terrestrial mass scales. In energy terms, the rest of one solar mass follows from Einstein's mass- equivalence E = M_\odot c^2, where c is the , resulting in approximately $1.79 \times 10^{47} joules; this underscores the immense scale of stellar energy potentials. For atomic-scale comparisons, one solar mass corresponds to roughly $1.2 \times 10^{57} unified units (u), with u = 1.660539 \times 10^{-27} based on one-twelfth the mass of a atom. Practical conversions in scientific computing and simulations often employ the scalar multiplication M (kg) = 1.9885 \times 10^{30} \times (M / M_\odot), enabling seamless integration of solar mass data into -based models. The 2019 redefinition of base units, which established exact values for constants such as c and Planck's constant h, indirectly influences solar mass conversions by stabilizing the kilogram definition while preserving uncertainty in the G, the key link between the precise solar mass parameter GM_\odot and M_\odot in kilograms.

References

  1. [1]
    NASA/Marshall Solar Physics
    Sun Facts. Solar radius = 695,990 km = 432,470 mi = 109 Earth radii; Solar mass = 1.989 × 1030 kg = 4.376 × 1030 lb = 333,000 Earth masses; Solar luminosity ...
  2. [2]
    Orbits and Kepler's Laws - NASA Science
    May 2, 2024 · Newton's version of Kepler's third law allows us to calculate the masses of any two objects in space if we know the distance between them and ...
  3. [3]
    [PDF] 2. Astrophysical Constants and Parameters - Particle Data Group
    Solar mass. M. 1.988 41(4) × 1030 kg. [10] nominal Solar equatorial radius. R. 6.957 × 108 m exact [11] nominal Solar constant. S. 1361 W m−2 exact [11,12].
  4. [4]
    Solar Mass - an overview | ScienceDirect Topics
    In subject area: Physics and Astronomy. Solar mass is defined as the mass of the Sun, which is estimated to be approximately 2×10^30 kg, and is 300 million ...
  5. [5]
    Black Hole Types - NASA Science
    Oct 22, 2024 · Astronomers generally divide black holes into three categories according to their mass: stellar-mass, supermassive, and intermediate-mass.
  6. [6]
    Estimates of the change rate of solar mass and gravitational ...
    To estimate the mass that is carried away with the solar wind, averaged over the solar cycle, we used data from the Ulysses spacecraft (NASA). Ulysses ...<|control11|><|separator|>
  7. [7]
    Solar Mass | COSMOS
    - **Definition**: Solar mass (M⊙) is the mass of the Sun, equal to (1.989±0.004) × 10³⁰ kg, approximately 333,000 times the mass of Earth.
  8. [8]
    solar mass - Einstein-Online
    In astronomy, the solar mass is frequently used as a unit of mass ("Neutron stars typically have a mass of 1.4 solar masses"), sometimes written as M⊙. mass.
  9. [9]
    Units in Space - Museum of Science
    Oct 1, 2024 · Once you're talking about things star-sized and above, solar masses is actually the favored unit of mass measurement for astronomers, so we ...
  10. [10]
    New Jersey Institute of Technology
    In fact, the mass of the Sun M☉ is such a fundamental unit in stellar astrophysics that it is called a solar mass.
  11. [11]
    Solar Mass Symbol Definition - National Radio Astronomy Observatory
    Jun 27, 2024 · Answer: That symbol indicates a mass given in multiples of the mass of the Sun. NASA provides a nice listing of symbols for solar system objects ...<|control11|><|separator|>
  12. [12]
    [PDF] 2. Astrophysical Constants and Parameters - Particle Data Group
    Solar mass. M. 1.988 41(4) × 1030 kg. [10] nominal Solar equatorial radius. R. 6.957 × 108 m exact [11] nominal Solar constant. S. 1361 W m−2 exact [11,12].
  13. [13]
    [PDF] CODATA RECOMMENDED VALUES OF THE FUNDAMENTAL ...
    CODATA RECOMMENDED VALUES OF THE FUNDAMENTAL PHYSICAL CONSTANTS: 2022. NIST SP 961 (May 2024). An extensive list of constants is available on the NIST Physics ...
  14. [14]
    Kepler's Laws of Planetary Motion - NASA Earth Observatory
    Jul 7, 2009 · Kepler's third law shows that there is a precise mathematical relationship between a planet's distance from the Sun and the amount of time it ...
  15. [15]
    The Mathematical Principles of Natural Philosophy | Project Gutenberg
    NEWTON'S PRINCIPIA. THE MATHEMATICAL PRINCIPLES OF NATURAL PHILOSOPHY,. BY SIR ISAAC NEWTON;. TRANSLATED INTO ENGLISH BY ANDREW MOTTE. TO WHICH IS ADDED.
  16. [16]
    Solar Physics Historical Timeline (1600 - 1799)
    1687: The mass of the Sun​​ Newton argued that stable planetary orbits resulted from a balance between centripetal and gravitational acceleration; In doing so he ...<|separator|>
  17. [17]
    Radar determination of the Astronomical Unit - NASA ADS
    The time-delay and Doppler shift data yield a value for the Astronomical Unit of 499.0052 ± 0.001 light-sec.<|separator|>
  18. [18]
    Chapter: 6 Planetary Radar Astronomy
    During the 1960s, radar astronomy made major contributions to our knowledge of the solar system and to basic physics. These included a significant ...
  19. [19]
    The astronomical unit determined by radar reflections from Venus
    The Doppler shift is a function of (1) the velocity of the center of mass of Venus at the instant the wave front strikes the surface of the planet with respect ...Missing: refinement | Show results with:refinement
  20. [20]
    Gravity field of the Jovian system from Pioneer and Voyager tracking ...
    ... masses of the Sun and the remaining planetary systems are taken from JPL Development Ephemeris 118 (Newhall et al. 1983). A priori uncertainties for these ...
  21. [21]
    Fact Sheet - ESA Science & Technology
    Hipparcos is an acronym for High Precision Parallax Collecting Satellite. This name, and that of Tycho, honour great astrometrists of classical and early ...
  22. [22]
    The I.A.U. 1976/1979 System of Fundamental Astronomical Constants
    ... constant of gravitation G, that is, L~2T2. The length A is also called the unit distance. 1. Gaussian gravitational constant Primary (fundamental) constants 2.
  23. [23]
    Dynamical Masses of 20 Asteroids Determined with Gaia DR3 ...
    Aug 4, 2023 · Specifically, we will take advantage of modified Encke's equation of motion to screen perturbations to construct a dynamical model complete ...
  24. [24]
    Gaia DR4 content - ESA Cosmos - European Space Agency
    Mar 27, 2025 · Gaia DR4 includes 500 TB of data, 2.7 billion sources, a 2 billion high-quality subset, and tables for astrometry, photometry, spectroscopy, ...Missing: refinement | Show results with:refinement
  25. [25]
    Gaia Data Release 3 - The Solar System survey
    The third data release by the Gaia mission of the European Space Agency (DR3) is the first release to provide the community with a large sample of observations.
  26. [26]
    ESA - Plato factsheet - European Space Agency
    Spacecraft and instruments: Plato will have a launch mass of about 2300 kg and a size of 3.5 x 3.1 x 3.7 metres when stowed during launch. Once its solar panels ...
  27. [27]
    [PDF] RESOLUTION B2 - SYRTE - Observatoire de Paris
    gravitational constant (k) takes the value of 0.017 202 098 95 when the units of measurements are the astronomical unit of length, mass and time. The dimensions ...
  28. [28]
    The fixing of the gaussian gravitational constant and ... - NASA ADS
    A considerable number of people think of the Gaussian k.~ as being defined by k~ = Gm® where G is the gravitational constant and in~ is the mass of the Sun, so ...
  29. [29]
    Kepler's Third Law - Physics
    Kepler's Third Law: T2 = (4π2/GM) r3. For an system like the solar system, M is the mass of the Sun. So the constant in the brackets is the same for every ...Missing: calculation | Show results with:calculation
  30. [30]
    kepler_3rd_law.html - UNLV Physics
    p_yr**2 = r_AU**3, where p_yr is orbital period in sidereal years and r_AU is mean orbital radius in astronomical units (AU). This formula applies only to Solar ...
  31. [31]
    Kepler's Third Law | Imaging the Universe - Physics and Astronomy
    Note that if the mass of one body, such as M1, is much larger than the other, then M1+M2 is nearly equal to M1. In our solar system M1 = 1 solar mass, and this ...Missing: calculation | Show results with:calculation
  32. [32]
    Astronomical Radar: Illuminating our Understanding of the Solar ...
    Dec 15, 2021 · Because the distance and motion measurements of radar are extremely precise, astronomers can use astronomical radar to obtain the precise orbit ...
  33. [33]
    Solar system expansion and strong equivalence principle as seen ...
    Jan 18, 2018 · MESSENGER and Mercury-combined orbit determination. The MESSENGER mission collected spacecraft radio tracking data near Mercury between January ...
  34. [34]
    Use of MESSENGER radioscience data to improve planetary ...
    The primary objectives of this work are to determine the precise orbit of the spacecraft around Mercury using radioscience data and then to improve the ...
  35. [35]
    Newtonian constant of gravitation - CODATA Value
    Newtonian constant of gravitation $ G $. Numerical value, 6.674 30 x 10-11 m3 kg-1 s-2. Standard uncertainty, 0.000 15 x 10-11 m3 kg-1 s-2.
  36. [36]
    NOMINAL VALUES FOR SELECTED SOLAR AND PLANETARY ...
    In this brief communication we provide the rationale for and the outcome of the International Astronomical Union (IAU) resolution vote at the XXIXth General ...
  37. [37]
    Planetary Physical Parameters - JPL Solar System Dynamics
    The following tables contain selected physical characteristics of the planets and dwarf planets, respectively. Table column headings are described below.
  38. [38]
    Solar oblateness and Mercury's perihelion precession
    Solar oblateness resulting from the rotation of the Sun distorts the gravitational force acting on a planet and disturbs its Keplerian motion.
  39. [39]
    Measuring the mass of solar system planets using pulsar timing - arXiv
    Aug 21, 2010 · High-precision pulsar timing relies on a solar-system ephemeris in order to convert times of arrival (TOAs) of pulses measured at an observatory ...
  40. [40]
    Detecting the errors in solar system ephemeris by pulsar timing
    Aug 10, 2025 · Since these planetary ephemerides cannot be perfect, a method of detecting the associated errors based on a pulsar timing array is developed.<|control11|><|separator|>
  41. [41]
    Newton's Determination ofthe Masses and Densities - jstor
    Newton's values for the masses of the sun, Jupiter, Saturn, and the earth ... computations of mass to Mercury, Venus, and Mars. Newton's second discussion of the ...Missing: estimate | Show results with:estimate
  42. [42]
    On the Early History of the Sun and the Formation of the Solar System.
    THE ANGULAR VELOCITY OF THE SUN CALCULATED FROM THE MASS DISTRIBUTION IN THE PLANETARY SYSTEM As an analysis has shown, the mass distribution within the ...
  43. [43]
    Astronomical constants and planetary ephemerides deduced from ...
    A number of astronomical constants have been deduced by processing planetary radar data spannng the interval from 1959 to July 1966 and U. S. Naval Observatory ...Missing: estimate 1960s 1970s
  44. [44]
    The Determination of Planetary Masses from Radio Tracking of ...
    This paper reviews the progress in recent years in determining the masses of the terrestrial planets through radio tracking information from space probes ...
  45. [45]
    [PDF] CODATA RECOMMENDED VALUES OF THE FUNDAMENTAL ...
    CODATA RECOMMENDED VALUES OF THE FUNDAMENTAL PHYSICAL CONSTANTS: 2018. NIST SP 961 (May 2019). An extensive list of constants is available on the NIST Physics ...
  46. [46]
    22.1 Evolution from the Main Sequence to Red Giants
    This means that the equation shown above can be simplified such that the lifetime of the star T = 1 / M 2.5 where T is in solar lifetimes and M is in solar ...
  47. [47]
    [PDF] Lecture 7: Stellar evolution I: Low-mass stars
    Mar 21, 2018 · τ ∝ M. −2. More accurate calculations give τ ∝ M. −2.5 so ... Main sequence lifetime exceeds age of Universe low-mass: 0.7M <M< 2M ...
  48. [48]
    The Mass-Luminosity Relationship | ASTRO 801
    L≈M3.5. This is usually referred to as the mass-luminosity relationship for Main Sequence stars. For a sample plot of this relationship see: astronomynotes ...
  49. [49]
    Lecture 2: Stars: Habitable Zones, Lifetimes, and Other Considerations
    M = mass; L = luminosity: For the Sun: lifetime = 10 Gyr if f=10% of the Sun's H burned into He with epsilon=0.7% efficiency. Lifetime as a function of Mass.
  50. [50]
    IoW_20230927 - Gaia - ESA Cosmos - European Space Agency
    Sep 27, 2023 · Until now, the Milky Way was estimated to weigh about 10 solar masses. Part of this mass consists of the ordinary matter like stars and ...
  51. [51]
    mass distribution in disk galaxies
    There are two major methods to measure the mass distribution using rotation curves, which are the direct method and the decomposition method.
  52. [52]
    https://www.cosmos.esa.int/web/gaia/iow_20230927
  53. [53]
    [PDF] the physics of core-collapse supernovae - arXiv
    The starting point is a star heavier than about 8 solar masses that has passed through successive stages of hydrogen, helium, carbon, neon, oxygen. Page 2. and ...
  54. [54]
    Detectability of extrasolar planets in radial velocity surveys
    For a mass MP, the velocity amplitude is. formula. 30. where P is the orbital period, MP is the mass of the planet and M⋆ is the mass of the star. In Figs. 12 ...Missing: M_star solar
  55. [55]
    Using long-term transit timing to detect terrestrial planets
    We propose that the presence of additional planets in extrasolar planetary systems can be detected by long-term transit timing studies. If a transiting planet ...
  56. [56]
    Generalized Hill-stability criteria for hierarchical three-body systems ...
    The natural length-scale of stability is the mutual Hill radius rH = aout(μ/3)1/3, where aout is the distance from the distant outer body with mass mout to the ...
  57. [57]
    The Birth Mass Function of Population III Stars - IOPscience
    The first studies suggested that Population III stars have typical masses of a few hundred solar masses and form in isolation, one per halo (Abel et al.
  58. [58]
    The Hubble Constant - Wendy L. Freedman & Barry F. Madore
    The Hubble constant is usually expressed in units of kilometers per second per megaparsec, and sets the cosmic distance scale for the present Universe.
  59. [59]
    Explaining the "too massive" high-redshift galaxies in JWST data
    Jul 29, 2025 · The James Webb Space Telescope has discovered high luminosity galaxies that appear to be "too many" and "too massive" compared to predictions of ...Missing: advances | Show results with:advances
  60. [60]
    Earth-mass planets with He atmospheres in the habitable zone of ...
    Jun 12, 2025 · We find that Earth-like planets with masses between ~0.95 M ⊕ and 1.25 M ⊕ inside the habitable zone of Sun-like stars can end up with He-dominated primordial ...
  61. [61]
    Isolated Planetary-Mass Object SIMP 0136 (Artist's Concept)
    Aug 28, 2025 · SIMP 0136 is about 13 times the mass of Jupiter. Although it is ... Brown Dwarfs · Exoplanet Atmosphere · Exoplanets · James Webb Space ...
  62. [62]
    [PDF] Determination of the Masses of the Moon and Venus and the ...
    Determination of Earth-Moon mass ratio. 4. Determination of astronomical unit and the mass of Venus. 5. Simultaneous solution for all constants. E. Summary of ...
  63. [63]
    Moon | Glenn Research Center - NASA
    Jul 7, 2025 · The mass of the Moon is approximately 8.1 x 1019 tons (7.3 x 1022 kg or .01 x Earth mass). The mean diameter of the Moon is 2,159 miles ...Moon · Moon's Formation · Atmosphere of Moon
  64. [64]
    https://science.nasa.gov/asset/webb/isolated-planetary-mass-object-simp-0136-artists-concept/
  65. [65]
    https://ntrs.nasa.gov/api/citations/19670019851/downloads/19670019851.pdf
  66. [66]
    [PDF] arXiv:1911.10204v1 [astro-ph.IM] 22 Nov 2019
    Nov 22, 2019 · One can imagine the same for the classical astronomical units. • A rounded solar-mass unit as M = 5 × 10−6 s has already been used in this paper ...