Destructive Capacity is the term used to determine the amount of damage a character can produce. It is normally the deciding factor of VS matches along with Speed. It is measured in units of energy.
An alternative term for Destructive Capacity which has more direct meaning: The Destructive Capacity that an attack is equivalent to. A character with a certain degree of attack potency does not necessarily need to cause destructive feats on that level, but can cause damage to characters that can withstand such forces.
We are aware that this technically violates the principle of conservation of energy, as it should logically disperse upon impact, but fiction generally tends to ignore this fact, so we overlook it as well.
Also, kindly remember that Attack Potency is the measure of Destructive Capacity of an attack, and as such, is measured via its energy damage equivalent. Hence, characters that destroy mountains or islands are not automatically mountain or island level, especially if they are small. The attack potency depends upon the energy output of the attack, not the area of effect of the attack.
Attack Potency Chart
|Energy in Tonnes
of TNT Equivalent
|Energy in Joules||High End to Low End ratio|
|10-C||Below Average||~0 Joules to
|~0 to 9.56x10-9||~0 to 4x101||NA|
|10-B||Human||40 Joules to
|9.56x10-9 to 2.39x10-8||4x101 to 102||2.5x|
|10-A||Athlete||100 Joules to
|2.39x10-8 to 7.17x10-8||102 to 3x102||3x|
|9-C||Street||300 Joules to
|7.17x10-8 to 3.59x10-6||3x102 to 1.5x104||50x|
to 0.005 Tons
|3.59x10-6 to 5x10-3||1.5x104 to 2.092x107||~1394.67x|
|9-A||Small Building||0.005 Tons
to 0.25 Tons
|5x10-3 to 2.5x10-1||2.092x107 to 1.046x109||50x|
to 2 Tons
|2.5x10-1 to 2||to 1.046x109 to 8.368x109||8x|
|High 8-C||Large Building||2 Tons to
|2 to 1.1x101||8.368x109 to 4.6024x1010||5.5x|
|8-B||City Block||11 Tons to 100 Tons||1.1x101 to 102||4.6024x1010 to 4.184x1011||~9.1x|
|8-A||Multi-City Block||100 Tons to 1 Kiloton||102 to 103||4.184x1011 to 4.184x1012||10x|
|Low 7-C||Small Town||1 Kiloton to
|103 to 5.8x103||4.184x1012 to 2.42672x1013||5.8x|
|7-C||Town||5.8 Kilotons to
|5.8x103 to 105||2.42672x1013 to 4.184x1014||~17.5x|
|High 7-C||Large Town||100 Kilotons
to 1 Megaton
|105 to 106||4.184x1014 to 4.184x1015||10x|
|Low 7-B||Small City||1 Megaton to
|106 to 6.3x106||4.184x1015 to 2.63592x1016||6.3x|
to 100 Megatons
|6.3x10^6 to 108||2.63592x1016 to 4.184x1017||~16x|
to 1 Gigaton
|108 to 109||4.184x1017 to 4.184x1018||10x|
|High 7-A||Large Mountain||1 Gigaton to
|109 to 4.3x109||4.184x1018 to 1.79912x1019||4.3x|
to 100 Gigatons
|4.3x109 to 1011||1.79912x1019 to 4.184x1020||~23.25x|
|High 6-C||Large Island||100 Gigatons
to 1 Teraton
|1011 to 1012||4.184x1020 to 4.184x1021||10x|
|Low 6-B||Small Country||1 Teraton to
|1012 to 7x1012||4.184x1021 to 2.9288x1022||7x|
to 100 Teratons
|7x1012 to 1014||2.9288x1022 to 4.184x1023||14x|
|High 6-B||Large Country||100 Teratons
to 760 Teratons
|1014 to 7.6x1014||4.184x1023 to 3.17984x1024||7.6x|
to 4.435 Petatons
|7.6x1014 to 4.435x1015||3.17984x1024 to 1.855604x1025||~5.8x|
|High 6-A||Multi-Continent||4.435 Petatons to
|4.435x1015 to 2.96x1019||1.855604x1025 to 1.24x1029||~6674x|
|5-C||Moon||29.6 Exatons to
|2.96x1019 to 4.33x1020||1.24x1029 to 1.81x1030||14.62x|
|Low 5-B||Small Planet||433 Exatons
to 59.44 Zettatons
|4.33x1020 to 5.944x1022||1.81x1030 to 2.487x1032||~137x|
to 2.7 Yottatons
|5.944x1022 to 2.7x1024||2.487x1032 to 1.13x1034||~45.5x|
|5-A||Large Planet||2.7 Yottatons
to 16.512 Ninatons
|2.7x1024 to 1.651x1028||1.13x1034 to 6.906x1037||~6111.5x|
|High 5-A||Dwarf Star||16.512 Ninatons
to 7.505 Tenatons
|1.651x1028 to 7.505x1030||6.906x1037 to 3.139x1040||~454.53x|
|Low 4-C||Small Star||7.505 Tenatons
to 136.066 Tenatons
|7.505x1030 to 1.36x1032||3.139x1040 to 5.693x1041||~18.14x|
to 912.295 Tenatons
|1.36x1032 to 9.12x1032||5.693x1041 to 3.817x1042||~6.71x|
|High 4-C||Large Star||912.295 Tenatons
to 22.77 Foe
|9.12x1032 to 5.442x1035||3.817x1042 to 2.277x1045||~596.54x|
|4-B||Solar System||22.77 Foe
to 20.08 TeraFoe
|5.442x1035 to 4.799x1047||2.277x1045 to 2.008x1057||~881.86 billion x|
|4-A||Multi-Solar System||20.08 TeraFoe
to 10.53 ZettaFoe
|4.799x1047 to 2.517x1056||2.008x1057 to 1.053x1066||~198.37 million x|
to 8.593 YottaFoe
|2.517x1056 to 2.054x1059||1.053x1066 to 8.593x1068||~816.05x|
to 2.825 TenaexaFoe
|2.054x1059 to 6.752x1082||8.593x1068 to 2.825x1092||~1.04x1023x|
|3-A||Universe||2.825 TenaexaFoe to any higher finite number||6.752x1082 to any higher finite number||2.825x1092 to any higher finite number||Not available|
- Moon level: Earth's satellite Moon.
- Small Planet level: Mercury.
- Planet level: The Earth.
- Dwarf Star level: Brown Dwarf star (specifically, the OTS 44).
- Small Star level: VB 10.
- Star level: The Sun.
- Large Star level: Rigel
The values for High 5-A and above are obtained from here. The calculation assumes that the blast is omni-directional (spherical), as is generally the case in most fictional occurrences, and that the energy output is sufficient to destroy the entirety of the cosmic structure.
- Solar System level: The star system known as the Solar System.
- Multi-Solar System level: Instead of doubling the value of Solar System level, the distance between two such systems needs to be accounted for as well. The calculation for energy required to destroy two solar systems was done, with the following assumptions:
- Distance between them as the minimum distance between Sun and the next closest star, the Alpha Centauri.
- A spherical blast, strong enough to obliterate the contents of both solar systems at the same time.
- Hence, the value obtained is the energy required to destroy two solar systems at a realistic distance.
- Galaxy level: The Milky Way galaxy.
- Galaxies in fiction tend to be destroyed completely, not dissociated. Hence, it is far more logical to index a common occurrence of compete obliteration instead of an obscure one like dissociation.
- We have a different interpretation regarding black holes. Simply put, we disagree with the premise of utilization of black holes for energy outputs, primarily because black holes rarely follow any scientific logic whatsoever. To know more, continue to read here.
- Multi-Galaxy level: Instead of doubling the value of Galaxy level, the distance between two galaxies needs to be accounted for as well. The calculation for energy required to destroy two galaxies was done with the assumptions:
- Distance between them as the minimum distance between Milky Way Galaxy and the next closest similar-sized galaxy, the Andromeda galaxy.
- A spherical blast, strong enough to obliterate the contents of both galaxies at the same time.
- Hence, the value obtained is the energy required to destroy two galaxies at a realistic distance.
- Universe level: Given that the universe's actual size is unknown, we do not know the amount of energy that would be required to destroy all matter within it. As such, the bare minimum value for the observable universe was calculated as a lower border instead (The PSRJ0348+0432 was used as a base). Any greater finite number is also included within this tier, whereas countably infinite numbers are included under High Universe level.
- Small Moon level: While most other tiers have been into 3 sub-tiers, Moon level does not have Small Moon level due to the existence of Multi-Continent level. Simply put, the two intersect, and Multi-Continent level is far more common than Small Moon.
- Small Galaxy level: Same reason as the one for Small Moon level, with the tier clashing with Multi-Solar System level instead.
- Large Galaxy level: Large Galaxy level was omitted because unlike planets, galaxies in fiction rarely specify the size of said galaxy, and instead go from galaxy to multiple galaxies. As such, a "Large Galaxy level" rating would not only be confusing, but also redundant.
- Higher Dimensional levels: These levels are not listed because they are not restricted to the same parameters for energy requirement. The energy for such levels cannot be calculated.
Currently misused to an extraordinary degree on the wiki, the "+" symbol should only be used when the Attack Potency has been calculated to be greater than the average (arithmetic mean) of the high end energy level and low end energy level of a particular tier.
Example: Average of Large Building level is: [2 Tons (low end) + 11 tons (high end)]/2 = 6.5 Tons (the arithmetic mean). All energy levels from 2 Tons to 6.5 Tons should be listed as Large Building level, whereas all energy levels from 6.5 Tons to 11 Tons should be listed as Large Building level+.
Currently used to denote high end of a particular tier, it will here-on no longer be utilized in that manner. "High" will be utilized only if the instance matches with the revised Attack Potency chart.
Example: If a character is in the upper range of a tier such as Solar System level, said character will be listed as "Solar System level+", not "High Solar System level".
Currently used to denote low end of a particular tier, it will here-on no longer be utilized in that manner. "Low" will be utilized only if the instance matches with the revised Attack Potency chart.
Example: There should be no usage of "Low 7-A", because it does not correspond with the revised Attack Potency chart.
Should be used to denote the lower cap of a character, if the exact value is indeterminate.
Should be used to denote the higher cap of a character, if the exact value is indeterminate.
Should be used to list a hypothetical statistic for a character, but inconclusive due to lack of feats or viable power-scaling. Probability of said hypothetical statistic should be favourable.
Should be used to list a hypothetical statistic for a character, but inconclusive due to lack of feats or viable power-scaling. Probability of said hypothetical statistic should also be indeterminate.
- To know the equivalent prefix for a particular exponential value, please see this page.
- The required sizes for shattered mountains, or islands, to be considered as "Mountain level", or "Island level".
- An easy to use reference list for estimating the tiers of different explosion sizes.
- The energy required to break down doors.
- The energy required to vaporise an average human being.
- The energy required to freeze another human-sized character.
- The energy required to shake the Earth.
- The energy required to destroy the surface of the Earth.
- The Earth's rotational energy.
- A Foe is a unit used to measure the energy released by a supernova, and is equivalent to 1044 Joules.
- The reasons for our Athlete, Street, and Wall level borders.
- The reasons for our Large Planet level to Universe level borders.