TNT equivalent is a convention for expressing energy, typically used to describe the energy released in an explosion. The ton of TNT is a unit of energy defined by convention to be 4.184 gigajoules (1 gigacalorie),[1] which is the approximate energy released in the detonation of a metric ton (1,000 kilograms) of TNT. In other words, for each gram of TNT exploded, 4.184 kilojoules (or 4184 joules) of energy are released.
TNT equivalent | |
---|---|
General information | |
Unit system | Non-standard |
Unit of | Energy |
Symbol | t, ton of TNT |
Conversions | |
1 t in ... | ... is equal to ... |
SI base units | ≈ 4.184 gigajoules |
CGS | 109 calories |
This convention intends to compare the destructiveness of an event with that of conventional explosive materials, of which TNT is a typical example, although other conventional explosives such as dynamite contain more energy.
Kiloton and megaton
editThe "kiloton (of TNT equivalent)" is a unit of energy equal to 4.184 terajoules (4.184×1012 J).[2]
The "megaton (of TNT equivalent)" is a unit of energy equal to 4.184 petajoules (4.184×1015 J).[3]
The kiloton and megaton of TNT equivalent have traditionally been used to describe the energy output, and hence the destructive power, of a nuclear weapon. The TNT equivalent appears in various nuclear weapon control treaties, and has been used to characterize the energy released in asteroid impacts.[4]
Historical derivation of the value
editAlternative values for TNT equivalency can be calculated according to which property is being compared and when in the two detonation processes the values are measured.[5][6][7][8]
Where for example the comparison is by energy yield, an explosive's energy is normally expressed for chemical purposes as the thermodynamic work produced by its detonation. For TNT this has been accurately measured as 4,686 J/g from a large sample of air blast experiments, and theoretically calculated to be 4,853 J/g.[9]
However even on this basis, comparing the actual energy yields of a large nuclear device and an explosion of TNT can be slightly inaccurate. Small TNT explosions, especially in the open, don't tend to burn the carbon-particle and hydrocarbon products of the explosion. Gas-expansion and pressure-change effects tend to "freeze" the burn rapidly. A large open explosion of TNT may maintain fireball temperatures high enough so that some of those products do burn up with atmospheric oxygen.[10]
Such differences can be substantial. For safety purposes a range as wide as 2,673–6,702 J has been stated for a gram of TNT upon explosion.[11]
Thus one can state that a nuclear bomb has a yield of 15 kt (6.3×1013 J), but the explosion of an actual 15,000 ton pile of TNT may yield (for example) 8×1013 J due to additional carbon/hydrocarbon oxidation not present with small open-air charges.[10]
These complications have been sidestepped by convention. The energy released by one gram of TNT was arbitrarily defined as a matter of convention to be 4,184 J,[12] which is exactly one kilocalorie.
A kiloton of TNT can be visualized as a cube of TNT 8.46 metres (27.8 ft) on a side.
Grams TNT | Symbol | Tons TNT | Symbol | Energy [joules] | Energy [Wh] | Corresponding mass loss[a] |
---|---|---|---|---|---|---|
milligram of TNT | mg | nanoton of TNT | nt | 4.184 J or 4.184 joules | 1.162 mWh | 46.55 fg |
gram of TNT | g | microton of TNT | μt | 4.184×103 J or 4.184 kilojoules | 1.162 Wh | 46.55 pg |
kilogram of TNT | kg | milliton of TNT | mt | 4.184×106 J or 4.184 megajoules | 1.162 kWh | 46.55 ng |
megagram of TNT | Mg | ton of TNT | t | 4.184×109 J or 4.184 gigajoules | 1.162 MWh | 46.55 μg |
gigagram of TNT | Gg | kiloton of TNT | kt | 4.184×1012 J or 4.184 terajoules | 1.162 GWh | 46.55 mg |
teragram of TNT | Tg | megaton of TNT | Mt | 4.184×1015 J or 4.184 petajoules | 1.162 TWh | 46.55 g |
petagram of TNT | Pg | gigaton of TNT | Gt | 4.184×1018 J or 4.184 exajoules | 1.162 PWh | 46.55 kg |
Conversion to other units
edit1 ton of TNT equivalent is approximately:
- 1.0×109 calories[13]
- 4.184×109 joules[14]
- 3.96831×106 British thermal units[15]
- 3.086×109 foot-pounds[16]
- 1.162×103 kilowatt-hours[17]
- 2.611×1028 electronvolts
Examples
editEnergy | Description | |
---|---|---|
Megatons of TNT | Watt-hours [Wh] | |
1×10−12 | 1.162 Wh | ≈ 1 food calorie (large calorie, kcal), which is the approximate amount of energy needed to raise the temperature of one kilogram of water by one degree Celsius at a pressure of one atmosphere. |
1×10−9 | 1.162 kWh | Under controlled conditions one kilogram of TNT can destroy (or even obliterate) a small vehicle. |
4.8×10−9 | 5.6 kWh | The energy to burn 1 kilogram of wood.[18] |
1×10−8 | 11.62 kWh | The approximate radiant heat energy released during 3-phase, 600 V, 100 kA arcing fault in a 0.5 m × 0.5 m × 0.5 m (20 in × 20 in × 20 in) compartment within a 1-second period.[further explanation needed][citation needed] |
1.2×10−8 | 13.94 kWh | Amount of TNT used (12 kg) in Coptic church explosion in Cairo, Egypt on December 11, 2016 that left 29 dead and 47 injured[19] |
1.9×10−6 | 2.90 MWh | The television show MythBusters used 2.5 tons of ANFO to make "homemade" diamonds. (Episode 116.) |
2.4×10−7–2.4×10−6 | 280–2,800 kWh | The energy output released by an average lightning discharge.[20] |
(1–44)×10−6 | 1.16–51.14 MWh | Conventional bombs yield from less than one ton to FOAB's 44 tons. The yield of a Tomahawk cruise missile is equivalent to 500 kg of TNT.[21] |
4.54×10−4 | 581 MWh | A real 0.454-kiloton-of-TNT (1.90 TJ) charge at Operation Sailor Hat. If the charge were a full sphere, it would be 1 kiloton of TNT (4.2 TJ). |
1.8×10−3 | 2.088 GWh | Estimated yield of the Beirut explosion of 2,750 tons of ammonium nitrate[22] that killed initially 137 at and near a Lebanese port at 6 p.m. local time Tuesday August 4, 2020.[23] An independent study by experts from the Blast and Impact Research Group at the University of Sheffield predicts the best estimate of the yield of Beirut explosion to be 0.5 kilotons of TNT and the reasonable bound estimate as 1.12 kilotons of TNT.[24] |
(1–2)×10−3 | 1.16–2.32 GWh | Estimated yield of the Oppau explosion that killed more than 500 at a German fertilizer factory in 1921. |
2.3×10−3 | 2.67 GWh | Amount of solar energy falling on 4,000 m2 (1 acre) of land in a year is 9.5 TJ (2,650 MWh) (an average over the Earth's surface).[25] |
2.9×10−3 | 3.4 GWh | The Halifax Explosion in 1917 was the accidental detonation of 200 tons of TNT and 2,300 tons of Picric acid[26] |
3.2×10−3 | 3.6 GWh | The Operation Big Bang on April 18, 1947, blasted the bunkers on Heligoland. It accumulated 6700 metric tons of surplus World War II ammunition placed in various locations around the island and set off. The energy released was 1.3×1013 J, or about 3.2 kilotons of TNT equivalent.[27] |
4×10−3 | 9.3 GWh | Minor Scale, a 1985 United States conventional explosion, using 4,744 tons of ANFO explosive to provide a scaled equivalent airblast of an eight kiloton (33.44 TJ) nuclear device,[28] is believed to be the largest planned detonation of conventional explosives in history. |
(1.5–2)×10−2 | 17.4–23.2 GWh | The Little Boy atomic bomb dropped on Hiroshima on August 6, 1945, exploded with an energy of about 15 kilotons of TNT (63 TJ) killing between 90,000 and 166,000 people,[29] and the Fat Man atomic bomb dropped on Nagasaki on August 9, 1945, exploded with an energy of about 20 kilotons of TNT (84 TJ) killing over 60,000.[29] The modern nuclear weapons in the United States arsenal range in yield from 0.3 kt (1.3 TJ) to 1.2 Mt (5.0 PJ) equivalent, for the B83 strategic bomb. |
>2.4×10−1 | 280 GWh | The typical energy yield of severe thunderstorms.[30] |
1.5×10−5 – 6×10−1 | 20 MWh – 700 GWh | The estimated kinetic energy of tornados.[31] |
1 | 1.16 TWh | The energy contained in one megaton of TNT (4.2 PJ) is enough to power the average American household for 103,000 years.[32] The 30 Mt (130 PJ) estimated upper limit blast power of the Tunguska event could power the same average home for more than 3,100,000 years. The energy of that blast could power the entire United States for 3.27 days.[33] |
8.6 | 10 TWh | The energy output that would be released by a typical tropical cyclone in one minute, primarily from water condensation. Winds constitute 0.25% of that energy.[34] |
16 | 18.6 TWh | The approximate radiated surface energy released in a magnitude 8 earthquake.[35] |
21.5 | 25 TWh | The complete conversion of 1 kg of matter into pure energy would yield the theoretical maximum (E = mc2) of 89.8 petajoules, which is equivalent to 21.5 megatons of TNT. No such method of total conversion as combining 500 grams of matter with 500 grams of antimatter has yet been achieved. In the event of proton–antiproton annihilation, approximately 50% of the released energy will escape in the form of neutrinos, which are almost undetectable.[36] Electron–positron annihilation events emit their energy entirely as gamma rays. |
24 | 28 TWh | Approximate total yield of the 1980 eruption of Mount St. Helens.[37] |
26.3 | 30.6 TWh | Energy released by the 2004 Indian Ocean earthquake.[38] |
45 | 53 TWh | The energy released in the 2011 Tōhoku earthquake and tsunami was over 200,000 times the surface energy and was calculated by the USGS at 1.9×1017 joules,[39][40] slightly less than the 2004 Indian Ocean quake. It was estimated at a moment magnitude of 9.0–9.1. |
50–56 | 58 TWh | The Soviet Union developed a prototype thermonuclear device, nicknamed the Tsar Bomba, which was tested at 50–56 Mt (210–230 PJ), but had a maximum theoretical design yield of 100 Mt (420 PJ).[41] The effective destructive potential of such a weapon varies greatly, depending on such conditions as the altitude at which it is detonated, the characteristics of the target, the terrain, and the physical landscape upon which it is detonated. |
61 | 70.9 TWh | The energy released by the 2022 Hunga Tonga–Hunga Haʻapai volcanic eruption, in the southern Pacific Ocean, is estimated to have been equivalent to 61 Megatons of TNT.[42] |
84 | 97.04 TWh | The solar irradiance on Earth every second.[b] |
200 | 230 TWh | The total energy released by the 1883 eruption of Krakatoa in the Dutch East Indies (present-day Indonesia).[43] |
540 | 630 TWh | The total energy produced worldwide by all nuclear testing and combat usage combined, from the 1940s to the present, is about 540 megatons. |
1,460 | 1.69 PWh | The total global nuclear arsenal is about 15,000 nuclear warheads[44][45][46] with a destructive capacity of around 1460 megatons[47][48][49][50] or 1.46 gigatons (1,460 million tons) of TNT. This is the equivalent of 6.11×1018 joules of energy |
2,680[dubious – discuss] | 3 PWh | The energy yield of the 1960 Valdivia earthquake, was estimated at a moment magnitude of 9.4–9.6. This is the most powerful earthquake recorded in history.[51][52] |
2,870 | 3.34 PWh | The energy released by a hurricane per day during condensation.[53] |
33,000 | 38.53 PWh | The total energy released by the 1815 eruption of Mount Tambora in the island of Sumbawa in Indonesia. Yielded the equivalent of 2.2 million Little Boys (the first atomic bomb to drop on Japan) or one-quarter of the entire world's annual energy consumption.[54] This eruption was 4-10 times more destructive than the 1883 Krakatoa eruption.[55] |
240,000 | 280 PWh | The approximate total yield of the super-eruption of the La Garita Caldera is 10,000 times more powerful than the 1980 Mount St. Helens eruption.[56] It was the second most energetic event to have occurred on Earth since the Cretaceous–Paleogene extinction event 66 million years ago. |
301,000 | 350 PWh | The total solar irradiance energy received by Earth in the upper atmosphere per hour.[c][d] |
875,000 | 1.02 EWh | Approximate yield of the last eruption of the Yellowstone supervolcano.[57] |
3.61×106 | 4.2 EWh | The solar irradiance of the Sun every 12 hours.[c][e] |
6×106 | 7 EWh | The estimated energy at impact when the largest fragment of Comet Shoemaker–Levy 9 struck Jupiter is equivalent to 6 million megatons (6 trillion tons) of TNT.[58] |
7.2×107 | 116 EWh | Estimates in 2010 show that the kinetic energy of the Chicxulub impact event yielded 72 teratons of TNT equivalent (1 teraton of TNT equals 106 megatons of TNT) which caused the K-Pg extinction event, wiping out 75% of all species on Earth.[59][60] This is far more destructive than any natural disaster recorded in history. Such an event would've caused global volcanism, earthquakes, megatsunamis, and global climate change.[59][61][62][63][64] |
>2.4×1010 | >28 ZWh | The impact energy of Archean asteroids.[65] |
9.1×1010 | 106 ZWh | The total energy output of the Sun per second.[66] |
2.4×1011 | 280 ZWh | The kinetic energy of the Caloris Planitia impactor.[67] |
5.972×1015 | 6.94 RWh | The explosive energy of a quantity of TNT of the mass of Earth.[68] |
7.89×1015 | 9.17 RWh | Total solar output in all directions per day.[69] |
1.98×1021 | 2.3×1033 Wh | The explosive energy of a quantity of TNT of the mass of the Sun.[70] |
(2.4–4.8)×1028 | (2.8–5.6)×1040 Wh | A type Ia supernova explosion gives off 1–2×1044 joules of energy, which is about 2.4–4.8 hundred billion yottatons (24–48 octillion (2.4–4.8×1028) megatons) of TNT, equivalent to the explosive force of a quantity of TNT over a trillion (1012) times the mass of the planet Earth. This is the astrophysical standard candle used to determine galactic distances.[71] |
(2.4–4.8)×1030 | (2.8–5.6)×1042 Wh | The largest type of supernova observed, gamma-ray bursts (GRBs) release more than 1046 joules of energy.[72] |
1.3×1032 | 1.5×1044 Wh | A merger of two black holes, resulting in the first observation of gravitational waves, released 5.3×1047 joules[73] |
9.6×1053 | 1.12×1066 Wh | Estimated mass-energy of the observable universe.[74] |
Relative effectiveness factor
editThe relative effectiveness factor (RE factor) relates an explosive's demolition power to that of TNT, in units of the TNT equivalent/kg (TNTe/kg). The RE factor is the relative mass of TNT to which an explosive is equivalent: The greater the RE, the more powerful the explosive.
This enables engineers to determine the proper masses of different explosives when applying blasting formulas developed specifically for TNT. For example, if a timber-cutting formula calls for a charge of 1 kg of TNT, then based on octanitrocubane's RE factor of 2.38, it would take only 1.0/2.38 (or 0.42) kg of it to do the same job. Using PETN, engineers would need 1.0/1.66 (or 0.60) kg to obtain the same effects as 1 kg of TNT. With ANFO or ammonium nitrate, they would require 1.0/0.74 (or 1.35) kg or 1.0/0.32 (or 3.125) kg, respectively.
Calculating a single RE factor for an explosive is, however, impossible. It depends on the specific case or use. Given a pair of explosives, one can produce 2× the shockwave output (this depends on the distance of measuring instruments) but the difference in direct metal cutting ability may be 4× higher for one type of metal and 7× higher for another type of metal. The relative differences between two explosives with shaped charges will be even greater. The table below should be taken as an example and not as a precise source of data.
Explosive, grade | Density (g/ml) |
Detonation vel. (m/s) |
Relative effectiveness |
---|---|---|---|
Ammonium nitrate (AN + <0.5% H2O) | 0.88 | 2,700[75] | 0.32[76][77] |
Mercury(II) fulminate | 4.42 | 4,250 | 0.51[78] |
Black powder (75% KNO3 + 19% C + 6% S, ancient low explosive) | 1.65 | 400 | 0.55[79] |
Hexamine dinitrate (HDN) | 1.30 | 5,070 | 0.60 |
Dinitrobenzene (DNB) | 1.50 | 6,025 | 0.60 |
HMTD (hexamine peroxide) | 0.88 | 4,520 | 0.74 |
ANFO (94% AN + 6% fuel oil) | 0.92 | 4,200 | 0.74 |
Urea nitrate | 1.67 | 4,700 | 0.77 |
TATP (acetone peroxide) | 1.18 | 5,300 | 0.80 |
Tovex Extra (AN water gel) commercial product | 1.33 | 5,690 | 0.80 |
Hydromite 600 (AN water emulsion) commercial product | 1.24 | 5,550 | 0.80 |
ANNMAL (66% AN + 25% NM + 5% Al + 3% C + 1% TETA) | 1.16 | 5,360 | 0.87 |
Amatol (50% TNT + 50% AN) | 1.50 | 6,290 | 0.91 |
Nitroguanidine | 1.32 | 6,750 | 0.95 |
Trinitrotoluene (TNT) | 1.60 | 6,900 | 1.00 |
Hexanitrostilbene (HNS) | 1.70 | 7,080 | 1.05 |
Nitrourea | 1.45 | 6,860 | 1.05 |
Tritonal (80% TNT + 20% aluminium)[f] | 1.70 | 6,650 | 1.05 |
Nickel hydrazine nitrate (NHN) | 1.70 | 7,000 | 1.05 |
Amatol (80% TNT + 20% AN) | 1.55 | 6,570 | 1.10 |
Nitrocellulose (13.5% N, NC; AKA guncotton) | 1.40 | 6,400 | 1.10 |
Nitromethane (NM) | 1.13 | 6,360 | 1.10 |
PBXW-126 (22% NTO, 20% RDX, 20% AP, 26% Al, 12% PU's system)[f] | 1.80 | 6,450 | 1.10 |
Diethylene glycol dinitrate (DEGDN) | 1.38 | 6,610 | 1.17 |
PBXIH-135 EB (42% HMX, 33% Al, 25% PCP-TMETN's system)[f] | 1.81 | 7,060 | 1.17 |
PBXN-109 (64% RDX, 20% Al, 16% HTPB's system)[f] | 1.68 | 7,450 | 1.17 |
Triaminotrinitrobenzene (TATB) | 1.80 | 7,550 | 1.17 |
Picric acid (TNP) | 1.71 | 7,350 | 1.17 |
Trinitrobenzene (TNB) | 1.60 | 7,300 | 1.20 |
Tetrytol (70% tetryl + 30% TNT) | 1.60 | 7,370 | 1.20 |
Dynamite, Nobel's (75% NG + 23% diatomite) | 1.48 | 7,200 | 1.25 |
Tetryl | 1.71 | 7,770 | 1.25 |
Torpex (aka HBX, 41% RDX + 40% TNT + 18% Al + 1% wax)[f] | 1.80 | 7,440 | 1.30 |
Composition B (63% RDX + 36% TNT + 1% wax) | 1.72 | 7,840 | 1.33 |
Composition C-3 (78% RDX) | 1.60 | 7,630 | 1.33 |
Composition C-4 (91% RDX) | 1.59 | 8,040 | 1.34 |
Pentolite (56% PETN + 44% TNT) | 1.66 | 7,520 | 1.33 |
Semtex 1A (76% PETN + 6% RDX) | 1.55 | 7,670 | 1.35 |
Hexal (76% RDX + 20% Al + 4% wax)[f] | 1.79 | 7,640 | 1.35 |
RISAL P (50% IPN + 28% RDX + 15% Al + 4% Mg + 1% Zr + 2% NC)[f] | 1.39 | 5,980 | 1.40 |
Hydrazine nitrate | 1.59 | 8,500 | 1.42 |
Mixture: 24% nitrobenzene + 76% TNM | 1.48 | 8,060 | 1.50 |
Mixture: 30% nitrobenzene + 70% nitrogen tetroxide | 1.39 | 8,290 | 1.50 |
Nitroglycerin (NG) | 1.59 | 7,700 | 1.54 |
Methyl nitrate (MN) | 1.21 | 7,900 | 1.54 |
Octol (80% HMX + 19% TNT + 1% DNT) | 1.83 | 8,690 | 1.54 |
Nitrotriazolon (NTO) | 1.87 | 8,120 | 1.60 |
DADNE (1,1-diamino-2,2-dinitroethene, FOX-7) | 1.77 | 8,330 | 1.60 |
Gelignite (92% NG + 7% nitrocellulose) | 1.60 | 7,970 | 1.60 |
Plastics Gel® (in toothpaste tube: 45% PETN + 45% NG + 5% DEGDN + 4% NC) | 1.51 | 7,940 | 1.60 |
Composition A-5 (98% RDX + 2% stearic acid) | 1.65 | 8,470 | 1.60 |
Erythritol tetranitrate (ETN) | 1.72 | 8,206 | 1.60 |
Hexogen (RDX) | 1.78 | 8,600 | 1.60 |
PBXW-11 (96% HMX, 1% HyTemp, 3% DOA) | 1.81 | 8,720 | 1.60 |
Penthrite (PETN) | 1.77 | 8,400 | 1.66 |
Ethylene glycol dinitrate (EGDN) | 1.49 | 8,300 | 1.66 |
MEDINA (Methylene dinitroamine)[80][81] | 1.65 | 8,700 | 1.70 |
Trinitroazetidine (TNAZ) | 1.85 | 9,597 | 1.70 |
Octogen (HMX grade B) | 1.86 | 9,100 | 1.70 |
Hexanitrobenzene (HNB) | 1.97 | 9,340 | 1.80 |
Hexanitrohexaazaisowurtzitane (HNIW; AKA CL-20) | 1.97 | 9,500 | 1.90 |
DDF (4,4’-Dinitro-3,3’-diazenofuroxan) | 1.98 | 10,000 | 1.95 |
Heptanitrocubane (HNC)[g] | 1.92 | 9,200 | N/A |
Octanitrocubane (ONC) | 1.95 | 10,600 | 2.38 |
Octaazacubane (OAC)[g] | 2.69 | 15,000 | >5.00 |
Nuclear examples
editWeapon | Total yield (kilotons of TNT) |
Mass (kg) |
Relative effectiveness |
---|---|---|---|
GBU-57 bomb (Massive Ordnance Penetrator, MOP) | 0.0035 | 13,600 | 0.26 |
Grand Slam (Earthquake bomb, M110) | 0.0065 | 9,900 | 0.66 |
Bomb used in Oklahoma City (ANFO based on racing fuel) | 0.0018 | 2,300 | 0.78 |
BLU-82 (Daisy Cutter) | 0.0075 | 6,800 | 1.10 |
MOAB (non-nuclear bomb, GBU-43) | 0.011 | 9,800 | 1.13 |
FOAB (advanced thermobaric bomb, ATBIP) | 0.044 | 9,100 | 4.83 |
W54, Mk-54 (Davy Crockett) | 0.022 | 23 | 1,000 |
Little Boy (dropped on Hiroshima) A-bomb | 15 | 4,400 | 4,000 |
Fat Man (dropped on Nagasaki) A-bomb | 20 | 4,600 | 4,500 |
W54, B54 (SADM) | 1.0 | 23 | 43,500 |
Classic (one-stage) fission A-bomb | 22 | 420 | 50,000 |
Hypothetical suitcase nuke | 2.5 | 31 | 80,000 |
Typical (two-stage) nuclear bomb | 500–1000 | 650–1,120 | 900,000 |
W88 modern thermonuclear warhead (MIRV) | 470 | 355 | 1,300,000 |
Tsar nuclear bomb (three-stage) | 50,000–56,000 | 26,500 | 2,100,000 |
B53 nuclear bomb (two-stage) | 9,000 | 4,050 | 2,200,000 |
Operation Dominic Housatonic[82][83][84] (two-stage) | 9,960 | 3,239 | 3,042,400 |
W56 thermonuclear warhead | 1,200 | 272–308 | 4,960,000 |
B41 nuclear bomb (three-stage) | 25,000 | 4,850 | 5,100,000 |
Theoretical antimatter weapon | 43,000 | 1 | 43,000,000,000 |
See also
edit- Brisance
- Net explosive quantity
- Nuclear weapon yield
- Orders of magnitude (energy)
- Table of explosive detonation velocities
- Tonne of oil equivalent, a unit of energy almost exactly 10 tonnes of TNT
References
editFootnotes
edit- ^ Mass–energy equivalence.
- ^ The solar constant of the sun is 1370 watts per square meter and Earth has a cross-sectional surface area of 2.6×1014 square meters.
- ^ a b The solar constant of the sun is 1370 watts per square meter and Earth has a cross-sectional surface area of 2.6×1014 square meters.
- ^ 1 hour is equivalent to 3600 seconds.
- ^ 1 day is equivalent to 86400 seconds.
- ^ a b c d e f g TBX (thermobaric explosives) or EBX (enhanced blast explosives), in a small, confined space, may have over twice the power of destruction. The total power of aluminized mixtures strictly depends on the condition of explosions.
- ^ a b Predicted values
Citations
edit- ^ "Tons (Explosives) to Gigajoules Conversion Calculator". unitconversion.org. Archived from the original on March 17, 2017. Retrieved January 6, 2016.
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- ^ Sorin Bastea, Laurence E. Fried, Kurt R. Glaesemann, W. Michael Howard, P. Clark Souers, Peter A. Vitello, Cheetah 5.0 User's Manual, Lawrence Livermore National Laboratory, 2007.
- ^ Maienschein, Jon L. (2002). Estimating equivalency of explosives through a thermochemical approach (PDF) (Technical report). Lawrence Livermore National Laboratory. UCRL-JC-147683. Archived from the original (PDF) on December 21, 2016. Retrieved December 12, 2012.
- ^ Maienschein, Jon L. (2002). Tnt equivalency of different explosives – estimation for calculating load limits in heaf firing tanks (Technical report). Lawrence Livermore National Laboratory. EMPE-02-22.
- ^ Cunningham, Bruce J. (2001). C-4/tnt equivalency (Technical report). Lawrence Livermore National Laboratory. EMPE-01-81.
- ^ Cooper, Paul W. (1996). Explosives Engineering. New York: Wiley-VCH. p. 406. ISBN 978-0-471-18636-6.
- ^ a b Charles E. Needham (October 3, 2017). Blast Waves. Springer. p. 91. ISBN 978-3319653822. OCLC 1005353847. Archived from the original on December 26, 2018. Retrieved January 25, 2019.
- ^ "Blast effects of external explosions (Section 4.8. Limitations of the TNT equivalent method)". Archived from the original on August 10, 2016.
- ^ "Appendix B8 – Factors for Units Listed Alphabetically". July 2, 2009. Archived from the original on January 29, 2016. Retrieved March 29, 2007. In NIST SI Guide 2008
- ^ "Tons Of Tnt to Calories | Kyle's Converter". www.kylesconverter.com. Retrieved March 22, 2022.
- ^ "Convert tons of TNT to joules | energy conversion". convert-to.com. Retrieved March 22, 2022.
- ^ "Convert tons of TNT to BTU - British Thermal Unit | energy conversion". convert-to.com. Retrieved March 22, 2022.
- ^ "Convert tons of TNT to foot pounds | energy conversion". convert-to.com. Retrieved March 22, 2022.
- ^ "Tons Of Tnt to Kilowatt-hours | Kyle's Converter". www.kylesconverter.com. Retrieved March 22, 2022.
- ^ Timcheck, Jonathan (Fall 2017). "The Energy in Wildfires: The Western United States". large.stanford.edu. Archived from the original on January 17, 2018. Retrieved March 31, 2022.
- ^ "Botroseya church bombing death toll rises to 29 victims". Egypt Independent. February 4, 2017. Archived from the original on May 24, 2024. Retrieved June 8, 2024.
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External links
edit- Thompson, A.; Taylor, B.N. (July 2008). "Guide for the Use of the International System of Units (SI)". NIST. NIST Special Publication. 811. National Institute of Standards and Technology. Version 3.2.
- Nuclear Weapons FAQ Part 1.3
- Rhodes, Richard (2012). The Making of the Atomic Bomb (25th Anniversary ed.). Simon & Schuster. ISBN 978-1-4516-7761-4.
- Cooper, Paul W. (1996), Explosives Engineering, New York: Wiley-VCH, ISBN 978-0-471-18636-6
- HQ Department of the Army (2004) [1967], Field Manual 5-25: Explosives and Demolitions, Washington, D.C.: Pentagon Publishing, pp. 83–84, ISBN 978-0-9759009-5-6
- Urbański, Tadeusz (1985) [1984], Chemistry and Technology of Explosives, Volumes I–IV (second ed.), Oxford: Pergamon
- Mathieu, Jörg; Stucki, Hans (2004), "Military High Explosives", CHIMIA International Journal for Chemistry, 58 (6): 383–389, doi:10.2533/000942904777677669, ISSN 0009-4293
- "3. Thermobaric Explosives". Advanced Energetic Materials. The National Academies Press, nap.edu. 2004. doi:10.17226/10918. ISBN 978-0-309-09160-2.