Orders of magnitude (energy)

Last updated

This list compares various energies in joules (J), organized by order of magnitude.

Contents

Below 1 J

List of orders of magnitude for energy
Factor (joules) SI prefix ValueItem
10−34 6.626×10−34 J Energy of a photon with a frequency of 1 hertz. [1]
 8×10−34 J Average kinetic energy of translational motion of a molecule at the lowest temperature reached (38 picokelvin [2] as of 2021)
10−30 quecto- (qJ)
10−28 6.6×10−28 JEnergy of a typical AM radio photon (1 MHz) (4×10−9 eV) [3]
10−27 ronto- (rJ)
10−24 yocto- (yJ)1.6×10−24 JEnergy of a typical microwave oven photon (2.45 GHz) (1×10−5 eV) [4] [5]
10−23 2×10−23 J Average kinetic energy of translational motion of a molecule in the Boomerang Nebula, the coldest place known outside of a laboratory, at a temperature of 1 kelvin [6] [7]
10−22 2–3000×10−22 JEnergy of infrared light photons [8]
10−21 zepto- (zJ)1.7×10−21 J1 kJ/mol, converted to energy per molecule [9]
2.1×10−21 J Thermal energy in each degree of freedom of a molecule at 25 °C (k T/2) (0.01 eV) [10]
2.856×10−21 JBy Landauer's principle, the minimum amount of energy required at 25 °C to change one bit of information
3–7×10−21 JEnergy of a van der Waals interaction between atoms (0.02–0.04 eV) [11] [12]
4.1×10−21 JThe "k T" constant at 25 °C, a common rough approximation for the total thermal energy of each molecule in a system (0.03 eV) [13]
7–22×10−21 JEnergy of a hydrogen bond (0.04 to 0.13 eV) [11] [14]
10−20 4.5×10−20 JUpper bound of the mass–energy of a neutrino in particle physics (0.28 eV) [15] [16]
10−19 1.602176634×10−19 J1 electronvolt (eV) by definition. This value is exact as a result of the 2019 revision of SI units. [17]
3–5×10−19 JEnergy range of photons in visible light (≈1.6–3.1 eV) [18] [19]
3–14×10−19 JEnergy of a covalent bond (2–9 eV) [11] [20]
5–200×10−19 JEnergy of ultraviolet light photons [8]
10−18 atto- (aJ)1.78×10−18 JBond dissociation energy for the carbon monoxide (CO) triple bond, alternatively stated: 1072 kJ/mol; 11.11eV per molecule. [21]

This is the strongest chemical bond known.

2.18×10−18 JGround state ionization energy of hydrogen (13.6 eV)
10−17 2–2000×10−17 JEnergy range of X-ray photons [8]
10−16   
10−15 femto- (fJ)3 × 10−15 JAverage kinetic energy of one human red blood cell. [22] [23] [24]
10−14 1×10−14 J Sound energy (vibration) transmitted to the eardrums by listening to a whisper for one second. [25] [26] [27]
> 2×10−14 JEnergy of gamma ray photons [8]
2.7×10−14 JUpper bound of the mass–energy of a muon neutrino [28] [29]
8.2×10−14 JRest mass–energy of an electron [30] (0.511 MeV) [31]
10−13 1.6×10−13 J1 megaelectronvolt (MeV) [32]
2.3×10−13 JEnergy released by a single event of two protons fusing into deuterium (1.44 megaelectronvolt MeV) [33]
10−12 pico- (pJ)2.3×10−12 JKinetic energy of neutrons produced by DT fusion, used to trigger fission (14.1 MeV) [34] [35]
10−11 3.4×10−11 JAverage total energy released in the nuclear fission of one uranium-235 atom (215 MeV) [36] [37]
10−10 1.492×10−10 J Mass-energy equivalent of 1 Da [38] (931.5 MeV) [39]
1.503×10−10 JRest mass–energy of a proton [40] (938.3 MeV) [41]
1.505×10−10 JRest mass–energy of a neutron [42] (939.6 MeV) [43]
1.6×10−10 J1 gigaelectronvolt (GeV) [44]
3×10−10 JRest mass–energy of a deuteron [45]
6×10−10 JRest mass–energy of an alpha particle [46]
7×10−10 JEnergy required to raise a grain of sand by 0.1mm (the thickness of a piece of paper). [47]
10−9 nano- (nJ)1.6×10−9 J10 GeV [48]
8×10−9 JInitial operating energy per beam of the CERN Large Electron Positron Collider in 1989 (50 GeV) [49] [50]
10−8 1.3×10−8 J Mass–energy of a W boson (80.4 GeV) [51] [52]
1.5×10−8 J Mass–energy of a Z boson (91.2 GeV) [53] [54]
1.6×10−8 J100 GeV [55]
2×10−8 J Mass–energy of the Higgs Boson (125.1 GeV) [56]
6.4×10−8 JOperating energy per proton of the CERN Super Proton Synchrotron accelerator in 1976 [57] [58]
10−7 1×10−7 J≡ 1 erg [59]
1.6×10−7 J1 TeV (teraelectronvolt), [60] about the kinetic energy of a flying mosquito [61]
10−6 micro- (μJ)1.04×10−6 JEnergy per proton in the CERN Large Hadron Collider in 2015 (6.5 TeV) [62] [63]
10−5   
10−4 1.0×10−4 JEnergy released by a typical radioluminescent wristwatch in 1 hour [64] [65] (1 μCi × 4.871 MeV × 1 hr)
10−3 milli- (mJ)3.0×10−3 JEnergy released by a P100 atomic battery in 1 hour [66] (2.4 V × 350 nA × 1 hr)
10−2 centi- (cJ)4.0×10−2 JUse of a typical LED for 1 second [67] (2.0 V × 20 mA × 1 s)
10−1 deci- (dJ)1.1×10−1 JEnergy of an American half-dollar falling 1 metre [68] [69]

1 to 105 J

List of orders of magnitude for energy
Factor (joules) SI prefix ValueItem
100J1 J≡ 1 N·m (newtonmetre)
1 J≡ 1 W·s (watt-second)
1 JKinetic energy produced as an extra small apple (~100 grams [70] ) falls 1 meter against Earth's gravity [71]
1 JEnergy required to heat 1 gram of dry, cool air by 1 degree Celsius [72]
1.4 J≈ 1 ft·lbf (foot-pound force) [59]
4.184 J≡ 1 thermochemical calorie (small calorie) [59]
4.1868 J≡ 1 International (Steam) Table calorie [73]
8 J Greisen-Zatsepin-Kuzmin theoretical upper limit for the energy of a cosmic ray coming from a distant source [74] [75]
101 deca- (daJ)1×101 JFlash energy of a typical pocket camera electronic flash capacitor (100–400 μF @ 330 V) [76] [77]
5×101 JThe most energetic cosmic ray ever detected. [78] Most likely a single proton traveling only very slightly slower than the speed of light. [79]
102 hecto- (hJ)1.25×102 JKinetic energy of a regulation (standard) baseball (5.1 oz / 145 g) [80] thrown at 93 mph / 150 km/h (MLB average pitch speed). [81]
1.5×102 - 3.6×102 JEnergy delivered by a biphasic external electric shock (defibrillation), usually during adult cardiopulmonary resuscitation for cardiac arrest.
3×102 JEnergy of a lethal dose of X-rays [82]
3×102 JKinetic energy of an average person jumping as high as they can [83] [84] [85]
3.3×102 J Energy to melt 1 g of ice [86]
> 3.6×102 JKinetic energy of 800 gram [87] standard men's javelin thrown at > 30 m/s [88] by elite javelin throwers [89]
5–20×102 JEnergy output of a typical photography studio strobe light in a single flash [90]
6×102 JUse of a 10-watt flashlight for 1 minute
7.5×102 JA power of 1 horsepower applied for 1 second [59]
7.8×102 JKinetic energy of 7.26 kg [91] standard men's shot thrown at 14.7 m/s[ citation needed ] by the world record holder Randy Barnes [92]
8.01×102 JAmount of work needed to lift a man with an average weight (81.7 kg) one meter above Earth (or any planet with Earth gravity)
103 kilo- (kJ)1.1×103 J≈ 1 British thermal unit (BTU), depending on the temperature [59]
1.4×103 JTotal solar radiation received from the Sun by 1 square meter at the altitude of Earth's orbit per second (solar constant) [93]
2.3×103 J Energy to vaporize 1 g of water into steam [94]
3×103 J Lorentz force can crusher pinch [95]
3.4×103 JKinetic energy of world-record men's hammer throw (7.26 kg [96] thrown at 30.7 m/s [97] in 1986) [98]
3.6×103 J≡ 1 W·h (watt-hour) [59]
4.2×103 JEnergy released by explosion of 1 gram of TNT [59] [99]
4.2×103 J≈ 1 food Calorie (large calorie)
~7×103 JMuzzle energy of an elephant gun, e.g. firing a .458 Winchester Magnum [100]
8.5×103 JKinetic energy of a regulation baseball thrown at the speed of sound (343 m/s = 767 mph = 1,235 km/h. Air, 20°C). [101]
9×103 JEnergy in an alkaline AA battery [102]
104 1.7×104 JEnergy released by the metabolism of 1 gram of carbohydrates [103] or protein [104]
3.8×104 JEnergy released by the metabolism of 1 gram of fat [105]
4–5×104 JEnergy released by the combustion of 1 gram of gasoline [106]
5×104 JKinetic energy of 1 gram of matter moving at 10 km/s [107]
105 3×105 – 15×105 J Kinetic energy of an automobile at highway speeds (1 to 5 tons [108] at 89 km/h or 55 mph) [109]
5×105 JKinetic energy of 1 gram of a meteor hitting Earth [110]

106 to 1011 J

List of orders of magnitude for energy
Factor (joules) SI prefix ValueItem
106 mega- (MJ)1×106 J Kinetic energy of a 2 tonne [108] vehicle at 32 metres per second (115 km/h or 72 mph) [111]
1.2×106 JApproximate food energy of a snack such as a Snickers bar (280 food calories) [112]
3.6×106 J= 1 kWh (kilowatt-hour) (used for electricity) [59]
4.2×106 JEnergy released by explosion of 1 kilogram of TNT [59] [99]
6.1×106 JKinetic energy of the 4 kg tungsten APFSDS penetrator after being fired from a 120mm KE-W A1 cartridge with a nominal muzzle velocity of 1740 m/s. [113] [114]
8.4×106 JRecommended food energy intake per day for a moderately active woman (2000 food calories) [115] [116]
9.1×106 JKinetic energy of a regulation baseball thrown at Earth's escape velocity (First cosmic velocity ≈ 11.186 km/s = 25,020 mph = 40,270 km/h). [117]
107 1×107 JKinetic energy of the armor-piercing round fired by the ISU-152 assault gun [118] [ citation needed ]
1.1×107 JRecommended food energy intake per day for a moderately active man (2600 food calories) [115] [119]
3.3×107 JKinetic energy of a 23 lb projectile fired by the Navy's mach 8 railgun. [120]
3.7×107 J$1 of electricity at a cost of $0.10/kWh (the US average retail cost in 2009) [121] [122] [123]
4×107 JEnergy from the combustion of 1 cubic meter of natural gas [124]
4.2×107 JCaloric energy consumed by Olympian Michael Phelps on a daily basis during Olympic training [125]
6.3×107 JTheoretical minimum energy required to accelerate 1 kg of matter to escape velocity from Earth's surface (ignoring atmosphere) [126]
9×107 JTotal mass-energy of 1 microgram of matter (25 kWh)
108 1×108 JKinetic energy of a 55 tonne aircraft at typical landing speed (59 m/s or 115 knots)[ citation needed ]
1.1×108 J≈ 1 therm, depending on the temperature [59]
1.1×108 J≈ 1 Tour de France, or ~90 hours [127] ridden at 5 W/kg [128] by a 65 kg rider [129]
7.3×108 J≈ Energy from burning 16 kilograms of oil (using 135 kg per barrel of light crude)[ citation needed ]
109 giga- (GJ)1×109 JEnergy in an average lightning bolt [130] (thunder)
1.1×109 JMagnetic stored energy in the world's largest toroidal superconducting magnet for the ATLAS experiment at CERN, Geneva [131]
1.2×109 JInflight 100-ton Boeing 757-200 at 300 knots (154 m/s)
1.4×109 JTheoretical minimum amount of energy required to melt a tonne of steel (380 kWh) [132] [133]
2×109 JEnergy of an ordinary 61 liter gasoline tank of a car. [106] [134] [135]
2×109 JUnit of energy in Planck units, [136] roughly the diesel tank energy of a mid-sized truck.
2.49×109 JKinetic energy carried by American Airlines Flight 11 (767-200ER) at the moment of impact [137] [138] with WTC 1, 8:46:30 A.M. [138] [139] [137] (EDT UTC−4:00), September 11, 2001
3×109 JInflight 125-ton Boeing 767-200 flying at 373 knots (192 m/s)
3.3×109 JApproximate average amount of energy expended by a human heart muscle over an 80-year lifetime [140] [141]
3.6×109 J= 1 MW·h (megawatt-hour)
4.2×109 JEnergy released by explosion of 1 ton of TNT.
4.5×109 JAverage annual energy usage of a standard refrigerator [142] [143]
6.1×109 J≈ 1 bboe (barrel of oil equivalent) [144]
1010 1.9×1010 JKinetic energy of an Airbus A380 at cruising speed (560 tonnes at 511 knots or 263 m/s)
4.2×1010 J≈ 1 toe (ton of oil equivalent) [144]
4.6×1010 JYield energy of a Massive Ordnance Air Blast bomb, the second most powerful non-nuclear weapon ever designed [145] [146]
7.3×1010 JEnergy consumed by the average U.S. automobile in the year 2000 [147] [148] [149]
8.6×1010 J≈ 1 MW·d (megawatt-day), used in the context of power plants (24 MW·h) [150]
8.8×1010 JTotal energy released in the nuclear fission of one gram of uranium-235 [36] [37] [151]
9×1010 JTotal mass-energy of 1 milligram of matter (25 MW·h)
1011 1.1×1011 JKinetic energy of a regulation baseball thrown at lightning speed (120 km/s = 270,000 mph = 435,000 km/h). [152]
2.4×1011 JApproximate food energy consumed by an average human in an 80-year lifetime. [153]

1012 to 1017 J

List of orders of magnitude for energy
Factor (joules) SI prefix ValueItem
1012 tera- (TJ)1.85×1012 JGravitational potential energy of the Twin Towers, combined, accumulated throughout their construction and released during the collapse of the complex. [154] [155] [156]
3.4×1012 JMaximum fuel energy of an Airbus A330-300 (97,530 liters [157] of Jet A-1 [158] ) [159]
3.6×1012 J1 GW·h (gigawatt-hour) [160]
4×1012 JElectricity generated by one 20-kg CANDU fuel bundle assuming ~29% [161] thermal efficiency of reactor [162] [163]
4.2×1012 JChemical energy released by the detonation of 1 kiloton of TNT [59] [164]
6.4×1012 JEnergy contained in jet fuel in a Boeing 747-100B aircraft at max fuel capacity (183,380 liters [165] of Jet A-1 [158] ) [166]
1013 1.1×1013 JEnergy of the maximum fuel an Airbus A380 can carry (320,000 liters [167] of Jet A-1 [158] ) [168]
1.2×1013 JOrbital kinetic energy of the International Space Station (417 tonnes [169] at 7.7 km/s [170] ) [171]
1.20×1013 JOrbital kinetic energy of the Parker Solar Probe as it dives deep into the Sun's gravity well in December 2024, reaching a peak velocity of 430,000 mph. [172] [173] [174]
6.3×1013 JYield of the Little Boy atomic bomb dropped on Hiroshima in World War II (15 kilotons) [175] [176]
9×1013 JTheoretical total mass–energy of 1 gram of matter (25 GW·h) [177]
1014 1.8×1014 JEnergy released by annihilation of 1 gram of antimatter and matter (50 GW·h)
3.75×1014 JTotal energy released by the Chelyabinsk meteor. [178]
6×1014 JEnergy released by an average hurricane in 1 second [179]
1015 peta- (PJ) > 1015 JEnergy released by a severe thunderstorm [180]
1×1015 JYearly electricity consumption in Greenland as of 2008 [181] [182]
4.2×1015 JEnergy released by explosion of 1 megaton of TNT [59] [183]
1016 1×1016 JEstimated impact energy released in forming Meteor Crater [ citation needed ]
1.1×1016 JYearly electricity consumption in Mongolia as of 2010 [181] [184]
6.3×1016 JYield of Castle Bravo, the most powerful nuclear weapon tested by the United States [185]
7.9×1016 JKinetic energy of a regulation baseball thrown at 99% the speed of light (KE = mc^2 × [γ-1], where the Lorentz factor γ ≈ 7.09). [186]
9×1016 J Mass–energy of 1 kilogram of antimatter (or matter) [187]
1017 1.4×1017 JSeismic energy released by the 2004 Indian Ocean earthquake [188]
1.7×1017 JTotal energy from the Sun that strikes the face of the Earth each second [189]
2.1×1017 JYield of the Tsar Bomba, the most powerful nuclear weapon ever tested (50 megatons) [190] [191]
2.552×1017 JTotal energy of the 2022 Hunga Tonga–Hunga Haʻapai eruption [192] [193]
4.2×1017 JYearly electricity consumption of Norway as of 2008 [181] [194]
4.516×1017 JEnergy needed to accelerate one ton of mass to 0.1c (~30,000 km/s) [195]
8×1017 JEstimated energy released by the eruption of the Indonesian volcano, Krakatoa, in 1883 [196] [197] [198]

1018 to 1023 J

List of orders of magnitude for energy
Factor (joules) SI prefix ValueItem
1018 exa- (EJ) 9.4×1018 JWorldwide nuclear-powered electricity output in 2023. [199] [200]
1019 1×1019 JThermal energy released by the 1991 Pinatubo eruption [201]
1.1×1019 JSeismic energy released by the 1960 Valdivia Earthquake [201]
1.2×1019 JExplosive yield of global nuclear arsenal [202] (2.86 Gigatons)
1.4×1019 JYearly electricity consumption in the U.S. as of 2009 [181] [203]
1.4×1019JYearly electricity production in the U.S. as of 2009 [204] [205]
5×1019 JEnergy released in 1 day by an average hurricane in producing rain (400 times greater than the wind energy) [179]
6.4×1019 JYearly electricity consumption of the world as of 2008 [206] [207]
6.8×1019 JYearly electricity generation of the world as of 2008 [206] [208]
1020 1.4×1020 JTotal energy released in the 1815 Mount Tambora eruption [209]
2.33×1020 JKinetic energy of a carbonaceous chondrite meteor 1 km in diameter striking Earth's surface at 20 km/s. [210] Such an impact occurs every ~500,000 years. [211]
2.4×1020 JTotal latent heat energy released by Hurricane Katrina [212]
5×1020 J Total world annual energy consumption in 2010 [213] [214]
6.2×1020 JWorld primary energy generation in 2023 (620 EJ). [215] [216]
8×1020 JEstimated global uranium resources for generating electricity 2005 [217] [218] [219] [220]
1021 zetta- (ZJ) 6.9×1021 JEstimated energy contained in the world's natural gas reserves as of 2010 [213] [221]
7.0×1021 JThermal energy released by the Toba eruption [201]
7.9×1021 JEstimated energy contained in the world's petroleum reserves as of 2010 [213] [222]
9.3×1021 JAnnual net uptake of thermal energy by the global ocean during 2003-2018 [223]
1022 1.2×1022JSeismic energy of a magnitude 11 earthquake on Earth (M 11) [224]
1.5×1022JTotal energy from the Sun that strikes the face of the Earth each day [189] [225]
1.94×1022JImpact event that formed the Siljan Ring, the largest impact structure in Europe [226]
2.4×1022 JEstimated energy contained in the world's coal reserves as of 2010 [213] [227]
2.9×1022 JIdentified global uranium-238 resources using fast reactor technology [217]
3.9×1022 JEstimated energy contained in the world's fossil fuel reserves as of 2010 [213] [228]
8.03×1022 JTotal energy of the 2004 Indian Ocean earthquake [229]
1023 1.5×1023 JTotal energy of the 1960 Valdivia earthquake [230]
2.2×1023 JTotal global uranium-238 resources using fast reactor technology [217]
3×1023 JThe energy released in the formation of the Chicxulub Crater in the Yucatán Peninsula [231]

Over 1024 J

List of orders of magnitude for energy
Factor (joules) SI prefix ValueItem
1024 yotta- (YJ)2.31×1024 JTotal energy of the Sudbury impact event [232]
2.69×1024 JRotational energy of Venus, which has a sidereal period of (-)243 Earth days. [233] [234] [235]
3.8×1024 JRadiative heat energy released from the Earth’s surface each year [201]
5.5×1024 JTotal energy from the Sun that strikes the face of the Earth each year [189] [236]
1025 4×1025 JTotal energy of the Carrington Event in 1859 [237]
1026 >1026JEstimated energy of early Archean asteroid impacts [238]
3.2×1026 JBolometric energy of Proxima Centauri's superflare in March 2016 (10^33.5 erg). In one year, potentially five similar superflares erupts from the surface of the red dwarf. [239]
3.828×1026 JTotal radiative energy output of the Sun each second [240]
1027 ronna- (RJ)1×1027 JEstimated energy released by the impact that created the Caloris basin on Mercury [241]
1×1027 JUpper limit of the most energetic solar flares possible (X1000) [242]
5.19×1027 JThermal input necessary to evaporate all surface water on Earth. [243] [244] [245] Note that the evaporated water still remains on Earth, merely in vapor form.
4.2×1027 JKinetic energy of a regulation baseball thrown at the speed of the Oh-My-God particle, itself a cosmic ray proton with the kinetic energy of a baseball thrown at 60 mph (~50 J). [246]
10283.8×1028 JKinetic energy of the Moon in its orbit around the Earth (counting only its velocity relative to the Earth) [247] [248]
7×1028 JTotal energy of the stellar superflare from V1355 Orionis [249] [250]
1029 2.1×1029 J Rotational energy of the Earth [251] [252] [253]
1030 quetta- (QJ)1.79×1030 JRough estimate of the gravitational binding energy of Mercury. [254]
1031 2×1031 JThe Theia Impact, the most energetic event ever in Earth's history [255] [256]
 3.3×1031JTotal energy output of the Sun each day [240] [257]
1032 1.71×1032 J Gravitational binding energy of the Earth [258]
3.10×1032 JYearly energy output of Sirius B, the ultra-dense and Earth-sized white dwarf companion of Sirius, the Dog Star. It has a surface temperature of about 25,200 K. [259]
1033 2.7×1033 J Earth's kinetic energy at perihelion in its orbit around the Sun [260] [261]
1034 1.2×1034 JTotal energy output of the Sun each year [240] [262]
10353.5×1035 JThe most energetic stellar superflare to date (V2487 Ophiuchi) [263]
10387.53×1038 JBaryonic (ordinary) mass-energy contained in a volume of one cubic light-year, on average. [264] [265]
1039  2–5×1039 JEnergy of the giant flare (starquake) released by SGR 1806-20 [266] [267] [268]
6.602×1039 J Theoretical total mass–energy of the Moon [269] [270]
1040  1.61×1040 JBaryonic mass-energy contained in a volume of one cubic parsec, on average. [265] [271]
1041 2.276×1041 JGravitational binding energy of the Sun [272]
5.3675×1041 JTheoretical total mass–energy of the Earth [273] [274]
1043 5×1043 JTotal energy of all gamma rays in a typical gamma-ray burst if collimated [275] [276]
>1043 JTotal energy in a typical fast blue optical transient (FBOT) [277]
1044 ~1044 JAverage value of a Tidal Disruption Event (TDE) in optical/UV bands [278]
~1044 JEstimated kinetic energy released by FBOT CSS161010 [279]
~1044 JTotal energy released in a typical supernova, [280] [281] sometimes referred to as a foe.
1.233×1044 JApproximate lifetime energy output of the Sun. [282] [283]
3×1044 JTotal energy of a typical gamma-ray burst if collimated [280]
1045 ~1045 JEstimated energy released in a hypernova and pair instability supernova [284]
1045 JEnergy released by the energetic supernova, SN 2016aps [285] [286]
1.7–1.9×1045 JEnergy released by hypernova ASASSN-15lh [287]
2.3×1045 JEnergy released by the energetic supernova PS1-10adi [288] [289]
>1045 JEstimated energy of a magnetorotational hypernova [290]
>1045 JTotal energy (energy in gamma rays+relativistic kinetic energy) of hyper-energetic gamma-ray burst if collimated [291] [292] [293] [294] [295]
1046>1046 JEstimated energy in theoretical quark-novae [296]
~1046 JUpper limit of the total energy of a supernova [297] [298]
1.5×1046 JTotal energy of the most energetic optical non-quasar transient, AT2021lwx [299]
1047 1045-47 JEstimated energy of stellar mass rotational black holes by vacuum polarization in an electromagnetic field [300] [301]
1047 JTotal energy of a very energetic and relativistic jetted Tidal Disruption Event (TDE) [302]
~1047 JUpper limit of collimated- corrected total energy of a gamma-ray burst [303] [304] [305]
1.8×1047 JTheoretical total mass–energy of the Sun [306] [307]
5.4×1047 J Mass–energy emitted as gravitational waves during the merger of two black holes, originally about 30 Solar masses each, as observed by LIGO (GW150914) [308]
8.6×1047 JMass–energy emitted as gravitational waves during the most energetic black hole merger observed until 2020 (GW170729) [309]
8.8×1047 J GRB 080916C – formerly the most powerful gamma-ray burst (GRB) ever recorded – total/true [310] isotropic energy output estimated at 8.8 × 1047 joules (8.8 × 1054 erg), or 4.9 times the Sun's mass turned to energy [311]
10481048 JEstimated energy of a supermassive Population III star supernova, denominated "General Relativistic Instability Supernova." [312] [313]
~1.2×1048 JApproximate energy released in the most energetic black hole merging to date (GW190521), which originated the first intermediate-mass black hole ever detected [314] [315] [316] [317] [318]
1.2–3×1048 J GRB 221009A – the most powerful gamma-ray burst (GRB) ever recorded – total/true [310] [319] isotropic energy output estimated at 1.2–3 × 1048 joules (1.2–3 × 1055 erg) [320] [321] [322]
1050≳1050 JUpper limit of isotropic energy (Eiso) of Population III stars Gamma-Ray Bursts (GRBs). [323]
1053 >1053 J Mechanical energy of very energetic so-called "quasar tsunamis" [324] [325]
6×1053 JTotal mechanical energy or enthalpy in the powerful AGN outburst in the RBS 797 [326]
7.65×1053 JMass-energy of Sagittarius A*, Milky Way's central supermassive black hole [327] [328]
1054 3×1054 JTotal mechanical energy or enthalpy in the powerful AGN outburst in the Hercules A (3C 348) [329]
1055 >1055 JTotal mechanical energy or enthalpy in the powerful AGN outburst in the MS 0735.6+7421, [330] Ophiucus Supercluster Explosion [331] and supermassive black holes mergings [332] [333]
1057~1057 JEstimated rotational energy of M87 SMBH and total energy of the most luminous quasars over Gyr time-scales [334] [335]
~2×1057 JEstimated thermal energy of the Bullet Cluster of galaxies [336]
7.3×1057 JMass-energy equivalent of the ultramassive black hole TON 618, an extremely luminous quasar / active galactic nucleus (AGN). [337] [338]
1058 ~1058 JEstimated total energy (in shockwaves, turbulence, gases heating up, gravitational force) of galaxy clusters mergings [339]
4×1058 JVisible mass–energy in our galaxy, the Milky Way [340] [341]
1059 1×1059 JTotal mass–energy of our galaxy, the Milky Way, including dark matter and dark energy [342] [343]
1.4×1059 JMass-energy of the Andromeda galaxy (M31), ~0.8 trillion solar masses. [344] [345]
1062 1–2×1062 JTotal mass–energy of the Virgo Supercluster including dark matter, the Supercluster which contains the Milky Way [346]
10701.462×1070 JRough estimate of total mass–energy of ordinary matter (atoms; baryons) present in the observable universe. [347] [348] [265]
10713.177×1071 JRough estimate of total mass-energy within our observable universe, accounting for all forms of matter and energy. [349] [265]

SI multiples

SI multiples of joule (J)
SubmultiplesMultiples
ValueSI symbolNameValueSI symbolName
10−1 JdJdecijoule101 JdaJdecajoule
10−2 JcJcentijoule102 JhJhectojoule
10−3 JmJmillijoule103 JkJkilojoule
10−6 JμJmicrojoule106 JMJmegajoule
10−9 JnJnanojoule109 JGJgigajoule
10−12 JpJpicojoule1012 JTJterajoule
10−15 JfJfemtojoule1015 JPJpetajoule
10−18 JaJattojoule1018 JEJexajoule
10−21 JzJzeptojoule1021 JZJzettajoule
10−24 JyJyoctojoule1024 JYJyottajoule
10−27 JrJrontojoule1027 JRJronnajoule
10−30 JqJquectojoule1030 JQJquettajoule

The joule is named after James Prescott Joule . As with every SI unit named for a person, its symbol starts with an upper case letter (J), but when written in full, it follows the rules for capitalisation of a common noun ; i.e., joule becomes capitalised at the beginning of a sentence and in titles but is otherwise in lower case.

See also

Notes

  1. "Planck's constant | physics | Britannica.com". britannica.com. Retrieved 26 December 2016.
  2. Calculated: KEavg = (3/2) × Boltzmann constant × Temperature
  3. Calculated: Ephoton = hν = 6.626×10−34 J-s × 1×106 Hz = 6.6×10−28 J. In eV: 6.6×10−28 J / 1.6×10−19 J/eV = 4.1×10−9 eV.
  4. Cheung, Howard (1998). Elert, Glenn (ed.). "Frequency of a microwave oven". The Physics Factbook. Retrieved 25 January 2022.
  5. Calculated: Ephoton = hν = 6.626×10−34 J-s × 2.45×108 Hz = 1.62×10−24 J. In eV: 1.62×10−24 J / 1.6×10−19 J/eV = 1.0×10−5 eV.
  6. "Boomerang Nebula boasts the coolest spot in the Universe". JPL. Archived from the original on 27 August 2009. Retrieved 13 November 2011.
  7. Calculated: KEavg ≈ (3/2) × T × 1.38×10−23 = (3/2) × 1 × 1.38×10−23 ≈ 2.07×10−23 J
  8. 1 2 3 4 "Wavelength, Frequency, and Energy". Imagine the Universe. NASA. Archived from the original on 18 November 2001. Retrieved 15 November 2011.
  9. Calculated: 1×103 J / 6.022×1023 entities per mole = 1.7×10−21 J per entity
  10. Calculated: 1.381×10−23 J/K × 298.15 K / 2 = 2.1×10−21 J
  11. 1 2 3 "Bond Lengths and Energies". Chem 125 notes. UCLA. Archived from the original on 23 August 2011. Retrieved 13 November 2011.
  12. Calculated: 2 to 4 kJ/mol = 2×103 J / 6.022×1023 molecules/mol = 3.3×10−21 J. In eV: 3.3×10−21 J / 1.6×10−19 J/eV = 0.02 eV. 4×103 J / 6.022×1023 molecules/mol = 6.7×10−21 J. In eV: 6.7×10−21 J / 1.6×10−19 J/eV = 0.04 eV.
  13. Ansari, Anjum. "Basic Physical Scales Relevant to Cells and Molecules". Physics 450. Retrieved 13 November 2011.
  14. Calculated: 4 to 13 kJ/mol. 4 kJ/mol = 4×103 J / 6.022×1023 molecules/mol = 6.7×10−21 J. In eV: 6.7×10−21 J / 1.6×10−19 eV/J = 0.042 eV. 13 kJ/mol = 13×103 J / 6.022×1023 molecules/mol = 2.2×10−20 J. In eV: 13×103 J / 6.022×1023 molecules/mol / 1.6×10−19 eV/J = 0.13 eV.
  15. Thomas, S.; Abdalla, F.; Lahav, O. (2010). "Upper Bound of 0.28 eV on Neutrino Masses from the Largest Photometric Redshift Survey". Physical Review Letters. 105 (3): 031301. arXiv: 0911.5291 . Bibcode:2010PhRvL.105c1301T. doi:10.1103/PhysRevLett.105.031301. PMID   20867754. S2CID   23349570.
  16. Calculated: 0.28 eV × 1.6×10−19 J/eV = 4.5×10−20 J
  17. "physics.nist.gov/cuu/Constants/Table/allascii.txt". 2022. Archived from the original on 10 September 2024.
  18. "BASIC LAB KNOWLEDGE AND SKILLS". Archived from the original on 15 May 2013. Retrieved 5 November 2011. Visible wavelengths are roughly from 390 nm to 780 nm
  19. Calculated: E = hc/λ. E780 nm = 6.6×10−34 kg-m2/s × 3×108 m/s / (780×10−9 m) = 2.5×10−19 J. E_390 _nm = 6.6×10−34 kg-m2/s × 3×108 m/s / (390×10−9 m) = 5.1×10−19 J
  20. Calculated: 50 kcal/mol × 4.184 J/calorie / 6.0×1022e23 molecules/mol = 3.47×10−19 J. (3.47×10−19 J / 1.60×10−19 eV/J = 2.2 eV.) and 200 kcal/mol × 4.184 J/calorie / 6.0×1022e23 molecules/mol = 1.389×10−18 J. (7.64×10−19 J / 1.60×10−19 eV/J = 8.68 eV.)
  21. Kim, Hahn; Doan, Van Dung; Cho, Woo Jong; Valero, Rosendo; Aliakbar Tehrani, Zahra; Madridejos, Jenica Marie L.; Kim, Kwang S. (6 November 2015). "Intriguing Electrostatic Potential of CO: Negative Bond-ends and Positive Bond-cylindrical-surface". Scientific Reports. 5: 16307. Bibcode:2015NatSR...516307K. doi:10.1038/srep16307. ISSN   2045-2322. PMC   4635358 . PMID   26542890.
  22. Phillips, Kevin; Jacques, Steven; McCarty, Owen (2012). "How much does a cell weigh?". Physical Review Letters. 109 (11): 118105. Bibcode:2012PhRvL.109k8105P. doi:10.1103/PhysRevLett.109.118105. PMC   3621783 . PMID   23005682. Roughly 27 picograms
  23. Bob Berman. "Our Bodies' Velocities, By the Numbers" . Retrieved 19 August 2016. The [...] blood [...] flow[s] at an average speed of 3 to 4 mph
  24. Calculated: 1/2 × 27×10−12 g × (3.5 miles per hour)2 = 3×10−15 J
  25. "Physics of the Body" (PDF). Notre Dame. Archived from the original (PDF) on 6 November 2016. Retrieved 19 August 2016.. "The eardrum is a [...] membran[e] with an area of 65 mm2."
  26. "Intensity and the Decibel Scale". Physics Classroom. Retrieved 19 August 2016.
  27. Calculated: two eardrums ≈ 1 cm2. 1×10−6 W/m2 × 1×10−4 m2 × 1 s = 1×10−14 J
  28. Thomas J Bowles (2000). P. Langacker (ed.). Neutrinos in physics and astrophysics: from 10–33 to 1028 cm: TASI 98 : Boulder, Colorado, USA, 1–26 June 1998. World Scientific. p. 354. ISBN   978-981-02-3887-2 . Retrieved 11 November 2011. an upper limit ov m_v_u < 170 keV
  29. Calculated: 170×103 eV × 1.6×10−19 J/eV = 2.7×10−14 J
  30. "electron mass energy equivalent". NIST. Retrieved 4 November 2011.
  31. "CODATA Value: electron mass energy equivalent in MeV". physics.nist.gov. Retrieved 13 August 2023.
  32. "Conversion from eV to J". NIST. Retrieved 4 November 2011.
  33. "How much energy is released when hydrogen is fused to produce one kilo of helium?". 11 November 2017. Retrieved 21 July 2021.
  34. Muller, Richard A. (2002). "The Sun, Hydrogen Bombs, and the physics of fusion". Archived from the original on 2 April 2012. Retrieved 5 November 2011. The neutron comes out with high energy of 14.1 MeV
  35. "Conversion from eV to J". NIST. Retrieved 4 November 2011.
  36. 1 2 "Energy From Uranium Fission". HyperPhysics. Retrieved 8 November 2011.
  37. 1 2 "Conversion from eV to J". NIST. Retrieved 4 November 2011.
  38. "CODATA Value: atomic mass constant energy equivalent". physics.nist.gov. Retrieved 13 August 2023.
  39. "CODATA Value: atomic mass constant energy equivalent in MeV". physics.nist.gov. Retrieved 13 August 2023.
  40. "proton mass energy equivalent". NIST. Retrieved 4 November 2011.
  41. "CODATA Value: proton mass energy equivalent in MeV". physics.nist.gov. Retrieved 13 August 2023.
  42. "neutron mass energy equivalent". NIST. Retrieved 4 November 2011.
  43. "CODATA Value: neutron mass energy equivalent in MeV". physics.nist.gov. Retrieved 13 August 2023.
  44. "Conversion from eV to J". NIST. Retrieved 4 November 2011.
  45. "deuteron mass energy equivalent". NIST. Retrieved 4 November 2011.
  46. "alpha particle mass energy equivalent". NIST. Retrieved 4 November 2011.
  47. Calculated: 7×10−4 g × 9.8 m/s2 × 1×10−4 m
  48. "Conversion from eV to J". NIST. Retrieved 4 November 2011.
  49. Myers, Stephen. "The LEP Collider". CERN. Archived from the original on 25 August 2010. Retrieved 14 November 2011. the LEP machine energy is about 50 GeV per beam
  50. Calculated: 50×109 eV × 1.6×10−19 J/eV = 8×10−9 J
  51. "W". PDG Live. Particle Data Group. Archived from the original on 17 July 2012. Retrieved 4 November 2011.
  52. "Conversion from eV to J". NIST. Retrieved 4 November 2011.
  53. Amsler, C.; Doser, M.; Antonelli, M.; Asner, D.; Babu, K.; Baer, H.; Band, H.; Barnett, R.; Bergren, E.; Beringer, J.; Bernardi, G.; Bertl, W.; Bichsel, H.; Biebel, O.; Bloch, P.; Blucher, E.; Blusk, S.; Cahn, R. N.; Carena, M.; Caso, C.; Ceccucci, A.; Chakraborty, D.; Chen, M. -C.; Chivukula, R. S.; Cowan, G.; Dahl, O.; d'Ambrosio, G.; Damour, T.; De Gouvêa, A.; et al. (2008). "Review of Particle Physics⁎". Physics Letters B. 667 (1): 1–6. Bibcode:2008PhLB..667....1A. doi:10.1016/j.physletb.2008.07.018. hdl: 1854/LU-685594 . S2CID   227119789. Archived from the original on 12 July 2012.
  54. "Conversion from eV to J". NIST. Retrieved 4 November 2011.
  55. "Conversion from eV to J". NIST. Retrieved 4 November 2011.
  56. ATLAS; CMS (26 March 2015). "Combined Measurement of the Higgs Boson Mass in pp Collisions at √s=7 and 8 TeV with the ATLAS and CMS Experiments". Physical Review Letters. 114 (19): 191803. arXiv: 1503.07589 . Bibcode:2015PhRvL.114s1803A. doi:10.1103/PhysRevLett.114.191803. PMID   26024162. S2CID   1353272.
  57. Adams, John. "400 GeV Proton Synchrotron". Excertp from the CERN Annual Report 1976. CERN. Archived from the original on 26 October 2011. Retrieved 14 November 2011. A circulating proton beam of 400 GeV energy was first achieved in the SPS on 17 June 1976
  58. Calculated: 400×109 eV × 1.6×10−19 J/eV = 6.4×10−8 J
  59. 1 2 3 4 5 6 7 8 9 10 11 12 "Appendix B8—Factors for Units Listed Alphabetically". NIST Guide for the Use of the International System of Units (SI). NIST. 2 July 2009. 1.355818
  60. "Conversion from eV to J". NIST. Retrieved 4 November 2011.
  61. "Chocolate bar yardstick". Archived from the original on 26 February 2014. Retrieved 24 January 2014. A TeV is actually a very tiny amount of energy. A popular analogy is to a flying mosquito.
  62. "First successful beam at record energy of 6.5 TeV" . Retrieved 28 April 2015.
  63. Calculated: 6.5×1012 eV per beam × 1.6×10−19 J/eV = 1.04×10−6 J
  64. "The radioactive series of radium-226" (PDF). CERN.
  65. Terrill, James G. Jr.; Ingraham, Samuel C. II; Moeller, Dade W. (1954). "Radium in the Healing Arts and in Industry: Radiation Exposure in the United States". Public Health Reports. 69 (3): 255–262. doi:10.2307/4588736. JSTOR   4588736. PMC   2024184 . PMID   13134440.
  66. "NanoTritium™: Next-gen Tritium Battery with Decade-Long Betavoltaic Battery Power | CityLabs" . Retrieved 4 April 2022.
  67. "LED - Basic Red 5mm - COM-09590 - SparkFun Electronics". www.sparkfun.com. Retrieved 4 April 2022.
  68. "Coin specifications". United States Mint. Archived from the original on 18 February 2015. Retrieved 2 November 2011. 11.340 g
  69. Calculated: m×g×h = 11.34×10−3 kg × 9.8 m/s2 × 1 m = 1.1×10−1 J
  70. "Apples, raw, with skin (NDB No. 09003)". USDA Nutrient Database. USDA. Archived from the original on 3 March 2015. Retrieved 8 December 2011.
  71. Calculated: m×g×h = 1×10−1 kg × 9.8 m/s2 × 1 m = 1 J
  72. "Specific Heat of Dry Air". Engineering Toolbox. Retrieved 2 November 2011.
  73. "Footnotes". NIST Guide to the SI. NIST. 2 July 2009.
  74. "Physical Motivations". ULTRA Home Page (EUSO project). Dipartimento di Fisica di Torino. Retrieved 12 November 2011.
  75. Calculated: 5×1019 eV × 1.6×10−19 J/ev = 8 J
  76. "Notes on the Troubleshooting and Repair of Electronic Flash Units and Strobe Lights and Design Guidelines, Useful Circuits, and Schematics" . Retrieved 8 December 2011. The energy storage capacitor for pocket cameras is typically 100 to 400 uF at 330 V (charged to 300 V) with a typical flash energy of 10 W-s.
  77. "Teardown: Digital Camera Canon PowerShot |". electroelvis.com. 2 September 2012. Archived from the original on 1 August 2013. Retrieved 6 June 2013.
  78. "The Fly's Eye (1981–1993)". HiRes. Archived from the original on 15 August 2009. Retrieved 14 November 2011.
  79. Bird, D. J. (March 1995). "Detection of a cosmic ray with measured energy well beyond the expected spectral cutoff due to cosmic microwave radiation". Astrophysical Journal, Part 1. 441 (1): 144–150. arXiv: astro-ph/9410067 . Bibcode:1995ApJ...441..144B. doi:10.1086/175344. S2CID   119092012.
  80. "How Much Does a Baseball Weigh? - Baseball Weight Facts". 4 January 2024. Archived from the original on 4 January 2024. Retrieved 4 January 2024.
  81. "How fast does an average MLB pitcher throw? - TopVelocity". 4 January 2024. Archived from the original on 4 January 2024. Retrieved 4 January 2024.
  82. "Ionizing Radiation". General Chemistry Topic Review: Nuclear Chemistry. Bodner Research Web. Retrieved 5 November 2011.
  83. "Vertical Jump Test". Topend Sports. Retrieved 12 December 2011. 41–50 cm (males) 31–40 cm (females)
  84. "Mass of an Adult". The Physics Factbook. Retrieved 13 December 2011. 70 kg
  85. Kinetic energy at start of jump = potential energy at high point of jump. Using a mass of 70 kg and a high point of 40 cm => energy = m×g×h = 70 kg × 9.8 m/s2 × 40×10−2 m = 274 J
  86. "Latent Heat of Melting of some common Materials". Engineering Toolbox. Retrieved 10 June 2013. 334 kJ/kg
  87. "Javelin Throw – Introduction". IAAF. Retrieved 12 December 2011.
  88. Young, Michael. "Developing Event Specific Strength for the Javelin Throw" (PDF). Archived from the original (PDF) on 13 August 2011. Retrieved 13 December 2011. For elite athletes, the velocity of a javelin release has been measured in excess of 30m/s
  89. Calculated: 1/2 × 0.8 kg × (30 m/s)2 = 360 J
  90. Greenspun, Philip. "Studio Photography". Archived from the original on 29 September 2007. Retrieved 13 December 2011. Most serious studio photographers start with about 2000 watts-seconds
  91. "Shot Put – Introduction". IAAF. Retrieved 12 December 2011.
  92. Calculated: 1/2 × 7.26 kg × (14.7 m/s)2 = 784 J
  93. Kopp, G.; Lean, J. L. (2011). "A new, lower value of total solar irradiance: Evidence and climate significance". Geophysical Research Letters. 38 (1): n/a. Bibcode:2011GeoRL..38.1706K. doi: 10.1029/2010GL045777 .
  94. "Fluids – Latent Heat of Evaporation". Engineering Toolbox. Retrieved 10 June 2013. 2257 kJ/kg
  95. powerlabs.org – The PowerLabs Solid State Can Crusher!, 2002
  96. "Hammer Throw – Introduction". IAAF. Retrieved 12 December 2011.
  97. Otto, Ralf M. "HAMMER THROW WR PHOTOSEQUENCE – YURIY SEDYKH" (PDF). Retrieved 4 November 2011. The total release velocity is 30.7 m/sec
  98. Calculated: 1/2 × 7.26 kg × (30.7 m/s)2 = 3420 J
  99. 1 2 4.2×109 J/ton of TNT-equivalent × (1 ton/1×106 grams) = 4.2×103 J/gram of TNT-equivalent
  100. ".458 Winchester Magnum" (PDF). Accurate Powder. Western Powders Inc. Archived from the original (PDF) on 28 September 2007. Retrieved 7 September 2010.
  101. "speed of sound - Google Search". 4 January 2024. Archived from the original on 4 January 2024. Retrieved 4 January 2024.
  102. "Battery energy storage in various battery sizes". AllAboutBatteries.com. Archived from the original on 4 December 2011. Retrieved 15 December 2011.
  103. "Energy Density of Carbohydrates". The Physics Factbook. Retrieved 5 November 2011.
  104. "Energy Density of Protein". The Physics Factbook. Retrieved 5 November 2011.
  105. "Energy Density of Fats". The Physics Factbook. Retrieved 5 November 2011.
  106. 1 2 "Energy Density of Gasoline". The Physics Factbook. Retrieved 5 November 2011.
  107. Calculated: E = 1/2 m×v2 = 1/2 × (1×10−3 kg) × (1×104 m/s)2 = 5×104 J.
  108. 1 2 "List of Car Weights". LoveToKnow. Retrieved 13 December 2011. 3000 to 12000 pounds
  109. Calculated: Using car weights of 1 ton to 5 tons. E = 1/2 m×v2 = 1/2 × (1×103 kg) × (55 mph × 1600 m/mi / 3600 s/hr) = 3.0×105 J. E = 1/2 × (5×103 kg) × (55 mph × 1600 m/mi / 3600 s/hr) = 15×105 J.
  110. Muller, Richard A. "Kinetic Energy in a meteor". Old Physics 10 notes. Archived from the original on 2 April 2012. Retrieved 13 November 2011.
  111. Calculated: KE = 1/2 × 2×103 kg × (32 m/s)2 = 1.0×106 J
  112. "Candies, MARS SNACKFOOD US, SNICKERS Bar (NDB No. 19155)". USDA Nutrient Database. USDA. Archived from the original on 3 March 2015. Retrieved 14 November 2011.
  113. "1/2*4kg*(1740m/s)^2 - Wolfram|Alpha". www.wolframalpha.com. Retrieved 23 September 2024.
  114. "120mm KE-W A1 Armor-Piercing, Fin-Stabilizing, Discarding Sabot-Tracer". General Dynamics Ordnance and Tactical Systems. Retrieved 23 September 2024.
  115. 1 2 "How to Balance the Food You Eat and Your Physical Activity and Prevent Obesity". Healthy Weight Basics. National Heart Lung and Blood Institutde. Retrieved 14 November 2011.
  116. Calculated: 2000 food calories = 2.0×106 cal × 4.184 J/cal = 8.4×106 J
  117. "What is Earth's Escape Velocity? - Earth How". 4 January 2024. Archived from the original on 4 January 2024. Retrieved 4 January 2024.
  118. Calculated: 1/2 × m × v2 = 1/2 × 48.78 kg × (655 m/s)2 = 1.0×107 J.
  119. Calculated: 2600 food calories = 2.6×106 cal × 4.184 J/cal = 1.1×107 J
  120. Ackerman, Spencer. "Video: Navy's Mach 8 Railgun Obliterates Record". Wired. ISSN   1059-1028 . Retrieved 28 July 2024.
  121. "Table 3.3 Consumer Price Estimates for Energy by Source, 1970–2009". Annual Energy Review. US Energy Information Administration. 19 October 2011. Retrieved 17 December 2011. $28.90 per million BTU
  122. Calculated J per dollar: 1 million BTU/$28.90 = 1×106 BTU / 28.90 dollars × 1.055×103 J/BTU = 3.65×107 J/dollar
  123. Calculated cost per kWh: 1 kWh × 3.60×106 J/kWh / 3.65×107 J/dollar = 0.0986 dollar/kWh
  124. "Energy in a Cubic Meter of Natural Gas". The Physics Factbook. Retrieved 15 December 2011.
  125. "The Olympic Diet of Michael Phelps". WebMD. Retrieved 28 December 2011.
  126. Cline, James E. D. "Energy to Space" . Retrieved 13 November 2011. 6.27×107 Joules / Kg
  127. "Tour de France Winners, Podium, Times". Bike Race Info. Retrieved 10 December 2011.
  128. "Watts/kg". Flamme Rouge. Archived from the original on 2 January 2012. Retrieved 4 November 2011.
  129. Calculated: 90 hr × 3600 seconds/hr × 5 W/kg × 65 kg = 1.1×108 J
  130. Smith, Chris (6 March 2007). "How do Thunderstorms Work?". The Naked Scientists. Retrieved 15 November 2011. It discharges about 1–10 billion joules of energy
  131. "Powering up ATLAS's mega magnet". Spotlight on... CERN. Archived from the original on 30 November 2011. Retrieved 10 December 2011. magnetic energy of 1.1 Gigajoules
  132. "ITP Metal Casting: Melting Efficiency Improvement" (PDF). ITP Metal Casting. U.S. Department of Energy. Retrieved 14 November 2011. 377 kWh/mt
  133. Calculated: 380 kW-h × 3.6×106 J/kW-h = 1.37×109 J
  134. Bell Fuels. "Lead-Free Gasoline Material Safety Data Sheet". NOAA. Archived from the original on 20 August 2002. Retrieved 6 July 2008.
  135. thepartsbin.com – Volvo Fuel Tank: Compare at The Parts Bin [ permanent dead link ], 6 May 2012
  136. 1 2 "1/2*(440mph)^2*283,600lb - Wolfram|Alpha". www.wolframalpha.com. Retrieved 11 September 2024.
  137. 1 2 "Final Report on the Collapse of the World Trade Center Towers". Final Report on the Collapse of the World Trade Center Towers: Federal Building and Fire Safety Investigation of the World Trade Center Disaster [NIST NCSTAR 1]. September 2005. Archived (PDF) from the original on 11 September 2024. Retrieved 11 September 2024.
  138. p. 20 (70 of 302) Section: 2.2 THE AIRCRAFT
  139. "Power of a Human Heart". The Physics Factbook. Retrieved 10 December 2011. The mechanical power of the human heart is ~1.3 watts
  140. Calculated: 1.3 J/s × 80 years × 3.16×107 s/year = 3.3×109 J
  141. "U.S. Household Electricity Uses: A/C, Heating, Appliances". U.S. HOUSEHOLD ELECTRICITY REPORT. EIA. Retrieved 13 December 2011. For refrigerators in 2001, the average UEC was 1,239 kWh
  142. Calculated: 1239 kWh × 3.6×106 J/kWh = 4.5×109 J
  143. 1 2 Energy Units Archived 10 October 2016 at the Wayback Machine , by Arthur Smith, 21 January 2005
  144. "Top 10 Biggest Explosions". Listverse. 28 November 2011. Retrieved 10 December 2011. a yield of 11 tons of TNT
  145. Calculated: 11 tons of TNT-equivalent × 4.184×109 J/ton of TNT-equivalent = 4.6×1010 J
  146. "Emission Facts: Average Annual Emissions and Fuel Consumption for Passenger Cars and Light Trucks". EPA. Retrieved 12 December 2011. 581 gallons of gasoline
  147. "200 Mile-Per-Gallon Cars?". Archived from the original on 19 December 2011. Retrieved 12 December 2011. a gallon of gas ... 125 million joules of energy
  148. Calculated: 581 gallons × 125×106 J/gal = 7.26×1010 J
  149. Calculated: 1×106 watts × 86400 seconds/day = 8.6×1010 J
  150. Calculated: 3.44×10−10 J/U-235-fission × 1×10−3 kg / (235 amu per U-235-fission × 1.66×10−27 amu/kg) = 8.82×10−10 J
  151. "10 striking facts about lightning - Met Office". 4 January 2024. Archived from the original on 4 January 2024. Retrieved 4 January 2024.
  152. Calculated: 2000 kcal/day × 365 days/year × 80 years = 2.4×1011 J
  153. "1/2*416m*1 million ton*9.81m/s^2 - Wolfram|Alpha". www.wolframalpha.com. Retrieved 23 September 2024.
  154. Equation for calculating potential assumes that the towers' center of mass is located halfway along the building's height of ~416 meters.
  155. "Why Did the World Trade Center Collapse? Science, Engineering, and Speculation". www.tms.org. Retrieved 23 September 2024".... The total weight of each tower was about 500,000 t."{{cite web}}: CS1 maint: postscript (link)
  156. "A330-300 Dimensions & key data". Airbus. Archived from the original on 16 January 2013. Retrieved 12 December 2011. 97530 litres
  157. 1 2 3 "Air BP Handbook of Products" (PDF). BP . Archived from the original (PDF) on 8 June 2011. Retrieved 19 August 2011.
  158. Calculated: 97530 liters × 0.804 kg/L × 43.15 MJ/kg = 3.38×1012 J
  159. Calculated: 1×109 watts × 3600 seconds/hour
  160. Weston, Kenneth. "Chapter 10. Nuclear Power Plants" (PDF). Energy Conversion. Archived from the original (PDF) on 5 October 2011. Retrieved 13 December 2011. The thermal efficiency of a CANDU plant is only about 29%
  161. "CANDU and Heavy Water Moderated Reactors" . Retrieved 12 December 2011. fuel burnup in a CANDU is only 6500 to 7500 MWd per metric ton uranium
  162. Calculated: 7500×106 watt-days/tonne × (0.020 tonnes per bundle) × 86400 seconds/day = 1.3×1013 J of burnup energy. Electricity = burnup × ~29% efficiency = 3.8×1012 J
  163. Calculated: 4.2×109 J/ton of TNT-equivalent × 1×103 tons/megaton = 4.2×1012 J/megaton of TNT-equivalent
  164. "747 Classics Technical Specs". Boeing. Archived from the original on 10 December 2007. Retrieved 12 December 2011. 183,380 L
  165. Calculated: 183380 liters × 0.804 kg/L × 43.15 MJ/kg = 6.36×1012 J
  166. "A380-800 Dimensions & key data". Airbus. Archived from the original on 8 July 2012. Retrieved 12 December 2011. 320,000 L
  167. Calculated: 320,000 L × 0.804 kg/L × 43.15  MJ/kg = 11.1×1012 J
  168. "International Space Station: The ISS to Date". NASA. Archived from the original on 11 June 2015. Retrieved 23 August 2011.
  169. "The wizards of orbits". European Space Agency. Retrieved 10 December 2011. The International Space Station, for example, flies at 7.7 km/s in one of the lowest practicable orbits
  170. Calculated: E = 1/2 m.v2 = 1/2 × 417000 kg × (7700m/s)2 = 1.2×1013 J
  171. Interrante, Abbey (6 September 2024). "Parker Solar Probe". blogs.nasa.gov. Retrieved 23 September 2024.
  172. "1/2*650kg*(430000mph)^2 - Wolfram|Alpha". www.wolframalpha.com. Retrieved 23 September 2024.
  173. "NASA - NSSDCA - Spacecraft - Details". NASA. Retrieved 24 September 2024.
  174. "What was the yield of the Hiroshima bomb?". Warbird's Forum. Retrieved 4 November 2011. 21 kt
  175. Calculated: 15 kt = 15×109 grams of TNT-equivalent × 4.2×103 J/gram TNT-equivalent = 6.3×1013 J
  176. "Conversion from kg to J". NIST. Retrieved 4 November 2011.
  177. "JPL – Fireballs and bolides". Jet Propulsion Laboratory. NASA. Retrieved 13 April 2017.
  178. 1 2 "How much energy does a hurricane release?". FAQ : HURRICANES, TYPHOONS, AND TROPICAL CYCLONES. NOAA. Retrieved 12 November 2011.
  179. "The Gathering Storms". COSMOS. Archived from the original on 4 April 2012. Retrieved 10 December 2011.
  180. 1 2 3 4 "Country Comparison :: Electricity – consumption". The World Factbook. CIA. Archived from the original on 28 January 2012. Retrieved 11 December 2011.
  181. Calculated: 288.6×106 kWh × 3.60×106 J/kWh = 1.04×1015 J
  182. Calculated: 4.2×109 J/ton of TNT-equivalent × 1×106 tons/megaton = 4.2×1015 J/megaton of TNT-equivalent
  183. Calculated: 3.02×109 kWh × 3.60×106 J/kWh = 1.09×1016 J
  184. "Castle Bravo: The Largest U.S. Nuclear Explosion | Brookings". 4 January 2024. Archived from the original on 4 January 2024. Retrieved 4 January 2024.
  185. "0.145kg*c^2*(1/sqrt(1-0.99^2)-1) - Wolfram|Alpha". www.wolframalpha.com. Retrieved 4 January 2024.
  186. Calculated: E = mc2 = 1 kg × (2.998×108 m/s)2 = 8.99×1016 J
  187. Choy, George L.; Boatwright, John (1 January 2007). "The Energy Radiated by the 26 December 2004 Sumatra–Andaman Earthquake Estimated from 10-Minute P -Wave Windows". Bulletin of the Seismological Society of America. 97 (1A): S18–S24. Bibcode:2007BuSSA..97S..18C. doi:10.1785/0120050623. ISSN   1943-3573.
  188. 1 2 3 The Earth has a cross section of 1.274×1014 square meters and the solar constant is 1361 watts per square meter. Note, however, that because portions of Earth reflect light well, the actual energy absorbed is about 1.2*10^17 watts, from an average albedo of 0.3.
  189. "The Soviet Weapons Program – The Tsar Bomba". The Nuclear Weapon Archive. Retrieved 4 November 2011.
  190. Calculated: 50×106 tons TNT-equivalent × 4.2×109 J/ton TNT-equivalent = 2.1×1017 J
  191. Díaz, J. S.; Rigby, S. E. (1 September 2022). "Energetic output of the 2022 Hunga Tonga–Hunga Ha'apai volcanic eruption from pressure measurements". Shock Waves. 32 (6): 553–561. Bibcode:2022ShWav..32..553D. doi: 10.1007/s00193-022-01092-4 . ISSN   1432-2153.
  192. Calculated to be 61 megatons of TNT, equivalent to 2.552×1017 J
  193. Calculated: 115.6×109 kWh × 3.60×106 J/kWh = 4.16×1017 J
  194. "1000*1/2*(0.1*299792458)^2*1/sqrt(1-0.1^2) joules - Wolfram|Alpha". www.wolframalpha.com. Retrieved 11 September 2024.
  195. Alexander, R. McNeill (1989). Dynamics of Dinosaurs and Other Extinct Giants. Columbia University Press. p. 144. ISBN   978-0-231-06667-9. the explosion of the island volcano Krakatoa in 1883, had about 200 megatonnes energy.
  196. Calculated: 200×106 tons of TNT equivalent × 4.2×109 J/ton of TNT equivalent = 8.4×1017 J
  197. This value appears to be referred only to the third explosion on 27 August, 10.02 a.m. According to reports, the third explosion was by far the largest; it is associated to the biggest sound in the recorded history, the highest tsunami during the eruption and the most powerful shock waves rounded the world several times. 200 Megatons of TNT are often referred as the total energy released by the entire eruption, but it's plausible that are rather the energy released by the single third explosion, considering the effects.
  198. "2602TWh to J - Wolfram|Alpha". www.wolframalpha.com. Retrieved 23 September 2024.
  199. "WNA report: Nuclear power generation increased globally in 2023". www.ans.org. Retrieved 23 September 2024.
  200. 1 2 3 4 Yoshida, Masaki; Santosh, M. (1 July 2020). "Energetics of the Solid Earth: An integrated perspective". Energy Geoscience. 1 (1–2): 28–35. Bibcode:2020EneG....1...28Y. doi: 10.1016/j.engeos.2020.04.001 . ISSN   2666-7592.
  201. Mizokami, Kyle (1 April 2019). "Here's What Would Happen If We Blew Up All the World's Nukes at Once". Popular Mechanics. Retrieved 8 April 2021.
  202. Calculated: 3.741×1012 kWh × 3.600×106 J/kWh = 1.347×1019 J
  203. "United States". The World Factbook. USA. Retrieved 11 December 2011.
  204. Calculated: 3.953×1012 kWh × 3.600×106 J/kWh = 1.423×1019 J
  205. 1 2 "World". The World Factbook. CIA. Retrieved 11 December 2011.
  206. Calculated: 17.8×1012 kWh × 3.60×106 J/kWh = 6.41×1019 J
  207. Calculated: 18.95×1012 kWh × 3.60×106 J/kWh = 6.82×1019 J
  208. Klemetti, Erik (10 April 2015). "Tambora 1815: Just How Big Was The Eruption?". Wired. ISSN   1059-1028 . Retrieved 25 May 2024.
  209. "1/6(1km^3)(3.5 g/cm^3)(20km/s)^2 - Wolfram|Alpha". www.wolframalpha.com. Retrieved 11 September 2024.
  210. "How often do asteroids strike Earth?". Catalina Sky Survey. Retrieved 11 September 2024.
  211. "Severe Weather: Hurricane energetics". www.atmo.arizona.edu. Retrieved 24 May 2024.
  212. 1 2 3 4 5 "Statistical Review of World Energy 2011" (PDF). BP. Archived from the original (PDF) on 2 September 2011. Retrieved 9 December 2011.
  213. Calculated: 12002.4×106 tonnes of oil equivalent × 42×109 J/tonne of oil equivalent = 5.0×1020 J
  214. Institute, Energy. "Home". Statistical review of world energy. Retrieved 11 September 2024.
  215. "2023 saw a second consecutive record year for global primary energy consumption as it grew by 2%, reaching 620 EJ."
  216. 1 2 3 "Global Uranium Resources to Meet Projected Demand | International Atomic Energy Agency". iaea.org. June 2006. Retrieved 26 December 2016.
  217. "U.S. Energy Information Administration, International Energy Generation".
  218. "U.S. EIA International Energy Outlook 2007". eia.doe.gov. Retrieved 26 December 2016.
  219. Final number is computed. Energy Outlook 2007 shows 15.9% of world energy is nuclear. IAEA estimates conventional uranium stock, at today's prices is sufficient for 85 years. Convert billion kilowatt-hours to joules then: 6.25×1019×0.159×85 = 8.01×1020.
  220. Calculated: "6608.9 trillion cubic feet" => 6608.9×103 billion cubic feet × 0.025 million tonnes of oil equivalent/billion cubic feet × 1×106 tonnes of oil equivalent/million tonnes of oil equivalent × 42×109 J/tonne of oil equivalent = 6.9×1021 J
  221. Calculated: "188.8 thousand million tonnes" => 188.8×109 tonnes of oil × 42×109 J/tonne of oil = 7.9×1021 J
  222. Cheng, Lijing; Foster, Grant; Hausfather, Zeke; Trenberth, Kevin E.; Abraham, John (2022). "Improved Quantification of the Rate of Ocean Warming". Journal of Climate. 35 (14): 4827–4840. Bibcode:2022JCli...35.4827C. doi: 10.1175/JCLI-D-21-0895.1 .Calculated per reference: 0.58 W·m−2 is 9.3×1021 J·yr−1 in the global domain
  223. Matsuzawa, Toru (1 June 2014). "The Largest Earthquakes We Should Prepare for". Journal of Disaster Research. 9 (3): 248–251. doi: 10.20965/jdr.2014.p0248 .
  224. Calculated: 1.27×1014 m2 × 1370 W/m2 × 86400 s/day = 1.5×1022 J
  225. Holm-Alwmark, Sanna; Rae, Auriol S. P.; Ferrière, Ludovic; Alwmark, Carl; Collins, Gareth S. (2 October 2017). "Combining shock barometry with numerical modeling: Insights into complex crater formation—The example of the Siljan impact structure (Sweden)". Meteoritics & Planetary Science. 52 (12): 2521–2549. Bibcode:2017M&PS...52.2521H. doi:10.1111/maps.12955. ISSN   1086-9379.
  226. Calculated: 860938 million tonnes of coal => 860938×106 tonnes of coal × (1/1.5 tonne of oil equivalent / tonne of coal) × 42×109 J/tonne of oil equivalent = 2.4×1022 J
  227. Calculated: natural gas + petroleum + coal = 6.9×1021 J + 7.9×1021 J + 2.4×1022 J = 3.9×1022 J
  228. Fujii, Yushiro; Satake, Kenji; Watada, Shingo; Ho, Tung-Cheng (1 December 2021). "Re-examination of Slip Distribution of the 2004 Sumatra–Andaman Earthquake (Mw 9.2) by the Inversion of Tsunami Data Using Green's Functions Corrected for Compressible Seawater Over the Elastic Earth". Pure and Applied Geophysics. 178 (12): 4777–4796. doi: 10.1007/s00024-021-02909-6 . ISSN   1420-9136.
  229. Gudmundsson, Agust (27 May 2014). "Elastic energy release in great earthquakes and eruptions". Frontiers in Earth Science. 2: 10. Bibcode:2014FrEaS...2...10G. doi: 10.3389/feart.2014.00010 . ISSN   2296-6463.
  230. Richards, Mark A.; Alvarez, Walter; Self, Stephen; Karlstrom, Leif; Renne, Paul R.; Manga, Michael; Sprain, Courtney J.; Smit, Jan; Vanderkluysen, Loÿc; Gibson, Sally A. (1 November 2015). "Triggering of the largest Deccan eruptions by the Chicxulub impact". Geological Society of America Bulletin . 127 (11–12): 1507–1520. Bibcode:2015GSAB..127.1507R. doi:10.1130/B31167.1. ISSN   0016-7606. S2CID   3463018.
  231. Echaurren, J. C. (2010). Numerical Estimations of Hydrothermal Zones, Trough Mathematical Calculations for Impact Conditions, on the Sudbury Structure, Ontario, Canada. Astrobiology Science Conference 2010. Bibcode:2010LPICo1538.5192E.
  232. Margot, Jean-Luc; Campbell, Donald B.; Giorgini, Jon D.; Jao, Joseph S.; Snedeker, Lawrence G.; Ghigo, Frank D.; Bonsall, Amber (July 2024). "Spin state and moment of inertia of Venus". Nature Astronomy. 5 (7): 676–683. doi:10.1038/s41550-021-01339-7. ISSN   2397-3366.
  233. "1/2*0.337*4.87*10^24kg*(6052km)^2*(2pi/(243*86400s))^2 - Wolfram|Alpha". www.wolframalpha.com. Retrieved 23 September 2024.
  234. Clarification of calculation: Rotational energy = (defined equal to) 1/2 * Moment of Inertia Factor * Mass * Radius^2 * Angular Velocity^2 The inertial factor has been normalized, and takes on a value between 0 and 1. In this case it is 0.337(24).
  235. Calculated: 1.27×1014 m2 × 1370 W/m2 × 86400 s/day = 5.5×1024 J
  236. Hudson, Hugh S. (8 September 2021). "Carrington Events". Annual Review of Astronomy and Astrophysics. 59 (1): 445–477. Bibcode:2021ARA&A..59..445H. doi:10.1146/annurev-astro-112420-023324. ISSN   0066-4146.
  237. Zahnle, K. J. (26 August 2018). "Climatic Effect of Impacts on the Ocean". Comparative Climatology of Terrestrial Planets III: From Stars to Surfaces. 2065: 2056. Bibcode:2018LPICo2065.2056Z.
  238. Howard, Ward S.; Tilley, Matt A.; Corbett, Hank; Youngblood, Allison; Loyd, R. O. Parke; Ratzloff, Jeffrey K.; Law, Nicholas M.; Fors, Octavi; del Ser, Daniel; Shkolnik, Evgenya L.; Ziegler, Carl; Goeke, Erin E.; Pietraallo, Aaron D.; Haislip, Joshua (20 June 2018). "The First Naked-Eye Superflare Detected from Proxima Centauri". The Astrophysical Journal Letters. 860 (2): L30. arXiv: 1804.02001 . Bibcode:2018ApJ...860L..30H. doi: 10.3847/2041-8213/aacaf3 . ISSN   2041-8205.
  239. 1 2 3 "Ask Us: Sun: Amount of Energy the Earth Gets from the Sun". Cosmicopia. NASA. Archived from the original on 16 August 2000. Retrieved 4 November 2011.
  240. Lii, Jiangning. "Seismic effects of the Caloris basin impact, Mercury" (PDF). MIT.
  241. Okamoto, Soshi; Notsu, Yuta; Maehara, Hiroyuki; Namekata, Kosuke; Honda, Satoshi; Ikuta, Kai; Nogami, Daisaku; Shibata, Kazunari (11 January 2021). "Statistical Properties of Superflares on Solar-type Stars: Results Using All of the Kepler Primary Mission Data". The Astrophysical Journal. 906 (2): 72. arXiv: 2011.02117 . Bibcode:2021ApJ...906...72O. doi: 10.3847/1538-4357/abc8f5 . ISSN   0004-637X.
  242. "1.386 billion km^3 * 1024kg/1m^3 * (2257J+4.19*(100-20)cal)/g - Wolfram|Alpha". www.wolframalpha.com. Retrieved 23 September 2024.
  243. "Heat of Vaporization". Archived from the original on 7 April 2023. Retrieved 24 September 2024.
  244. "SCTqh.png (PNG Image, 500 x 300 pixels)". i.sstatic.net. Retrieved 24 September 2024Heat Capacity v.s. Temperature graph for water. 4.19 taken as average value for 20 to 100 degrees C.{{cite web}}: CS1 maint: postscript (link)
  245. "0.145kg*c^2*(1/sqrt(1-0.9999999999999999999999951^2)-1) - Wolfram|Alpha". www.wolframalpha.com. Retrieved 4 January 2024.
  246. "Moon Fact Sheet". NASA. Retrieved 16 December 2011.
  247. Calculated: KE = 1/2 × m × v2. v = 1.023×103 m/s. m = 7.349×1022 kg. KE = 1/2 × (7.349×1022 kg) × (1.023×103 m/s)2 = 3.845×1028 J.
  248. Inoue, Shun; Maehara, Hiroyuki; Notsu, Yuta; Namekata, Kosuke; Honda, Satoshi; Namizaki, Keiichi; Nogami, Daisaku; Shibata, Kazunari (2023). "Detection of a High-velocity Prominence Eruption Leading to a CME Associated with a Superflare on the RS CVn-type Star V1355 Orionis". The Astrophysical Journal. 948 (1): 9. arXiv: 2301.13453 . Bibcode:2023ApJ...948....9I. doi: 10.3847/1538-4357/acb7e8 . ISSN   0004-637X.
  249. Cowing, Keith (28 April 2023). "Superflare With Massive, High-velocity Prominence Eruption". SpaceRef. Retrieved 26 May 2024.
  250. "Moment of Inertia—Earth". Eric Weisstein's World of Physics. Retrieved 5 November 2011.
  251. Allain, Rhett. "Rotational energy of the Earth as an energy source". .dotphysics. Science Blogs. Archived from the original on 17 November 2011. Retrieved 5 November 2011. the Earth takes 23.9345 hours to rotate
  252. Calculated: E_rotational = 1/2 × I × w2 = 1/2 × (8.0×1037 kg m2) × (2×pi/(23.9345 hour period × 3600 seconds/hour))2 = 2.1×1029 J
  253. "gravitational binding energy calculator - Wolfram|Alpha". www.wolframalpha.com. Retrieved 11 September 2024.
  254. Dhar, Michael (6 November 2022). "What was Earth's biggest explosion?". livescience.com. Retrieved 27 May 2024.
  255. Firestone, Richard B. (29 May 2023). "The origin of the terrestrial planets". arXiv: 2305.18635 [astro-ph.EP].
  256. Calculated: 3.8×1026 J/s × 86400 s/day = 3.3×1031 J
  257. Typinski, Dave (January 2009). "Earth's Gravitational Binding Energy" (PDF). Archived from the original (PDF) on 4 January 2024. Retrieved 4 January 2024.
  258. "pi*(11700km)^2*stefan boltzmann constant*(25200K)^4*yr - Wolfram|Alpha". www.wolframalpha.com. Retrieved 23 September 2024.
  259. "Earth Fact Sheet". 26 December 2023. Archived from the original on 26 December 2023. Retrieved 4 January 2024.
  260. KE = 1/2 × 5.9722×10^24 kg × (30.29 km/s)^2 = 2.74×10^33 J
  261. Calculated: 3.8×1026 J/s × 86400 s/day × 365.25 days/year = 1.2×1034 J
  262. Schaefer, Bradley E. (2 May 2024). "Recurrent Nova V2487 Oph Had Superflares in 1941 and 1942 With Radiant Energies 1042.5±1.6 Ergs". arXiv: 2405.01210 [astro-ph.SR].
  263. "9.9e-30g/cm3*1ly3*c^2 - Wolfram|Alpha". www.wolframalpha.com. Retrieved 13 September 2024.
  264. 1 2 3 4 "WMAP- Content of the Universe". wmap.gsfc.nasa.gov. Retrieved 11 September 2024.
  265. "NASA - Cosmic Explosion Among the Brightest in Recorded History". www.nasa.gov. Retrieved 27 March 2022.
  266. Palmer, D. M.; Barthelmy, S.; Gehrels, N.; Kippen, R. M.; Cayton, T.; Kouveliotou, C.; Eichler, D.; Wijers, R. a. M. J.; Woods, P. M.; Granot, J.; Lyubarsky, Y. E. (April 2005). "A giant γ-ray flare from the magnetar SGR 1806–20". Nature. 434 (7037): 1107–1109. arXiv: astro-ph/0503030 . Bibcode:2005Natur.434.1107P. doi:10.1038/nature03525. ISSN   1476-4687. PMID   15858567. S2CID   16579885.
  267. Stella, L.; Dall'Osso, S.; Israel, G. L.; Vecchio, A. (17 November 2005). "Gravitational Radiation from Newborn Magnetars in the Virgo Cluster". The Astrophysical Journal. 634 (2): L165–L168. arXiv: astro-ph/0511068 . Bibcode:2005ApJ...634L.165S. doi:10.1086/498685. ISSN   0004-637X. S2CID   18172538.
  268. "7.346e 22kg*c^2 - Wolfram|Alpha". www.wolframalpha.com. Retrieved 13 September 2024.
  269. "Moon Fact Sheet". nssdc.gsfc.nasa.gov. Retrieved 13 September 2024.
  270. "9.9e-30g/cm3*1pc3*c^2 - Wolfram|Alpha". www.wolframalpha.com. Retrieved 13 September 2024.

  271. Chandrasekhar, S. 1939, An Introduction to the Study of Stellar Structure (Chicago: U. of Chicago; reprinted in New York: Dover), section 9, eqs. 90–92, p. 51 (Dover edition)
    Lang, K. R. 1980, Astrophysical Formulae (Berlin: Springer Verlag), p. 272
  272. "Earth Fact Sheet". nssdc.gsfc.nasa.gov. Retrieved 13 September 2024.
  273. "5.9722e 24kg*c^2 - Wolfram|Alpha". www.wolframalpha.com. Retrieved 13 September 2024.
  274. Frail, D. A.; Kulkarni, S. R.; Sari, R.; Djorgovski, S. G.; Bloom, J. S.; Galama, T. J.; Reichart, D. E.; Berger, E.; Harrison, F. A.; Price, P. A.; Yost, S. A.; Diercks, A.; Goodrich, R. W.; Chaffee, F. (2001). "Beaming in Gamma-Ray Bursts: Evidence for a Standard Energy Reservoir". The Astrophysical Journal. 562 (1): L55. arXiv: astro-ph/0102282 . Bibcode:2001ApJ...562L..55F. doi:10.1086/338119. S2CID   1047372. "the gamma-ray energy release, corrected for geometry, is narrowly clustered around 5 × 1050 erg"
  275. Calculated: 5×1050 erg × 1×10−7 J/erg = 5×1043 J
  276. Lyutikov, Maxim (2022). "On the nature of fast blue optical transients". Monthly Notices of the Royal Astronomical Society. 515 (2): 2293–2304. arXiv: 2204.08366 . doi: 10.1093/mnras/stac1717 via Oxford Academic.
  277. Lu, Wenbin; Kumar, Pawan (28 September 2018). "On the Missing Energy Puzzle of Tidal Disruption Events". The Astrophysical Journal. 865 (2): 128. arXiv: 1802.02151 . Bibcode:2018ApJ...865..128L. doi: 10.3847/1538-4357/aad54a . ISSN   1538-4357. S2CID   56015417.
  278. Coppejans, D. L.; Margutti, R.; Terreran, G.; Nayana, A. J.; Coughlin, E. R.; Laskar, T.; Alexander, K. D.; Bietenholz, M.; Caprioli, D.; Chandra, P.; Drout, M. R. (26 May 2020). "A Mildly Relativistic Outflow from the Energetic, Fast-rising Blue Optical Transient CSS161010 in a Dwarf Galaxy". The Astrophysical Journal. 895 (1): L23. arXiv: 2003.10503 . Bibcode:2020ApJ...895L..23C. doi: 10.3847/2041-8213/ab8cc7 . ISSN   2041-8213. S2CID   214623364.
  279. 1 2 Frail, D. A.; Kulkarni, S. R.; Sari, R.; Djorgovski, S. G.; Bloom, J. S.; Galama, T. J.; Reichart, D. E.; Berger, E.; Harrison, F. A.; Price, P. A.; Yost, S. A.; Diercks, A.; Goodrich, R. W.; Chaffee, F. (1 November 2001). "Beaming in Gamma-Ray Bursts: Evidence for a Standard Energy Reservoir". The Astrophysical Journal. 562 (1): L55. arXiv: astro-ph/0102282 . Bibcode:2001ApJ...562L..55F. doi:10.1086/338119. ISSN   0004-637X.
  280. Li, Miao; Li, Yuan; Bryan, Greg L.; Ostriker, Eve C.; Quataert, Eliot (5 May 2020). "The Impact of Type Ia Supernovae in Quiescent Galaxies. I. Formation of the Multiphase Interstellar Medium". The Astrophysical Journal. 894 (1): 44. arXiv: 1909.03138 . Bibcode:2020ApJ...894...44L. doi: 10.3847/1538-4357/ab86b4 . ISSN   0004-637X.
  281. "Astronomy with an online telescope". Open Learning. Retrieved 11 September 2024.
  282. "1.37e27 kg * 9e16 m^2/s^2 - Wolfram|Alpha". www.wolframalpha.com. Retrieved 11 September 2024.
  283. Nakamura, Takayoshi; Umeda, Hideyuki; Iwamoto, Koichi; Nomoto, Ken’ichi; Hashimoto, Masa-aki; Hix, W. Raphael; Thielemann, Friedrich-Karl (10 July 2001). "Explosive Nucleosynthesis in Hypernovae". The Astrophysical Journal. 555 (2): 880–899. arXiv: astro-ph/0011184 . Bibcode:2001ApJ...555..880N. doi:10.1086/321495. ISSN   0004-637X.
  284. Nicholl, Matt; Blanchard, Peter K.; Berger, Edo; Chornock, Ryan; Margutti, Raffaella; Gomez, Sebastian; Lunnan, Ragnhild; Miller, Adam A.; Fong, Wen-fai; Terreran, Giacomo; Vigna-Gómez, Alejandro (September 2020). "An extremely energetic supernova from a very massive star in a dense medium". Nature Astronomy. 4 (9): 893–899. arXiv: 2004.05840 . Bibcode:2020NatAs...4..893N. doi:10.1038/s41550-020-1066-7. ISSN   2397-3366. S2CID   215744925.
  285. Suzuki, Akihiro; Nicholl, Matt; Moriya, Takashi J.; Takiwaki, Tomoya (1 February 2021). "Extremely Energetic Supernova Explosions Embedded in a Massive Circumstellar Medium: The Case of SN 2016aps". The Astrophysical Journal. 908 (1): 99. arXiv: 2012.13283 . Bibcode:2021ApJ...908...99S. doi: 10.3847/1538-4357/abd6ce . ISSN   0004-637X.
  286. Godoy-Rivera, D.; Stanek, K. Z.; Kochanek, C. S.; Chen, Ping; Dong, Subo; Prieto, J. L.; Shappee, B. J.; Jha, S. W.; Foley, R. J.; Pan, Y.-C.; Holoien, T. W.-S.; Thompson, Todd. A.; Grupe, D.; Beacom, J. F. (1 April 2017). "The unexpected, long-lasting, UV rebrightening of the superluminous supernova ASASSN-15lh". Monthly Notices of the Royal Astronomical Society. 466 (2): 1428–1443. arXiv: 1605.00645 . doi: 10.1093/mnras/stw3237 . ISSN   0035-8711.
  287. Kankare, E.; Kotak, R.; Mattila, S.; Lundqvist, P.; Ward, M. J.; Fraser, M.; Lawrence, A.; Smartt, S. J.; Meikle, W. P. S.; Bruce, A.; Harmanen, J. (December 2017). "A population of highly energetic transient events in the centres of active galaxies". Nature Astronomy. 1 (12): 865–871. arXiv: 1711.04577 . Bibcode:2017NatAs...1..865K. doi:10.1038/s41550-017-0290-2. ISSN   2397-3366. S2CID   119421626.
  288. Both ASSASN-15lh and PS1-10adi are indicated as supernovae and probably they are; actually, other mechanisms are proposed to explain them, more or less in accordance to the characteristics of supernovae
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  309. 1 2 It is important to specify that the energetic reduction for beaming (invoked to explain so much energetics and jet breaks) is expected in the "Fireball model", which is the traditional one; other main models explain both Long and Short GRBs with binary systems, such as "Induced Gravitational Collapse", "Binary-Driven Hypernovae" which refer to the "Fireshell" one, in which cases the beaming isn't assumpted and the isotropic energy is a real value of energy due to the rotational energy of the stellar black hole and vacuum polarization in an electromagnetic field, which are able to explain energetics up and over 1047 J
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