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  1. Vin with the power of Preservation spins the planet around in an incredibly short timeframe, and the Sun is noted to drop below the horizon in less than a second. Using this formula for help.

    Using the values of the Earth for this. The circumference of the Earth is 40075km, and half of that is 20037.5km, or 50% of the circumference of the planet. This calculator gives us a result of 3.1415926535898 radians from that percentage. The mass of the Earth is 5.97219e24kg and its surface area is 5.1 X 10^8 km^2 (or 5.1e14m^2).

    E = 1/2Iw^2
    = 1/2 (5.97219e24 X 5.1e14) X 3.1415926535898^2
    = 1.50305039e40 joules
    = 3.5923766491395793855 tenatons

    That's energy. What about speed? Timeframe is less than a second, but we'll go with a second.

    T = 20037.5km/1s
    = 20037500/340.29
    = Mach 58883.5993

    Final Results
    Vin rotates the planet (energy) = 3.592 tenatons
    Vin rotates the planet (speed) = Mach 58883.599
  2. There's a few good feats from Symphogear G. To start with...

    The Symphogears channel the songs of the people of the world, punch Nephilim in the face and create a huge cyclone of energy into space in the span of a second. The diameter of the Earth is 12,756.2km.

    = 2*atan(336/(1434/tan(70/2)))
    = 0.221133154 rad
    = 12.6699964346479081 degrees

    Enter that through the angscaler and we have a distance of 57450km.
    Spoiler:


    Timeframe is 1 second.

    T = 57450km/1s
    = 57450000/299792458 X 100
    = 19.1632573% C

    Pretty good all in all. Next up...

    The Frontier's hand reaches up and grabs the Moon. The Moon is 384,400km away from the Earth.
    Spoiler:


    Timeframe is 5 seconds.

    T = 384,400km/5s
    = 76880000/299792458 X 100
    = 25.6444076% C

    Finall for the dustclouds created when the giant hand hits the Moon. Diameter of the Moon is 3474.8km.
    Spoiler:


    Timeframe is 2 seconds.

    1031 pixels = 3474.8km
    1 pixel = 3474.8km/1031 = 3.37032008km (3370.32008m)
    3370.32008m X 105 = 353.883608km (353883.608m)
    353883.608m/2 = 176941.804m
    3370.32008m X 240 = 808876.819m
    3370.32008m X 246 = 829098.74m
    3370.32008m X 121 = 407808.73m
    407808.73m/2 = 203904.365m
    3370.32008m X 262 = 883023.861m
    3370.32008m X 113 = 380846.169m
    380846.169m/2 = 190423.084m
    3370.32008m X 350 = 1179612.03m
    3370.32008m X 129 = 434771.29m
    434771.29m/2 = 217385.645m
    3370.32008m X 337 = 1135797.87m
    3370.32008m X 88 = 296588.167m
    296588.167m/2 = 148294.084m
    3370.32008m X 399 = 1344757.71m
    1344757.71m/2 = 672378.855m
    3370.32008m X 240 = 808876.819m
    808876.819m/2 = 404438.41m
    3370.32008m X 204 = 687545.296m
    687545.296m/2 = 343772.648m
    343772.648m/2 = 171886.324m
    3370.32008m X 97 = 326921.048m
    326921.048m/2 = 163460.524m
    3370.32008m X 297 = 1000985.06m
    1000985.06m/2 = 500492.53m
    3370.32008m X 381 = 642045.975m
    642045.975m/2 = 321022.987m

    Volumes of the 3 on the left as ellipsoids and the other 5 as cones.

    V = πr^2h/3
    = π X 176941.804^2 X 808876.819/3
    = 2.65199016e16m^3

    V = πr^2h/3
    = π X 829098.74^2 X 203904.365/3
    = 1.46780259e17m^3

    V = πr^2h/3
    = π X 883023.861^2 X 190423.084/3
    = 1.55486644e17m^3

    V = πr^2h/3
    = π X 1179612.03^2 X 217385.645/3
    = 3.16765493e17m^3

    V = πr^2h/3
    = π X 1135797.87^2 X 148294.084/3
    = 2.00333945e17m^3

    V = 4/3πabc
    = 4/3 X π X 672378.855 X 404438.41 X 404438.41
    = 4.60688579e17m^3

    V = 4/3πabc
    = 4/3 X π X 171886.324 X 163460.524 X 163460.524
    = 1.92378133e16m^3

    V = 4/3πabc
    = 4/3 X π X 500492.53 X 321022.987 X 321022.987
    = 2.1605209e17m^3

    V = 2.65199016e16m^3 + 1.46780259e17m^3 + 1.55486644e17m^3 + 3.16765493e17m^3 + 2.00333945e17m^3 + 4.60688579e17m^3 + 1.92378133e16m^3 + 2.1605209e17m^3
    = 1.54186473e18m^3

    Weight of a dustcloud is 1.003kg/m^3.

    M = 1.54186473e18 X 1.003
    = 1.54649032e18kg

    T = 642045.975m/2s
    = 321022.987m/s

    At last, for our kinetic energy.

    KE = (0.5)mv^2
    = (0.5) X 1.54649032e18 X 321022.987^2
    = 7.96873662e28 joules

    That's not all though; the Moon visibly rocks when the hand grabs it, considerably in the space of just a frame. First off, we need the radius of the Moon (that being 1737.4km) from it's curvature.


    R = (h/2) + c^2/(8h)
    = (253/2) + 2250^2/(8 X 253)
    = 2627.73518

    2627.73518 pixels = 1737.4km
    1 pixel = 1737.4km/2627.73518 = 0.661177737km
    Spoiler:


    0.661177737km X 374 = 247.280474km
    0.661177737km X 396 = 261.826384km
    261.826384km - 247.280474km = 14.54591km

    T = 1s/25
    = 14.54591km/40ms
    = 363647.75m/s

    Weight of the Moon is 7.35e22kg.

    KE = (0.5)mv^2
    = (0.5) X 7.35e22 X 363647.75^2
    = 4.85980846e33 + 7.96873662e28
    = 4.85988815e33 joules
    = 1.1615411448374759473 yottatons

    Final Results
    Symphogear's cyclone = 19.1632573% C
    Frontier hand reaches to the Moon = 25.6444076% C
    Frontier hand whacks the Moon = 1.162 yottatons
  3. Calc request for @GiveRobert20dollars and @Cipher97 .


    The Warrior of Light blasts a Sin Eater hard enough to part infront and behind him. Average height of a man is 176.1cm, or 1.761m. That would mean at least 4.7km to the horizon, or 4700m. How wide is the gap though?
    Spoiler:


    = 2*atan(234/(673/tan(70/2)))
    = 0.326554592 rad
    = 18.7101999022629677 degrees
    Using the angscaler, the gap in the clouds is 1548.6m across.

    234 pixels = 1548.6m
    1 pixel = 1548.6m/234 = 6.61794872m
    6.61794872m X 90 = 595.615385m

    Volume as a rectangle.

    V = 4700 X 595.615385 X 1548.6
    = 4.33513893e9m^3

    Density of a cloud is 1.003kg/m^3.

    M = 4.33513893e9 X 1.003
    = 4.34814435e9kg

    Next we need the timeframe.
    Spoiler:


    1.02 seconds.

    T = 4700m/1.02s
    = 4607.84314/340.29
    = Mach 13.5409302

    Finally for the KE.

    KE = (0.5)mv^2
    = (0.5) X 4.34814435e9 X 4607.84314^2
    = 4.61603752e16 joules

    Given it goes both ways, let's times that by two.

    E = 4.61603752e16 X 2
    = 9.23207504e16 joules
    = 22.065188910133844757 megatons

    Final Results
    Warrior of Light parts clouds (speed) = Mach 13.541
    Warrior of Light parts clouds (energy) = 22.0652 megatons
  4. Calc request from @John Wayne.

    Kiss Shot destroys Antartica just by jumping. First off, what are the dimensions of Antartica's rocky and icy parts. The ice shelf covering Antartica is 14000000km^2, or 1.4e+13m^2. The ice shelf is on average 1.9km thick, or 1900m.

    V = Ah
    = 1.4e+13 X 1900
    = 2.66e16m^3

    The fragmentation looks pretty violent. Violent fragmentation of ice is 0.825 joules per cm^3, or 825000 joules per m^3.

    E = 2.66e16 X 825000
    = 2.1945e22 joules

    Save that for the end. What about the rocky bit? The average elevation in Antartica is 2500m above sea level.

    H = 2500m - 1900m
    = 600m

    V = 1.4e+13 X 600
    = 8.4e15m^3

    Violent fragmentation of rock is 69000000 joules per m^3.

    E = 8.4e15 X 69000000
    = 5.79600e23 joules

    Finally, to add them both together.

    E = 2.1945e22 + 5.79600e23
    = 6.01545e23 joules
    = 143.77270554493307486 teratons

    Let's also get the speed. It takes 12 seconds in that shot to get from Antartica to Japan. Distance from Antartica to Japan is 13,930km.

    T = 13,930km/12s
    = 1160833.33/340.29
    = Mach 3411.30603

    Final Results
    Kiss Shot destroys Antartica = >143.773 teratons
    Kiss Shot jumps from Antartica to Japan = Mach 3411.306
  5. (Episode 11)

    Fine uses Kadingir to destroy the Moon, Chris blocks most of it but a large chunk of the Moon is still taken out. Diameter of the Moon is 3474.8km, or 3474800m.

    443 pixels = 3474800m
    1 pixel = 3474800m/443 = 7843.79233m
    7843.79233m X 144 = 1129506.1m
    1129506.1m/2 = 564753.05m
    7843.79233m X 230 = 1804072.24m
    1804072.24m/2 = 902036.12m

    I...can't be bothered scaling all the swiggily part in detail, so I'm just going with the volume of an ellipsoid for now.

    V = 4/3πabc
    = 4/3 X π X 564753.05 X 564753.05 X 902036.12
    = 1.20511837e18m^3

    The mean density of the Moon is 3344kg/m^3.

    M = 1.20511837e18 X 3344
    = 4.02991583e21kg

    Next up for the timeframe and the distance moved.
    Spoiler:



    Timeframe is 3 seconds.

    1021 pixels = 1129506.1m
    1 pixel = 1129506.1m/1021 = 1106.27434m
    1106.27434m X 936 = 1035472.78m

    T = 1035472.78m/3s
    = 345157.593m/s

    Now for our energy.

    KE = (0.5)mv^2
    = (0.5) X 4.02991583e21 X 345157.593^2
    = 2.40049521e32 joules
    = 57.373212476099425317 zettatons

    A dying Fine later drags this chunk down to Earth, so let's get that too.

    Unfortunately, I can't find anything to scale from in that initial shot, but we get later shots of the distance travelled so we'll go with that.
    Spoiler:



    The timeframe for the Nehushtan Armor reaching the moon is 3 seconds, and the timeframe for the Moon chunk falling is 142 seconds. Distance to the Moon is 384,400km away.

    T = 384,400km/3s
    = 128133333/299792458 X 100
    = 42.7406793% C
    = 2*atan(275/(1610/tan(70/2))
    = 0.161510163 rad
    = 9.25385068839294256 degrees

    Enter that through the angscaler and we get a distance of 11146000m from the Earth to the Moon chunk, or 11,146km.

    T = 11,146km/142s
    = 78492.9577/s

    KE = (0.5)mv^2
    = (0.5) X 4.02991583e21 X 78492.9577^2
    = 1.24144467e31 joules
    = 2.9671239722753344203 zettatons

    Finally, for the Nehushtan Armor's return to Earth.
    Spoiler:


    ...Also three seconds, which means it will be the same.

    Final Results
    Kadingir's remaining power hits the Moon = 57.373 zettatons
    Nehushtan Armor reaches/returns from the Moon = 42.741% C
    Fine drags down Moon chunk = 2.967 zettatons

  6. 0:00

    Vanya's power rips apart the moon, draggin huge meteors to Earth, killing everyone. The diameter of the Moon is 3474.8km, or 3474800m.

    379 pixels = 3474800m
    1 pixel = 3474800m/379 = 9168.33773m
    9168.33773m X 73 = 669288.654m
    669288.654m/2 = 334644.327m
    9168.33773m X 60 = 550100.264m
    550100.264m/2 = 275050.132m

    520 pixels = 550100.264m (550.100264km)
    1 pixel = 550100.264m/520 = 1057.88512m
    1057.88512m X 347 = 367086.137m
    1057.88512m X 288 = 304670.915m
    304670.915m/2 = 152335.457m
    1057.88512m X 111 = 117425.248m
    117425.248m/2 = 58712.624m
    1057.88512m X 282 = 298323.604m
    298323.604m/2 = 149161.802m

    Calculating the main volume as a conical frustrum, calculating the outsticking bit as an ellipsoid.

    V = (1/3)π(r^2+rR+R^2)h
    = (1/3) X π X (152335.457^2 + 152335.457 X 275050.132 + 275050.132^2) X 367086.137
    = 5.41092356e16m^3

    V = 4/3πabc
    = 4/3 X π X 58712.624 X 58712.624 X 149161.802
    = 2.15381904e15m^3

    V = 5.41092356e16 + 2.15381904e15
    = 5.62630546e16m^3

    The mean density of the Moon is 3344kg/m^3.

    M = 5.62630546e16 X 3344
    = 1.88143655e20kg

    Now for the speed at which the meteor was thrown.
    Spoiler:


    Timeframe is 2.06 seconds. Keep in mind too there's a margin of the above video, which is feint but visible.

    = 2*atan(245/(598/tan(70/2)))
    = 0.383473476 rad
    = 21.9714117300657676 degrees

    Enter those values through the angscaler and the distance to the Moon is 8950.1km.

    = 2*atan(208/(598/tan(70/2)))
    = 0.326673796 rad
    = 18.7170297883640657 degrees

    That's a distance of 1668.9km. Now we can find the distance the chunk of Moon travelled in that timeframe.

    D = 8950.1km - 1668.9km
    = 7281.2km

    T = 7281.2km/2.06s
    = 3534563.11/340.29
    = Mach 10386.9144

    Last but not least, our energy.

    KE = (0.5)mv^2
    = (0.5) X 1.88143655e20 X 3534563.11^2
    = 1.17525217e33 joules
    = 280.89201003824092595 zettatons

    Final Results
    Meteor breaks away from the Moon (speed) = Mach 10386.914
    Meteor breaks away from the Moon (energy) = 280.892 zettatons


  7. https://en.uesp.net/wiki/Online:Bolt_Escape
    Bolt Escape involves turning to energy to flash forward and stun enemies. Pretty sure this is a spamable attack too.The average weight of a human adult is 62kg.

    E = mc^2
    = 62 X 299792458^2
    = 5.57228211e18 joules
    = 1.331807387667303999 gigatons

    Final Results

    Bolt Escape = 1.332 gigatons
  8. From My Hero Academia: Two Heroes, about 1 hour, 17 minutes in.

    All Might leaps up the tower on I-Island, ripping the walls of said tower as he goes. Keep in mind, this is a really tall tower. Not sure if Wolfram and his terrorists are Japanese or not, but most characters in MHA are, and he did visit All For One, so we'll be using average height of a Japanese man is 171.2cm, or 1.761m

    26 pixels = 1.761m
    1 pixel = 1.761m/26 = 0.0677307692m
    0.0677307692m X 1433 = 97.0581923m

    We don't get quite a full shot of the helipad, but we do in other shots.

    337 pixels = 97.0581923m
    1 pixel = 97.0581923m/337 = 0.288006505m
    0.288006505m X 672 = 193.540371m
    0.288006505m X 1045 = 300.966798m

    78 pixels = 300.966798m
    1 pixel = 300.966798m/78 = 3.85854869m
    3.85854869m X 771 = 2974.94104m

    All Might in his big form is 220cm (2.20m) tall.

    577 pixels = 2.20m
    1 pixel = 2.20m/577 = 0.00381282496m
    0.00381282496m X 61 = 0.232582323m

    50 pixels = 0.232582323m
    1 pixel = 0.232582323m/50 = 0.00465164646m
    0.00465164646m X 1350 = 6.27972272m

    0.00465164646m X 9 = 0.0418648181m

    Volume as a rectangular prism (it's an arc, so it'd likely be even higher, but for now that will serve).

    V = lhw
    = 6.27972272 X 2974.94104 X 0.0418648181
    = 782.110361m^3

    Violent fragmentation of steel is 568500000 joules/m^3.

    E = 782.110361 X 568500000
    = 4.4462974e11 joules
    = 106.2690583174 tons of TNT

    Final Results
    All Might jumps I-Island tower = 106.269 tons of TNT
  9. Jiro's one of my favourite MHA characters, and she has some impressive feats.

    1. Tuning
    First up, scaling. We'll need the dimensions of her head vertically and horizontally. Jiro is 154 cm (1.54m) tall.

    548 pixels = 1.54m
    1 pixel = 1.54m/548 = 0.00281021898m
    0.00281021898m X 83 = 0.233248175m
    0.00281021898m X 89 = 0.250109489m

    2. Jiro rocks

    Jiro shatters a boulder with her earjacks. This should be fairly straight forward...

    73 pixels = 0.250109489m
    1 pixel = 0.250109489m/73 = 0.00342615738m
    0.00342615738m X 126 = 0.43169583m
    0.00342615738m X 254 = 0.870243975m

    Volume as half an ellipsoid.

    V = 4/3πabc
    = 4/3 X π X 0.43169583 X 0.43169583 X 0.870243975
    = 0.67933711359/2
    = 0.339668557m^3

    It';s clearly blown apart pretty violently. Violent fragmentation of rock is 69000000 joules/m^3.

    E = 0.339668557 X 69000000
    = 23437130.4 joules
    = 0.005601608604207 tons of TNT

    Not bad...but she can do way better.

    3. Jiro really rocks

    Jiro's Heartbeat Fuzz shatters the ground considerably. First the distance from Jiro to the other students...

    27 pixels = 0.233248175m
    1 pixel = 0.233248175m/27 = 0.0086388213m
    0.0086388213m X 801 = 6.91969586m

    Enter that through the angscaler, and we have us a distance of 5.24808394m. That's not the total distance though; we also have the distance of the other students attacking Class 1-A. Given the 16 from this point on, we'll be going with the average height of Japanese 16 year olds, the boy for the depth, the girl for the distance. The average height of a 16 year old Japanese boy is 169.4cm (1.694m) and the 16 year old Japanese girl is 157.5cm (1.575m). Scaling the boy's head and torso differently because he's hunched over.

    55 + 11 + 16 = 82
    82 pixels = 1.575m
    1 pixel = 1.575m/82 = 0.0192073171m
    0.0192073171m X 18 = 0.345731708m
    0.0192073171m X 968 = 18.592683m
    100 + 41 = 141
    141 pixels = 1.694m
    1 pixel = 1.694m/141 = 0.0120141844m
    0.0120141844m X 36 = 0.432510638m
    0.0120141844m X 83 = 0.997177305m

    First to scale from the boys head, then to the girls.
    = 2*atan(36/(359/tan(70/2)))
    = 0.0949554958 rad
    = 5.440549150925710009 degrees

    Enter that through the angscaler and have us a distance of 4.6504m
    = 2*atan(18/(359/tan(70/2)))
    = 0.0475045183 rad
    = 2.721808406398736224 degrees

    That's a distance of 7.2765m. Now, adding together to get the distance to Jiro...

    L = 6.91969586m + 4.6504m + 7.2765m
    = 18.8465959m

    Volume as a rectangular prism.

    V = 18.8465959 X 18.592683 X 0.997177305
    = 349.419686m^3

    Once again, given fragments are thrown everywhere and dust is heaved up, it's clearly violent fragmentation.

    E = 349.419686 X 69000000
    = 24109958334 joules
    = 5.7624183398662 tons of TNT

    Final Results
    Jiro shatters boulder = 0.006 tons of TNT
    Heart Fuzz = 5.762 tons of TNT
  10. First of all, this feat is canon.

    Now onto the feat.

    0:34
    Spoiler:


    Izuku and Allmight halt and destroy a massive block of metal that Wolfram throws at them. That's the best quality version, but unfortunately bits of it are cropped out, so we'll look at some other videos to get the full image. The average height of a Japanese man is 171.2cm, or 1.761m (I don't even recall if Wolfram is Japanese or not, but it's good to go with for now).

    946 pixels = 1.761m
    1 pixel = 1.761m/946 = 0.0018615222m
    0.0018615222m X 140 = 0.260613108m

    5 pixels = 0.260613108m
    1 pixel = 0.260613108m/5 = 0.0521226216m
    0.0521226216m X 194 = 10.1117886m

    68 pixels = 10.1117886m
    1 pixel = 10.1117886m/68 = 0.148702774m
    0.148702774m X 2214 = 329.227942m

    That's a ridiculously big cube. A big cube it is though, so obviously volume's as a cube.

    V = lhw
    = 329.227942 X 329.227942 X 329.227942
    = 35685358.3m^3

    For it's mass I was suggested to use iron. Cast iron weighs 7300kg/m^3.

    M = 35685358.3 X 7300
    = 260503115590kg

    Now for the timeframe.
    Spoiler:



    Timeframe is 0.54 seconds.

    362 pixels = 329.227942m
    1 pixel = 329.227942m/362 = 0.909469453m
    0.909469453m X 633 = 575.694164m

    T = 575.694164m/0.54s
    = 1066.1003/340.29
    = Mach 3.13291692

    Let's get our mighty energy!

    KE = (0.5)mv^2
    = (0.5) X 260503115590 X 1066.1003^2
    = 1.48039993e17 joules
    = 35.382407504780111651 megatons

    It gets blown apart pretty violently. How much energy would that take? Violent fragmentation of steel is 568500000 joules/m^3.

    E = 35685358.3 X 568500000
    = 2.02871262e16 joules
    = 4.8487395315487571423 megatons

    Final Results
    Wolfram throws giant metal block (speed) = Mach 3.134
    Wolfram throws giant metal block (energy) = 35.382 megatons
    Deku & All Might destroy metal block = 4.849 megatons

  11. 0:05

    Garnet shatters a huge obsidian block. And yes, these kinds of blocks are Obsidian.

    In a previous calc, I put Garnet at being 2.14968787m tall.

    241 pixels = 2.14968787m
    1 pixel = 2.14968787m/241 = 0.00891986668m
    0.00891986668m X 517 = 4.61157107m
    0.00891986668m X 759 = 6.77017881m
    0.00891986668m X 119 = 1.06146413m
    0.00891986668m X 163 = 1.45393827m

    Volume of the main bulk as a trapezoid, volume of the top bit as half a cube. This is the formula we'll be using for the former;

    A = 1/2(a + b)h
    = 1/2 X (1.06146413 + 4.61157107) X 6.77017881
    = 19.2037313497m^2

    V = 19.2037313497 X 4.61157107
    = 88.5593719283m^3

    V = 1.06146413 X 1.45393827 X 1.45393827
    = 2.24386776039/2
    = 1.1219338802m^3

    V = 88.5593719283 + 1.1219338802
    = 89.6813058085m^3

    Obsidian's mass varies, but apparently it's typically at 2600kg/m^3 (according to that link at least).

    M = 89.6813058085 X 2600
    = 233171.395102kg
    Spoiler:


    Timeframe is 0.75 seconds.

    150 pixels = 2.14968787m
    1 pixel = 2.14968787m/150 = 0.0143312525m
    0.0143312525m X 497 = 7.12263249m

    T = 7.12263249m/0.75s
    = 9.49684332m/s

    KE = (0.5)mv^2
    = (0.5) X 233171.395102 X 9.49684332^2
    = 10514867.9147 joules

    That's not all; we'll also go with a low end of violent fragmentation and a high end of pulverization.

    (Low end)
    E = 88.5593719283 X 69000000
    = 6110596663.05 + 10514867.9147
    = 6121111530.96 joules
    = 1.462980767437859 tons of TNT

    (High end)
    E = 88.5593719283 X 200000000
    = 17711874385.7 + 10514867.9147
    = 17722389253.6 joules
    = 4.235752689674952 tons of TNT

    Final Results
    Garnet destroys Obsidian block (low end) = 1.463 tons of TNT
    Garnet destroys Obsidian block (high end) = 4.236 tons of TNT


    Ultimately a bit feat, but still nice. Also, Garnet can break Obsidian?

  12. 2:50

    Lapis rocks her gem tower noticably. Looking at the Mercalli Intensity Scale...
    Spoiler:


    The shaking looks around 4. Given this isn't seizemic though, we'll be using an impact calculator.
    Going from my previous calculation, Lapis's ocean tower is 2040100m tall. Messing around with the impact calculator until I got magnitude 4, we get a result of 1.58 x 10^30 Joules (1.58e+30 joules), or 377.62906309751432855 exotons of TNT!

    Final Results
    Lapis shakes her tower = 377.629 exotons


    Holy shit, moon level Lapis! :bookerskully Seriously though, I'm gonna need a second opinion on if this is done right or not. :thunk

  13. There's a ton of overlooked feats in the battle between Alexandrite & Malachite. We'll, not for much longer!
    Spoiler:
    1. Build a wall and make the Crystal Gems pay for it
    1:21

    Malachite creates an ice wall to block Alexandrite's attack. Scaling to the wall from Malachite from Alexandrite from Steven, who's head in a previous calc I put at 0.671863183m.

    22 pixels = 0.671863183m
    1 pixel = 0.671863183m/22 = 0.0305392356m
    0.0305392356m X 94 = 2.87068815m
    0.0305392356m X 507 = 15.4833924m
    0.0305392356m X 77 = 2.35152114m

    458 pixels = 2.87068815m
    1 pixel = 2.87068815m/458 = 0.00626787806m
    0.00626787806m X 147 = 0.921378075m
    0.00626787806m X 479 = 3.00231359m

    218 pixels = 3.00231359m
    1 pixel = 3.00231359m/218 = 0.0137720807m

    0.0137720807m X 1070 = 14.7361263m
    0.0137720807m X 615 = 8.46982963m

    195 pixels = 8.46982963m
    1 pixel = 8.46982963m/195 = 0.0434350237m
    0.0434350237m X 1107 = 48.0825712m

    Volume as a rectangle.

    V = lhw
    = 14.7361263 X 8.46982963 X 48.0825712
    = 6001.3049162m^3

    Water weighs 1000kg per m^3.

    M = 6001.3049162 X 1000
    = 6001304.9162kg (6001304916.2g)

    The events of Super Watermelon Island take place right before the Summer of Steven event, so I think it's safe to assume this happened in either Spring or Summer. Mask Island resides within the Atlantic Ocean.

    This here shows the average water temperatures off the East coast of America in Spring, se we'll find an average from that.

    T = 77 + 76 + 77 + 77 + 81
    = 388/5
    = 77.6 F

    We'll need that in C though, which is 25.33333. Specific heat of water is 4.186 joules per gram.

    E = 6001304916.2 X 4.186 X 25.33333
    = 636410296535 joules

    Before we get our final result, let's add the heat fusion of water, which is 334 kilojoules per kg.

    E = 6001304.9162 X 334
    = 2004435842.01 kilojoules
    = 2.0044358e+12 joules

    Finally, to add them both together.

    E = 636410296535 + 2.0044358e+12
    = 2.6408461e+12 joules
    = 631.1773661567878 tons of TNT

    2. Not-so-master-hand
    1:06

    Alexandrite evaporates one of Malachites water hands with her flame breath.

    51 pixels = 2.35152114m
    1 pixel = 2.35152114m/51 = 0.0461082576m
    0.0461082576m X 190 = 8.76056894m
    0.0461082576m X 219 = 10.0977084m
    8.76056894m + 10.0977084m = 18.8582773m
    0.0461082576m X 139 = 6.40904781m
    6.40904781m/2 = 3.2045239m

    Volume as a cylinder.

    V = πr^2h
    = π X 3.2045239^2 X 18.8582773m
    = 608.385591693m^3

    M = 608.385591693 X 1000
    = 608385.591693kg

    Next to calculate the energy to vaporize the water, the values of which can be found here.

    E = 608385.591693 X 2.26 X 10^6
    = 1.3749514e+12 joules
    = 328.6212715105162 tons of TNT

    Take in mind it would ultimately be even higher, because I couldn't be bothered getting the volume of the fingers. Maybe later.


    Final Results
    Malachite's ice wall = 631.177 tons of TNT
    Alexandrite evaporates water hand = >328.622 tons of TNT

    And Lapis alone and each of the Crystal Gems have better than this in anycase.

  14. 2:30

    The Duke of Strawberries jumps with a huge metal ball which comes down and whacks it. Scaling the bomy-knocker from Garnets head, which in a previous calc I put at being 0.560031954m high.

    23 pixels = 0.560031954m
    1 pixel = 0.560031954m/23 = 0.0243492154m
    0.0243492154m X 159 = 3.87152525m
    3.87152525m/2 = 1.93576262m
    0.0243492154m X 24 = 0.58438117m
    0.58438117m/2 = 0.292190585m
    0.0243492154m X 31 = 0.754825677m

    The ball as a sphere and the pointy bits as cylinders (of which I can count 9).

    V = πr^2h
    = π X 0.292190585^2 X 0.754825677
    = 0.20245521761 X 9
    = 1.82209695849m^3

    V = 4/3πr3
    = 4/3 X π X 1.93576262^3
    = 30.3839971844m^3

    V = 30.3839971844 + 1.82209695849
    = 32.2060941429m^3

    Medieval weapons (and weapons in general) are made of steel, which weighs 7850kg/m^3.

    M = 32.2060941429 X 7850
    = 252817.839022kg

    Spoiler:


    Timeframe is 0.16 seconds.

    0.0243492154m X 212 = 5.16203366m

    T = 5.16203366m/0.16s
    = 32.2627104m/s

    KE = (0.5)mv^2
    = (0.5) X 252817.839022 X 32.2627104^2
    = 131576829.932 joules

    Let's also add GPE.

    E = 1.93576262 X 9.807 X 252817.839022
    = 4799499.92725 joules

    E = 131576829.932 + 4799499.92725
    = 136376329.859 joules
    = 0.03259472510970363 tons of TNT

    Final Results
    Duke of Strawberries mace slam = 0.033 tons of TNT

    Could've sworn this would've been higher. :thunk

  15. 0:05

    Peridot moves some massive metal blocks. Scaling Peridot from Garnet, who I put at 2.14968787m in a previous calc.

    837 pixels = 2.14968787m
    1 pixel = 2.14968787m/837 = 0.00256832481m
    0.00256832481m X 495 = 1.27132078m
    0.00256832481m X 228 = 0.585578057m

    34 pixels = 1.27132078m
    1 pixel = 1.27132078m/34 = 0.0373917876m
    0.0373917876m X 192 = 7.17922322m
    0.0373917876m X 507 = 18.9576363m
    18.9576363m/2 = 9.47881815m
    0.0373917876m X 777 = 29.053419m

    That's all the hard work done! Now onto volume, which is obviously a rectangle.
    V = lhw
    = 7.17922322 X 7.17922322 X 18.9576363
    = 977.100196924m^3

    For mass, we'll go with a low end of aluminium (2600kg/m^3), a mid end of titanium (4500kg/m^3) and a high end of steel (7850kg/m^3, values here).
    (Low end)
    M = 977.100196924 X 2600
    = 2540460.512kg

    (Mid end)
    M = 977.100196924 X 4500
    = 4396950.88616kg

    (High end)
    M = 977.100196924 X 7850
    = 7670236.54585kg

    Spoiler:



    4.02 seconds.

    T = 29.053419m/4.02s
    = 7.22721866m/s

    Lastly, we get our energy! As well as the kinetic energy, we can also go for GPE. Earths Gravity Pull is 9.807m/s².

    (Low end)
    KE = (0.5)mv^2
    = (0.5) X 2540460.512 X 7.22721866^2
    = 66347542.6307 joules

    E = 9.47881815 X 9.807 X 2540460.512
    = 66347542.6307 + 236158083.405
    = 302505626.036 joules
    = 0.07230057983652008 tons of TNT

    (Mid end)
    KE = (0.5)mv^2
    = (0.5) X 4396950.88616 X 7.22721866^2
    = 114832285.322 joules

    E = 9.47881815 X 9.807 X 4396950.88616
    = 114832285.322 + 408735144.356
    = 523567429.678 joules
    = 0.1251356189478967 tons of TNT

    (High end)
    KE = (0.5)mv^2
    = (0.5) X 7670236.54585 X 7.22721866^2
    = 200318542.173 joules

    E = 9.47881815 X 9.807 X 7670236.54585
    = 713015751.821 + 200318542.173
    = 913334293.994 joules
    = 0.2182921352758126 tons of TNT

    Final Results
    Peridot moves blocks of steel (low end) = 0.073 tons of TNT
    Peridot moves blocks of steel (mid end) = 0.125 tons of TNT
    Peridot moves blocks of steel (high end) = 0.218 tons of TNT


    Higher than her getting smashed around in the canyon, but alas, still just small building level.
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