Jansky
The jansky (symbol: Jy) is a non-SI unit of spectral flux density used in radio and infrared astronomy to quantify the power received per unit area per unit frequency interval from astronomical sources.[1] It is defined precisely as $10^{-26} watts per square metre per hertz ($10^{-26} W m^{-2} Hz^{-1}).[2] The unit is named in honor of Karl Guthe Jansky, the American radio engineer who in 1932 detected the first extraterrestrial radio signals from the Milky Way while investigating sources of static interference for transatlantic radio communications.[3] The jansky was formally adopted as the standard unit for flux density in radio astronomy by the International Astronomical Union during its 1973 General Assembly in Sydney, Australia, replacing earlier ad hoc units like the flux unit (f.u.).[4] Karl Guthe Jansky (October 22, 1905 – February 14, 1950) was born in Norman, Oklahoma, to Cyril Jansky, a prominent electrical engineering professor, and grew up in Madison, Wisconsin.[5] After earning a bachelor's degree in physics from the University of Wisconsin in 1927, he joined Bell Laboratories in 1931, where he constructed a large rotatable antenna—often called the "merry-go-round"—on a 100-foot track in Holmdel, New Jersey, to study shortwave radio noise.[3] His systematic observations revealed a third type of static, distinct from local thunderstorms and atmospheric sources, that peaked every 23 hours and 56 minutes, aligning with the Earth's sidereal rotation and originating from the constellation Sagittarius near the galactic center.[3] Jansky announced his findings in a seminal paper, "Directional Studies of Atmospherics at High Frequencies," published in the Proceedings of the Institute of Radio Engineers in 1932, and presented them publicly in Washington, D.C., on April 27, 1933. Despite the groundbreaking nature of his work, Jansky's discovery received limited attention during his lifetime, partly because Bell Labs reassigned him to other projects in 1933, and he conducted no further astronomical research.[6] He continued contributing to radio technology, including advancements in radar and waveguides, until his death from chronic kidney disease at age 44 in Red Bank, New Jersey.[7] Jansky's legacy endures through the field of radio astronomy, which his observations founded; notable early followers like Grote Reber built upon his work to map the radio sky.[3] In practice, the jansky measures flux densities ranging from the faint emissions of distant galaxies (often in microjansky or nanojansky scales) to brighter sources like quasars or pulsars, which can reach thousands of janskys at centimeter wavelengths.[8] For extended sources, surface brightness is expressed in jansky per steradian (Jy sr^{-1}), while point sources are directly in Jy; conversions to other systems, such as magnitudes, are common for multi-wavelength studies.[8] The unit's small scale reflects the weak nature of cosmic radio signals, enabling precise quantification in modern observatories like the Karl G. Jansky Very Large Array, named in his honor since 2012.[9]History
Karl Jansky's contributions
Karl Guthe Jansky (1905–1950) was an American physicist and engineer whose pioneering work at Bell Laboratories laid the groundwork for radio astronomy. Born on October 22, 1905, in Norman, Oklahoma, and raised in Madison, Wisconsin, Jansky earned a Bachelor of Science degree in physics from the University of Wisconsin in 1927. He joined Bell Laboratories in 1928, where he focused on improving transatlantic radio-telephone communications by investigating sources of interference, such as atmospheric static.[10] In 1931 and 1932, Jansky constructed a large rotating directional antenna—a linear array of dipoles spanning approximately 100 feet (30 meters) mounted on wheels from a Model T Ford—to study shortwave radio static at a frequency of 20.5 MHz. This meridian transit instrument allowed systematic directional observations by rotating once every 20 minutes. Through months of meticulous measurements, Jansky classified three types of static: local thunderstorms (sharp crackles), distant thunderstorms (steady crashes every few seconds), and a third faint, steady hiss that repeated every 23 hours and 56 minutes, corresponding to the Earth's sidereal rotation period.[10][3] By plotting the signal's intensity, Jansky determined that the third type of static originated from a fixed direction in space, peaking toward the constellation Sagittarius and aligning with the plane of the Milky Way. He concluded this was extraterrestrial radio emission from the center of our galaxy, beyond the solar system, marking the first detection of cosmic radio waves.[3][10] Jansky published his findings in two seminal papers: "Directional Studies of Atmospherics at High Frequencies" in the Proceedings of the Institute of Radio Engineers in December 1932, detailing the directional properties, and "Electrical Disturbances Apparently of Extraterrestrial Origin" in October 1933, explicitly identifying the galactic source. He presented his results at the International Union of Radio Science (URSI) meeting on April 27, 1933, which garnered brief media attention, including a New York Times article on May 5, 1933. However, the astronomical community initially overlooked his work, partly due to the era's focus on optical astronomy and economic constraints limiting further research; Jansky himself shifted to defense-related projects during World War II.[11][10][3] Despite the muted reception, Jansky's innovations in directional antennas, precise frequency measurements, and systematic sky mapping pioneered radio astronomy techniques, enabling later astronomers to explore the radio universe. He also patented a radio direction-finder utilizing solar emissions, which influenced subsequent engineering developments. In recognition of his foundational discoveries, the flux density unit was named the jansky in his honor decades later.[10][3]Establishment of the unit
The jansky (Jy) was formally proposed as a unit of spectral flux density in radio astronomy by the International Astronomical Union (IAU) in 1973 to honor Karl G. Jansky's pioneering detection of cosmic radio emission in 1932.[4] The proposal was adopted during the IAU's General Assembly in Sydney, Australia, where the unit was defined as $1 \, \mathrm{Jy} = 10^{-26} \, \mathrm{W \, m^{-2} \, Hz^{-1}}, standardizing measurements that had previously relied on informal "flux units" of the same magnitude.[4][12] Prior to this formal naming, the equivalent unit had been in practical use within the astronomical community, as evidenced by the Third Cambridge Catalogue of Radio Sources (3C), published in 1959, which reported flux densities in "flux units" explicitly defined as $10^{-26} \, \mathrm{W \, m^{-2} \, (c/s)^{-1}}, demonstrating the need for a dedicated measure in radio source surveys.[13] This early application underscored the unit's utility despite lacking an official name, paving the way for its institutional recognition.[14] Although the jansky's non-SI status initially posed challenges for integration with broader scientific measurement systems, it achieved widespread acceptance in astronomical literature by the mid-1970s, becoming the standard for radio flux density reporting. Further institutional acknowledgment came in 2012, when the National Radio Astronomy Observatory (NRAO) renamed its flagship Very Large Array (VLA) the Karl G. Jansky Very Large Array to commemorate Jansky's foundational role in the field.[15]Definition and properties
Formal definition
The jansky (symbol: Jy) is a non-SI unit of spectral flux density, measuring the power received per unit area per unit frequency interval from an astronomical source.[16] It is named after Karl Jansky, the American engineer who pioneered radio astronomy.[4] The formal definition of the unit is $1 \, \mathrm{Jy} = 10^{-26} \, \mathrm{W \, m^{-2} \, Hz^{-1}}, where W denotes watts, m meters, and Hz hertz.[17] In centimeter-gram-second (CGS) units, this is equivalent to $1 \, \mathrm{Jy} = 10^{-23} \, \mathrm{erg \, s^{-1} \, cm^{-2} \, Hz^{-1}}.[18] The dimensional formula for the jansky is [\mathrm{Jy}] = [\mathrm{energy}] \, [\mathrm{time}]^{-1} \, [\mathrm{length}]^{-2} \, [\mathrm{frequency}]^{-1}, reflecting its role in quantifying energy flux per unit bandwidth.[17] Unlike total flux density, which integrates power over the entire spectrum, the jansky specifically quantifies monochromatic flux at a given frequency, enabling precise spectral analysis.[19]Relation to flux density
The spectral flux density S_\nu quantifies the amount of energy received from an astronomical source per unit time, per unit area, and per unit frequency interval, providing a measure of the source's emission at a specific frequency.[20] In radio astronomy, this quantity is typically expressed in janskys (Jy), where 1 Jy corresponds to $10^{-26} W m^{-2} Hz^{-1}.[4] The jansky unit is especially suitable for characterizing unresolved or point-like sources in radio astronomy, as these appear much smaller than the observing beam, allowing the total integrated flux to be effectively represented by the flux density at the measurement frequency rather than requiring spatial resolution.[17] For such sources, the total flux F across a broadband spectrum is given by the integral F = \int S_\nu \, d\nu, but the jansky directly measures S_\nu at discrete frequencies, facilitating precise spectral analysis without needing full bandwidth integration.[20] This unit offers key advantages for detecting weak signals from distant astronomical objects, such as galaxies with flux densities as low as $10^{-6} Jy (microjansky sources), enabling the study of faint emissions that would be challenging in other units.[21] Additionally, it avoids confusion with surface brightness measures like Jy per steradian (Jy/sr), which are more appropriate for extended sources, by focusing solely on the total energy flux density from compact emitters.[17]Conversions and equivalents
SI and CGS units
The jansky (Jy) is defined in the International System of Units (SI) as $1 \, \mathrm{Jy} = 10^{-26} \, \mathrm{W \, m^{-2} \, Hz^{-1}}, a scale chosen to accommodate the micro-power levels typical in radio astronomy measurements.[22] This equivalence arises from the unit's origins in quantifying spectral flux density, where the factor of $10^{-26} provides a convenient numerical range for observed signals without excessive scientific notation.[23] In the centimeter-gram-second (CGS) system, the jansky converts to $1 \, \mathrm{Jy} = 10^{-23} \, \mathrm{erg \, s^{-1} \, cm^{-2} \, Hz^{-1}}, derived from the relations $1 \, \mathrm{W} = 10^{7} \, \mathrm{erg \, s^{-1}} and $1 \, \mathrm{m^{2}} = 10^{4} \, \mathrm{cm^{2}}.[24] Thus, substituting yields $10^{-26} \, \mathrm{W \, m^{-2} \, Hz^{-1}} = 10^{-26} \times 10^{7} / 10^{4} = 10^{-23} \, \mathrm{erg \, s^{-1} \, cm^{-2} \, Hz^{-1}}, maintaining consistency across unit systems for flux density calculations.[24] Expressed in decibels relative to 1 W m^{-2} Hz^{-1}, where 0 dB(W m^{-2} Hz^{-1}) corresponds to 1 W m^{-2} Hz^{-1}, the jansky equates to -260 \, \mathrm{[dB](/page/DB)(W \, m^{-2} \, Hz^{-1})}, calculated as $10 \log_{10}(10^{-26}) = -260.[25] This logarithmic form is useful in radio engineering contexts for signal analysis.[25] The choice of the $10^{-26} factor aligns with typical extraterrestrial radio fluxes, which range from approximately $10^{-24} to $10^{-30} \, \mathrm{W \, m^{-2} \, Hz^{-1}} for sources like galactic emissions and distant quasars, allowing "bright" objects to register in the order of a few janskys.[23] For fainter detections, prefixes such as milli- (mJy, $10^{-3} \, \mathrm{Jy}) and micro- (μJy, $10^{-6} \, \mathrm{Jy}) are commonly employed.[23]Magnitude systems
The AB magnitude system provides a standardized way to convert flux densities measured in janskys to magnitudes, facilitating comparisons across optical and radio wavelengths. It is defined such that a source with a monochromatic flux density S_\nu = 3631 Jy at the reference frequency corresponds to an AB magnitude of zero:m_{\rm AB} = -2.5 \log_{10} \left( \frac{S_\nu}{3631 \, \rm Jy} \right),
where S_\nu is the flux density in janskys. This definition assumes a spectrum that is flat in flux density per unit frequency, making it independent of wavelength for broadband photometry. For faint sources common in radio-optical studies, an equivalent expression converts AB magnitudes to flux density in microjansky units, useful for bridging sensitivities between optical surveys and radio interferometry:
S_\nu \, [\mu\rm Jy] = 10^{6} \times 10^{\left(23 - (m_{\rm AB} + 48.6)/2.5\right)}.
This formula derives from the cgs-based zero point of the AB system and approximates the conversion for typical observational contexts. In contrast to the Vega magnitude system, which calibrates zero magnitude to the spectrum of Vega and varies with wavelength due to the star's non-flat energy distribution, the AB system is frequency-independent and ties directly to absolute flux units like the jansky. This alignment enables consistent cross-wavelength flux comparisons, particularly for sources with power-law spectra. The AB system was developed in the 1970s to support precise spectrophotometry and broadband observations, with its formal adoption driven by the need to align optical magnitudes with radio flux densities in jansky for studying quasars and other extragalactic objects. These conversions apply primarily to point sources, where the total flux density integrates over the object's angular size; for extended sources, adjustments for surface brightness (e.g., in jansky per steradian or magnitudes per square arcsecond) are required to avoid underestimating diffuse emission.[26]
Brightness temperature
In radio astronomy, brightness temperature T_b serves as a convenient measure to interpret flux densities measured in janskys as equivalent blackbody radiation temperatures, facilitating the analysis of thermal and non-thermal emissions from celestial sources. This concept is particularly relevant in the radio regime, where emissions often approximate blackbody behavior under certain conditions. The jansky, as a unit of spectral flux density S_\nu, is converted to T_b by relating it to the specific intensity I_\nu, which represents the flux per unit solid angle and frequency.[17] The standard conversion relies on the Rayleigh-Jeans (RJ) approximation to the Planck blackbody function, valid at low frequencies where h\nu \ll kT (with h Planck's constant, \nu frequency, k Boltzmann's constant, and T temperature). In this limit, the specific intensity is given byI_\nu = \frac{2 k T_b \nu^2}{c^2},
where c is the speed of light; solving for T_b yields
T_b = \frac{c^2 I_\nu}{2 k \nu^2}.
This relation defines T_b in kelvin for I_\nu expressed in consistent units, such as W m^{-2} Hz^{-1} sr^{-1}, derived from the low-frequency tail of the Planck spectral radiance B_\nu(T) \approx \frac{2 \nu^2 k T}{c^2}.[17][27] To connect this to observed flux density in janskys, note that S_\nu = \int I_\nu \, d\Omega \approx I_\nu \Omega for a compact source subtending a small solid angle \Omega (in steradians) with uniform brightness. Substituting gives
T_b = \frac{c^2 S_\nu}{2 k \nu^2 \Omega},
or equivalently in terms of wavelength \lambda = c/\nu,
T_b = \frac{\lambda^2 S_\nu}{2 k \Omega}.
Here, S_\nu is in Jy (with 1 Jy = $10^{-26} W m^{-2} Hz^{-1}), yielding T_b in K when constants are inserted numerically (e.g., the prefactor c^2 / (2 k) \approx 2.02 \times 10^{23} K Jy sr Hz^2 m^{-2}). This derivation starts from the RJ form of I_\nu, equates it to the blackbody radiance, and integrates over the source's projected area on the sky.[17][27][28] For higher frequencies where the RJ approximation breaks down (typically h\nu \gtrsim 0.1 kT), the full Planck law is employed:
I_\nu = \frac{2 h \nu^3}{c^2} \frac{1}{e^{h\nu / k T_b} - 1}.
Here, T_b is found by inverting this equation numerically for the observed I_\nu, providing a more accurate blackbody-equivalent temperature that accounts for the exponential cutoff in the Planck spectrum. This full form ensures proper interpretation of submillimeter or higher-frequency radio data, though the RJ limit suffices for most astronomical radio observations below ~100 GHz.[17][29] These conversions assume a source of uniform brightness filling the solid angle \Omega, which is often the telescope's beam solid angle for unresolved sources. In practice, this enables size estimation: for a detected flux S_\nu, the implied \Omega from an assumed T_b (e.g., based on physical models) yields the source angular diameter, or vice versa, with beam-dependent \Omega providing limits for compact objects like quasars. Such applications highlight the utility of brightness temperature in bridging flux measurements to physical source properties without direct imaging.[27][28]
Applications
Radio astronomy
The jansky (Jy) serves as the fundamental unit for measuring spectral flux density in radio astronomy, enabling precise quantification of radio emissions from celestial objects such as galaxies, quasars, and pulsars. This unit, defined as 10^{-26} W m^{-2} Hz^{-1}, allows astronomers to characterize the intensity of signals across the radio spectrum, facilitating comparisons between sources and instruments. For instance, large-scale surveys like the NRAO VLA Sky Survey (NVSS) at 1.4 GHz catalog thousands of extragalactic radio sources with integrated flux densities typically in the milliJansky (mJy) range, down to a completeness limit of approximately 3 mJy, providing a census of cosmic radio emitters including active galactic nuclei and star-forming galaxies.[30] In telescope operations, the jansky underpins sensitivity assessments for major facilities. The Karl G. Jansky Very Large Array (VLA) achieves detection limits as low as ~1 μJy (10^{-6} Jy) in its most sensitive configurations and long integrations, allowing it to resolve faint radio structures in nearby galaxies and distant quasars. Similarly, the Atacama Large Millimeter/submillimeter Array (ALMA) employs jansky units to measure continuum and line emissions in the submillimeter regime, with typical sensitivities reaching tens of μJy for point sources, crucial for studying dust-obscured star formation in protostellar disks. Historically, early radio catalogs laid the groundwork for flux measurements that evolved into the standardized jansky system. The Third Cambridge Catalogue (3C) from the 1950s listed 471 discrete radio sources with flux densities measured in arbitrary "flux units," initially calibrated against bright sources like Cygnus A, which equated to about 10^3 flux units or roughly 1000 Jy today. By the 1970s, the International Astronomical Union formalized the jansky as the standard unit for spectral flux density, replacing ad hoc scales and enabling consistent global observations, as detailed in absolute calibration efforts using primary standards like Cassiopeia A.[31][32] Contemporary research leverages the jansky to probe dynamic astrophysical phenomena. Recent VLA observations from 2023 to 2025 have measured radio emissions from protostars in star-forming regions, such as those in the Orion Nebula, with flux densities on the order of a few mJy, revealing outflow structures and accretion processes. Fast radio bursts (FRBs), transient events detected by the VLA, exhibit peak flux densities exceeding 1 Jy in their millisecond-duration pulses, aiding localization and host galaxy identification. In dwarf galaxies, VLA Sky Survey data from 2024 identify active galactic nuclei (AGN) with radio excesses at mJy levels, indicating supermassive black hole activity that influences star formation efficiency.[33] The jansky facilitates data analysis through signal-to-noise ratio (SNR) calculations, where detection sensitivity improves with the square root of integration time and bandwidth. For a source with flux density S_\nu, the required integration time t to achieve a desired SNR scales as t \propto 1 / S_\nu^2, accounting for system noise temperature and telescope gain, as derived from the radiometer equation; this relationship guides observation planning for faint sources like distant pulsars.[34][35]Gravitational wave detection
Gravitational waves carry energy that can be quantified using the jansky unit, which measures spectral flux density in units of 10^{-26} W m^{-2} Hz^{-1}. For events detected by Advanced LIGO, such as binary black hole or neutron star mergers, the equivalent peak flux density of the gravitational wave signal itself reaches approximately 10^{20} Jy at frequencies around 100 Hz, derived from the strain amplitude h \approx 10^{-21} and the relation between strain power and energy flux.[36] This conversion highlights the immense energy output of these events, though direct detection relies on interferometric methods rather than radio telescopes due to the low-frequency nature of the waves (10–1000 Hz). The jansky unit facilitates comparisons between gravitational wave energy fluxes and electromagnetic signals, underscoring the unit's versatility in multimessenger astrophysics. While gravitational waves themselves do not directly produce radio emission, binary neutron star mergers often generate electromagnetic counterparts, including radio afterglows from synchrotron emission in the merger ejecta or jet. Simulations and observations indicate that these afterglows can reach peak fluxes of several mJy in the radio band for events at distances of tens of Mpc. For instance, the binary neutron star merger GW170817, detected at 40 Mpc, exhibited a radio afterglow peaking at approximately 1 mJy at 3 GHz around 150 days post-merger, following an initial rise from early detections at ~15 μJy.[37] This emission arises from the deceleration of relativistic ejecta in the circumbinary medium, with flux levels scaled to jansky for integration with radio surveys. The relation between gravitational wave strain h and observable flux involves the energy released during the merger, which powers the electromagnetic counterpart. Peak fluxes are estimated from numerical simulations incorporating the merger's luminosity, ejecta velocity, and ambient density, yielding S_\nu \propto E / d^2, where E is the isotropic-equivalent energy output and d is the distance; these are then expressed in jansky for direct comparison with radio observations. For GW170817, the optical peak was dominant initially, but the radio tail persisted at mJy levels, consistent with structured jet models.[38] Detecting these counterparts poses significant challenges due to their transient nature and faintness. Prompt electromagnetic emission, if present, lasts less than 1 second and spans high frequencies from gamma rays to potentially radio, necessitating wideband arrays capable of rapid follow-up over large sky areas localized by LIGO/Virgo/KAGRA (typically 10–1000 deg²). Current radio telescopes, such as the Karl G. Jansky Very Large Array, achieve detection limits of ~0.1 mJy for 1-second integrations in prompt searches for LIGO events (assuming L-band with ~1 GHz bandwidth), far above typical afterglow peaks but sufficient to constrain models of coherent emission.[39] Afterglows evolve over days to months, allowing deeper integrations down to μJy, yet localization uncertainties and variable sky coverage limit detections to nearby events (<100 Mpc). Recent advancements in multimessenger astronomy emphasize the role of next-generation facilities like the Square Kilometre Array (SKA), with studies from 2023–2025 proposing its use for routine detection of radio counterparts to gravitational wave events at nanojansky (nJy) sensitivities. The SKA's wide-field capabilities and improved point-source sensitivity (~1 nJy for 1-hour integrations at 1 GHz) would enable blind searches over thousands of square degrees, identifying afterglows from off-axis mergers up to 200 Mpc and enhancing distance measurements via standard sirens. Theoretical frameworks for these fluxes follow S_\nu \propto (distance)^{-2} \times energy output, scaled to jansky to benchmark against electromagnetic sources like gamma-ray bursts, facilitating joint analyses of merger energetics and environments.[40]Other uses
In planetary science, the jansky is employed to quantify radio emissions from magnetospheric interactions, particularly in observations and simulations of Jupiter's decametric radiation, which arises from electron cyclotron maser instability in its auroral regions and can reach peak flux densities of approximately 10^6 Jy at frequencies around 12–27 MHz when normalized to 1 AU.[41] Simulations of exoplanet magnetospheres, such as those using tools like the Exoplanetary and Planetary Radio Emissions Simulator (ExPRES), model similar coherent emissions from hypothetical planetary-scale magnetic fields, expressing predicted flux densities in jansky to assess detectability with current radio arrays.[42] In engineering applications, particularly radar astronomy, the jansky calibrates the flux density of planetary radar echoes, enabling precise characterization of near-Earth asteroids; for instance, Arecibo Observatory's S-band system measured system equivalent flux densities around 38 Jy, facilitating the detection and imaging of asteroid surfaces through echo power analysis in jansky units.[43] These calibrations are crucial for determining asteroid sizes, shapes, and rotation states, as radar returns from icy bodies like Europa have been quantified in jansky to study surface properties and subsurface structures.[44] Interdisciplinary uses extend to solar physics and communications engineering, where type III solar radio bursts—produced by electron beams streaming along coronal magnetic fields—exhibit flux densities up to 10^12 Jy at 1 MHz, observed with ground-based arrays like the Nançay Radioheliograph to trace particle acceleration during flares.[45] In satellite communications, the jansky models noise from unintended electromagnetic radiation, such as broadband emissions from Starlink satellites detected at levels of several jansky in the 110–188 MHz band, informing interference mitigation strategies for protected radio astronomy bands.[46] Emerging applications in cosmology include the jansky's role in cosmic microwave background (CMB) foreground subtraction for next-generation experiments succeeding Planck, where radio point sources at microjansky (μJy) levels—such as those contributing to the extragalactic background light—are cataloged and removed from multifrequency maps to isolate primordial signals.[47] Techniques like convolutional neural networks applied to Planck data achieve residual foregrounds below 1 μJy, enhancing precision in polarization measurements for inflation studies.[48] Despite these uses, the jansky remains less common outside astronomy due to its non-SI nature, with engineering contexts often favoring watt per square meter per hertz (W m⁻² Hz⁻¹) for broader compatibility in system design and regulatory standards.[49] This limitation arises from the unit's origin in weak extraterrestrial signals, making direct SI conversions essential for interdisciplinary integration, such as in telecommunication link budgets where flux densities are recast in decibels relative to 1 Jy (dBJy).Examples and scales
Orders of magnitude
The orders of magnitude of flux densities measured in janskys span a vast range in radio astronomy, from intense terrestrial and solar phenomena at the high end to faint cosmic signals at the low end, illustrating the dynamic range required for observations. This logarithmic scale provides context for the relative strengths of various sources and interferences, influencing telescope design and detection strategies. Representative examples highlight key regimes without exhaustive listings.| log₁₀(Jy) | Example Category |
|---|---|
| 10 | Extreme solar radio bursts at low frequencies (MHz), reaching fluxes of order 10¹⁰ Jy due to coherent plasma emission during flares. |
| 9 | Intense solar radio bursts at meter wavelengths, up to ~10⁹ Jy in coherent plasma emissions. |
| 8 | Strong terrestrial radio frequency interference, such as from GSM signals, with flux densities up to 10⁸ Jy in populated areas.[50] |
| 7 | Active Sun or planetary radio bursts at decameter wavelengths, around 10⁷ Jy for Jupiter's decametric emissions.[51] |
| 6 | Quiet Sun at centimeter wavelengths, approximately 10⁶ Jy at 10 GHz from thermal coronal emission.[52] |
| 3 | Brightest extragalactic radio sources, such as quasars with fluxes up to 10³ Jy at low frequencies, and galactic plane emission from the Milky Way around 1000 Jy at 10 GHz due to synchrotron radiation.[53] |
| 1.5 | Prominent quasars like 3C 273, with core flux density ~30 Jy at ~1 GHz.[54] |
| 0 | Typical quasars and radio galaxies, around 1 Jy at GHz frequencies. |
| -3 | Typical nearby galaxies, with integrated flux densities ~1 mJy at 1.4 GHz from star formation and AGN activity.[55] |
| -6 | Distant galaxies in deep radio surveys, such as microjansky sources at z ~ 1–2 with fluxes ~10 μJy at 1.4 GHz.[56] |
| -9 | Faint sources in ultra-deep fields, nanojansky detections of high-redshift galaxies ~10 nJy at 1.4 GHz.[57] |
| -12 | Cosmic microwave background fluctuations, equivalent to ~10⁻¹² Jy in small angular scales after beam dilution.[58] |
| -26 | Hypothetical ultra-weak cosmic signals or the fundamental unit scale, defining the baseline sensitivity limit for point sources.[39] |