Reference for Common Feats: Difference between revisions

=='''Impact Feats'''==

===<u>'''Getting Hit by a Car'''</u>===

===='''If not slammed into a wall'''====

For example, assuming the human is 70 kg, the car is 1500 kg and that the car's speed is 11.176 m/s:

Using the values above this is 10.677707006369426751592356687898 m/s.

'''Street level'''

===='''If slammed into a wall'''====

However, it should be noted that the above calculation assumes that the person is sent flying by the car. In some odd cases in fiction, the car stops and the character tanks the attack. Or in some cases, a character is slammed into a wall by a car. In these cases, the entire KE of the car scales to the character's durability.

'''KE= 1/2*mass*velocity^2''' (Where mass is in kilograms and velocity is in meters per second)

=====<u>'''Getting Hit by a Car'''</u>=====

0.5*1500*11.176^2 = '''9.3677232e4 Joules - Wall level'''

This value assumes that this is an average-sized car weighing in at 1500 kg and travelling at 25 mph/11.176 m/s.

When travelling at '''45 mph''': 0.5(1500) * 20.1168^2 = 303,514.23168 joules, or '''303.5 Kilojoules''' - '''Wall level'''

When travelling at '''60 mph''': 0.5(1500) * 26.8224^2 = 539,580.85632 joules, or '''539.5 Kilojoules''' - '''Wall level'''

When travelling at '''70 mph''': 0.5(1500) * 31.2928^2 = '''734,429.49888 joules, or 734 Kilojoules - Wall level'''

Here are some values for other vehicle types and the like.

=====<u>'''Getting Hit by a Bus'''</u>=====

The average "traditional-sized" school bus weighs in at [http://www.scapt.org/files/download/school%20bus%20types.pdf 10,659.421 kg].

'''25 mph (Average suburb speed)'''= 0.5(10,659.421) * 11.176^2 = 665,696.702668 joules, or '''666 Kilojoules''' - '''Wall level'''

'''45 mph (Daily City travel speed)'''= 0.5(10,659.421) * 20.1168^2 = 2,156,857.31665 joules, or '''2.15 Megajoules''' - '''Wall level'''

'''60 mph (Traditional interstate travel speed)'''= 0.5(10,659.421) * 26.8224^2 = 3,834,413.00737 joules, or '''4 Megajoules''' - '''Wall level'''

'''70 mph (Highway speed limit)'''= 0.5(10,659.421) * 31.2928^2 = 5,219,062.14892063232 joules, or '''5.22 Megajoules - Wall level'''

=====<u>'''Getting hit by a Pickup Truck'''</u>=====

'''25 mph (Average suburb speed)'''= 0.5(4,082.3) * 11.176^2 = 254,945.709462 joules, or '''255 Kilojoules''' - '''Wall level'''

'''45 mph (Daily City travel speed)'''= 0.5(4,082.3) * 20.1168^2 = 826,024.098658 joules, or '''826 Kilojoules''' - '''Wall level'''

'''60 mph (Traditional interstate travel speed)'''= 0.5(4,082.3) * 26.8224^2 = 1,468,487.2865 joules, or '''1.5 Megajoules''' - '''Wall level'''

'''70 mph (Highway speed limit)'''= 0.5(4,082.3) * 31.2928^2 = 1,998,774.362185216 joules, or '''2 Megajoules - Wall level'''

=====<u>'''Getting hit by a Semi Truck'''</u>=====

'''25 mph (Average suburb speed)'''= 0.5(36,287) * 11.176^2 = 2,266,177.145056 joules, or '''2.27. Megajoules''' - '''Wall level'''

'''45 mph (Daily City travel speed)'''= 0.5(36,287) * 20.1168^2 = 7,342,413.94998144 joules, or '''7.34 Megajoules''' - '''Wall level'''

'''60 mph (Traditional interstate travel speed)'''= 0.5(36,287) * 26.8224^2 = 13,055,127.03695416 joules, or '''13 Megajoules''' - '''Wall level+'''

'''70 mph (Highway speed limit)'''= 0.5(36,287) * 31.2928^2 = 17,766,828.81723904 joules, or '''17.77 Megajoules - Wall level+'''

===<u>'''Falling from Great Heights'''</u>===

However, in most cases in fiction, in order to make the character's durability impressive, the height is so great that it reaches terminal velocity ([https://vsbattles.fandom.com/wiki/Calculations#Terminal_velocity more details about that]).

The terminal velocity of a human being is around [https://en.wikipedia.org/wiki/Free_fall 53 m/s].

Assuming the person is 70 kg:

Approximating that border without air resistance: 53 m/s / 9.8 m/s^2 = 5.4081632653061224s drop time.

 

===<u>'''A Human-Shaped Hole'''</u>===

The average human body has a surface area of 1.9 m^2. Divide that in half and you get 0.95m^2, or 9,500 cm^2.

Assuming that the average human head's length (meaning, front to back) is 7/8ths of the average human head's height (23.9 cm). That will be used for the depth of the crater.

Fragmentation:

 

198,668.75 * 208 = 4.1323100e7 joules, or 0.009 Tons of TNT, '''Small Building level'''

Violent fragmentation:

198,668.75 * 568.5 = 1.12943184e8 joules, or 0.027 Tons of TNT, '''Small Building level'''

==='''<u>[[User_blog:CrimsonStarFallen/Cannonball AP|Getting hit by cannonballs]]</u>'''===

KE= 0.5 * m * v^2, where mass= kg and v= m/s

Low end (381 m/s)= 197.531 kilojoule, 9-B, (Wall level)

Mid end (441.96 m/s)= 217.7 kilojoule, 9-B (Wall level)

 

High end (518.16 m/s)= 265.8 kilojoule, 9-B (Wall level)

Low-end (381 m/s)= 395 kilojoule, 9-B (Wall level)

 

Mid-end (441.96 m/s)= 531.6 kilojoule, 9-B (Wall level)

High-end (518.16 m/s)= 730.71 kilojoule, 9-B (Wall level)

Low-end (381 m/s)= 592.6 kilojoule, 9-B (Wall level)

 

Mid-end (441.96 m/s)= 797.4 kilojoule, 9-B (Wall level)

High-end (518.16 m/s)= 1.09606 megajoule, 9-B (Wall level)

Low-end (381 m/s)= 790 kilojoule, 9-B (Wall level)

Mid-end (441.96 m/s)= 1.0632 megajoule, 9-B (Wall level)

High-end (518.16 m/s)= 1.46 megajoule, 9-B (Wall level)

===='''32 lbs (14.515 kg)'''====

Low-end (381 m/s)= 1.05 megajoules, 9-B

Mid-end (441.96 m/s)= 1.41 megajoules, 9-B

High-end (518.16 m/s)= 1.94 megajoules, 9-B

 

===='''42 lbs (19.0509 kg)'''====

 

Mid-end (441.96 m/s)= 1.86 megajoule, 9-B (Wall level)

 

High-end (518.16 m/s)= 2.56 megajoule, 9-B (Wall level)

 

==='''<u>Surviving a Fall from Low-Earth Orbit</u>'''===

[https://en.wikipedia.org/wiki/Low_Earth_orbit Low Earth orbit ]starts at 160km.

For the weight of the creature I will assume 60 kg.

 

 

 

 

 

 

 

 

 

 

 

 

[https://en.wikipedia.org/wiki/Free_fall The terminal velocity for a human is 53 m/s], near the ground.

So at terminal velocity this would only be low end '''Wall level'''.

'''What is Realistic?'''

The actual value would likely lie somewhere inbetween those two.

One could try to do a more accurate method using the drag equation and the barometric formula, even though I am not quite sure whether that would work (at some point of the fall we would likely talk about supersonic stuff which it usually is hard to get the needed values for).

Also let us mention that this is only for low earth orbit falling. For higher alitudes the potential energy value would go closer to the kinetic energy when falling with [https://en.wikipedia.org/wiki/Escape_velocity escape velocity], while for lower it would mostly just stay the same (the realistic value would go towards to terminal velocity value) except for short falls where not even that much speed if attained.

=='''Bone Breaking Feats'''==

On average, the weight of a man's bones is 15% of their body mass, which inof itself is 88.768027 Kilograms. 15% of that is 13.31520405 Kilograms.

The density of bone is 3.88 g/cm^3, which would mean that the total volume would be 13.31520405 divided by 0.00388, which equals 3431.75362113402 cm^3 for our volume.

To get the fragmentation values, we need to use the compressive strength of bones. To quote [https://en.wikipedia.org/wiki/Bone Wikipedia], "bone has a high compressive strength of about 170 MPa (1800 kgf/cm²), poor tensile strength of 104–121 MPa, and a very low shear stress strength (51.6 MPa)"

So, low end is 51.6, mid is 104, high is 170. Plugging those all into our volume gets us....

Low End: 1.77078.486850515432e5 Joules, '''Wall level'''

Mid End: 3.56902376598e5 Joules, '''Wall level'''

 

===<u>'''Breaking a Human neck'''</u>===

 

 

 

 

 

 

 

 

 

===<u>'''Breaking a Bone'''</u>===

A bone of a deceased 52-year old woman only required 375 Joules of energy when the force was applied within five degrees of the orientation of the collagen fibres. But the force increased exponentially when they applied it at anything over 50 degrees away from that orientation, up to 9920 Joules when they applied a nearly perpendicular force.

So breaking a bone would require 375-9920 Joules, depending on the angle of attack. That's '''Street level''' to '''Street level+'''.

==='''<u>Vaporizing a Human</u>'''===

'''Conditions'''

https://www.thoughtco.com/chemical-composition-of-the-human-body-603995

Okay, First off. To vaporize a human thoroughly at once, let’s assume the temperature change is 1800°F or 982.2°C https://www.cremationresource.org/cremation/how-is-a-body-cremated.html

 

 

 

 

 

 

 

'''STEP I'''

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Plugging it into the specific heat energy calculator, we get '''32,060,320 J'''.

We will bone for this, specifically cortical bone, which is 1.313 kilojoules per kilogram.

We get '''4,614,353 J'''

'''STEP V'''

Carbohydrates make up merely 1% of human weight, or 0.62 kilograms

https://www.researchgate.net/post/What_are_the_Heat_capacities_of_carbohydrates_for_liquid_amorphous_glass_and_solid_states

Heat energy of sugar (carbohydrate) is 1.255 kilojoules per kilogram.

 

 

 

 

 

==='''<u>Vaporizing an average Building</u>'''===

 

=='''Melting/Heat Feats'''==

 

===<u>'''Surviving the Heat of the Sun'''</u>===

The temperature of the sun is about 5500°C per [https://en.wikipedia.org/wiki/Sun#Sunlight Wikipedia].

For the surface area we take the surface of the average human body, since we assume that the person is submerged in the sun. The average body surface area is about 1.73 m^2 per [https://en.wikipedia.org/wiki/Body_surface_area this] article.

Human Skin is around 3mm thick. (https://en.wikipedia.org/wiki/Human_skin)

Normal skin temperature is about 33°C. (http://hypertextbook.com/facts/2001/AbantyFarzana.shtml)

Now we add both results together to get a final value: 658901.0633333334 J/s + 130756044.60407 J/s = 1.3141494566740333*10^8 J/s. '''Core''' Now a similar procedure for the core. The core of the sun is about [https://en.wikipedia.org/wiki/Sun#Core 15.7 million Kelvin hot]. The emissivity of the sun at temperatures such as this isn´t known, but the article that is linked to emissivity states says that the minimum lies at 6900°C. So we will use the minimum emissivity of 0.92 for this. Now we just need to input all values in the calculators again.

[https://en.wikipedia.org/wiki/Human_body_weight#Ideal_body_weight Average weight of a grown human is around 62 kg.]

'''Surface: '''The surface of the sun has a temperature of 5.773.2K.

That is <u>Building Level</u>.

'''Core: '''The core of the sun has an temperature of 15 700 000K.

That is <u>Multi-City Block Level+</u>.

===<u>'''Melting a Plane'''</u>===

'''Melting Point''' Titanium = 1604 °C

Steel = 1425 °C

Aluminium = 502 °C

Total Energy = (((526.3)*(7320.98084)*(1604-25)) + ((7320.98084)*(419000))) + (((510)*(23793.1877)*(1604-25)) + ((23793.1877)*(272000))) + (((875)*(148249.862)*(1604-25)) + ((148249.862)*(398000))) = 2.9861275268025227e11 Joules, or 71.37 Tons, '''City Block level+'''

===<u>'''Melting a Tank'''</u>===

Materials of tanks and especially how much of which is there is mostly classified information. Using [https://en.wikipedia.org/wiki/Vehicle_armour#Composite this] article on composite armour we get 10% ceramics and 90% steel, given that the mechanics and everything will be made out of metal. For the ceramics we will assume Alumina, since that is also mentioned as a material used [https://en.wikipedia.org/wiki/Chobham_armour#Material here].

Alumina: 2072 °C (per wikipedia)

Steel: 1425 °C (per [http://www.engineeringtoolbox.com/melting-temperature-metals-d_860.html this])

Mass of materials: 6000 kg alumina, 54000 kg Steel

Assuming a tank is on average 20°C warm.

850 J/(kg*K)*6000 kg *(2072 °C - 20 °C) + 620000 J/kg * 6000 kg + 481 J/(kg * K) * 54000 kg * (2072 °C - 20 °C) + 260000 J/kg * 56000 kg = 8.2043848e10 Joules, '''City Block level'''

 

Low end: 850 J/(kg*K)*6000 kg *(1425 °C - 20 °C) + 620000 J/kg * 6000 kg + 481 J/(kg * K) * 54000 kg * (1425 °C - 20 °C) + 260000 J/kg * 56000 kg = 6.193897e10 Joules, '''City Block level'''

===<u>'''Durability to Tank Lava'''</u>===

[http://volcano.oregonstate.edu/how-hot-lava Lava can be between 700°C and 1250°C]. Given that we likely don´t know the heat of the lava let's work with 700°C.

[https://en.wikipedia.org/wiki/Body_surface_area The average human body surface area is 1.73 m^2].

Human Skin is around 3 mm thick. (https://en.wikipedia.org/wiki/Human_skin)

Normal skin temperature is about 33°C (http://hypertextbook.com/facts/2001/AbantyFarzana.shtml)

=='''Weather Feats'''==

 

===<u>'''Destructive Energy of Winds'''</u>===

 

[https://www.engineeringtoolbox.com/standard-atmosphere-d_604.html Air is 1.225 kg/m^3 at sea level.]I am going to find the energy of different winds at diffirent speeds and different sizes.

1 m/s = 0.6125 J = '''Below Average level'''

5 m/s = 15.3125 J = '''Below Average level'''

10 m/s = 61.25 J = '''Human level '''(A little over [https://sciencing.com/average-wind-speed-during-thunderstorm-24075.html Low-End wind speed of a thunderstorm])

20 m/s = 245 J = '''Athlete level+''' (A little over the High-End wind speed of a thunderstorm and [http://www.tornadoproject.com/cellar/fscale.htm Low-end speed of an f0 tornado] )

40 m/s = 980 J = '''Street level''' (Speeds of an F1 tornado and [https://en.wikipedia.org/wiki/Saffir%E2%80%93Simpson_scale Category 1 hurricane] )

50 m/s = 1531.25 J = '''Street level''' (An F2 tornado and Cat. 3 hurricane)

70 m/s = 3001.25 J = '''Street level''' (An F3 tornado and Cat. 5 hurricane)

90 m/s = 4961.25 J =''' Street level''' (An F4 Tornado)

115 m/s = 8100.31 J = '''Street level''' (An F5 tornado)

135 m/s = 11162.8 J = '''Street level+''' ([https://en.wikipedia.org/wiki/1999_Bridge_Creek%E2%80%93Moore_tornado Highest wind speed recorded on Earth])

170 m/s = 17701.3 J = '''Wall level''' ([https://www.nasa.gov/centers/goddard/news/topstory/2008/jupiter_lrs.html Great Red Spot wind speeds])

500 m/s = 153125 J = '''Wall level''' ([https://www.nasa.gov/mission_pages/cassini/whycassini/planet.html Wind speed of Saturn])

600 m/s = 220500 J = '''Wall level''' ([https://en.wikipedia.org/wiki/Neptune#Climate Wind speed of Neptune])

2415 m/s = 3572240 J = '''Wall level''' ([https://warwick.ac.uk/newsandevents/pressreleases/5400mph_winds_discovered/ Fastest wind speed ever found on a planet])

===<u>'''Creating a Storm'''</u>===

Storms are calculated with either CAPE, condensation, or KE (if applicable). You can read more about that [https://vsbattles.fandom.com/wiki/Cloud_Calculations here]. Usually the storm clouds extend all the way to the horizon. The visibility on a normal day is 2000 km.

 

 

 

Multiplying that by 1.003 (density of cloud) gives us 10083255780961 kg.

'''CAPE'''

 

 

 

 

 

 

 

 

 

 

 

 

 

Explosion radius = '''20037.50 km'''

This method assumes that all they're doing is causing the Earth to quake via sheer brute Force. This is what is usually used for the standard Earthquake feat, but, if there's sufficient evidence they're also moving the plates via magic or sheer rule of cool, you can move to the next section.

 

 

 

(Magnitude at distance) + 6.399 + 1.66×log((r/110)×((2×π)/360)) = Richter Magnitude of Earthquake, with r representing the distance away from it.

In our case, it would be, using half of the Circumference of earth,

(4)+6.399+1.66×log((20037.5÷110)×((2×π)÷360)) = Magnitude 11.2328648415393

Now, we take the magnitude and use the formula for a joulecount from said magnitude listed in [https://vsbattles.fandom.com/wiki/Earthquake_Calculations Earthquake Calculations]

10^(1.5*(11.2328648415393)+4.8) is 4.459613919339E21 Joules, 1.06587330768147 Teratons, '''Small Country level'''

===<u>'''The Earth's Rotational Energy'''</u>===

[https://vignette.wikia.nocookie.net/vsbattles/images/b/ba/Mic.gif/revision/latest?cb=20160506130520 (Picture)]

The formula of the rotational energy is K= 1/2* Ι*ω^2

The Earth's angular velocity is [https://en.wikipedia.org/wiki/Earth%27s_rotation#Angular_speed 7.3*10^-5 rad/s]

===<u>'''Splitting the Earth in half'''</u>===

M = m = mass of half of the Earth = 5.97237e+24/2 = 2.986185e+24 kg

[[File:800px-The_Earth_seen_from_Apollo_17.jpg|center|700px]]

=='''Freezing Feats'''==

[https://en.wikipedia.org/wiki/Human_body_weight Average human weight] = 62kg

[https://en.wikipedia.org/wiki/Body_water On average 65% of the human body weight is water.]

So water mass = 0.65*62kg.

So total energy = 62 * 3500 * 38 + 0.65*62*1000*333.55 =21,688,065 Joules, '''Small Building level'''

=='''Crushing Feats'''==

===<u>'''Crushing a Golf Ball'''</u>===

The core of the ball is 3.75 cm in diameter. [https://en.wikipedia.org/wiki/Golf_ball#Design The ball itself can be no less than 4.267 cm in diameter].

723.2373463 Joules in total, '''Street level'''

 

===<u>'''Crushing a Human Skull'''</u>===

Compressive Strength of Bone - [https://en.wikipedia.org/wiki/Bone 170 MPa]

 

Weight of the Skull - [http://www.answers.com/Q/What_is_the_average_weight_of_a_human_skull?#slide=2 997 g]

 

Density of Bone - [http://hypertextbook.com/facts/2002/AnnaYarusskaya.shtml 1.6 g/cm^3]

 

 

 

 

 

56.1 MPa*623.125 cm^3 = 34,960 J

 

 

Head Crush (Compressive) - 1.05931e5 Joules, '''Wall level'''

 

 

'''NOTE:''' In case the skull is destroyed in a swift blow, the shear value would apply, and in the case of the head being slowly crushed to pieces, the compressive value would apply.

 

=='''Potential Energy/Lifting Feats'''==

 

===<u>'''Leaping onto a Roof'''</u>===

Another common feat in fiction is when a character is leaping high in the air usually to jump on a roof of a nearby building.

 

 

PE = 70*10*9.81 = 6.867e3 Joules, '''Street level'''

 

 

PE = 70*30*9.81 = 2.0601e4 Joules, '''Wall level'''

 

Tall building (70 m)

 

PE = 70*70*9.81 = 4.8069e4 Joules, '''Wall level'''

 

Skyscrapers (300 m)

 

 

 

The amount of force necessary to [https://www.youtube.com/watch?v=-6NZMAbfmW0#t=1m42s break a neck] is around [https://en.wikipedia.org/wiki/Hanging#Long_drop 1000-1250 lbf].

However, technique can [https://vsbattles.fandom.com/wiki/User_blog:XING06/Can_Opener_Neck_Crank_Force greatly reduce] the lifting strength necessary through leverage and [https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5535002/ bodyweight application]. In addition, many fictional cases of neck snapping are outliers, with the characters never demonstrating similar lifting strength in any other capacity.

For these reasons, only use neck snapping as justification for Class 1 if the character has consistently demonstrated such strength with other feats.

===<u>'''Destroying a Door'''</u>===

Volume = 61947.75 cm^3

[http://web.archive.org/web/20170322181309/http://www.narutoforums.com/xfa-blog-entry/because-fluttershit-sucks-and-we-need-something.34025/ Fragmentation values for wood and steel can be found here].

'''Wood Door''' Fragmentation = 516644.24 Joules

'''Steel Door''' Fragmentation = 1.289e7 Joules

Pulverization = 4.058e7 Joules

===<u>'''Destroying a Car'''</u>===

[https://www.epa.gov/fuel-economy-trends/highlights-co2-and-fuel-economy-trends#Highlight2 The EPA stated that an average vehicle produced in 2016 weighed, on average, 4,035 lbs.] or '''1830.245 kg'''

[https://www.aluminum.org/news/unprecedented-growth-expected-automotive-aluminum-multi-material-vehicles-ascend-new-survey as of 2015, The average vehicle uses 397 lbs of aluminum]. or '''180.076 kg''' at '''9.838901349272913 %''' of the car.

[https://www.copper.org/publications/pub_list/pdf/A6191-ElectricVehicles-Factsheet.pdf The highest amount of copper used in an average conventional car is 49 lbs]. or '''22.226 kg'''at '''1.2143729391420275 %''' of the car.

[https://altairenlighten.com/news/plastic-reduces-weight-of-car-windows-by-50-percent/ The amount of glass in an average vehicle is 100 lbs]. or '''45.3592 kg''' at '''2.478313012738732%''' of the car

[https://plastics.americanchemistry.com/Automotive/ Plastic makes up 10% of the weight of a car]. or '''183.0245 kg'''

[https://p2infohouse.org/ref/11/10504/html/intro/tire.htm Tires are made up of 14% natural rubber and 27% synthetic rubber with an average weight of 25 lbs]. or '''11.3398 kg'''. 14% of the tires is '''1.5875720000000002 kg'''. 27% is '''3.0617460000000003''' kg. Since there are 4 tirse we will time these numbers by 4. The total weight lf natural rubber is '''6.350288 kg''', or '''0.3469638217834225 %''' of the car. The total weight of synthetic rubber is '''12.246984 kg''', or '''0.6691445134394576%''' of the car.

[https://www.fcagroup.com/en-US/sustainability/overview/pubblicazioni/FiatDocuments/sustainability_report_2012_UK.pdf#page=114 The amount of cast iron in an average car is about 7.2%]. or '''131.77764000000002 kg'''.

 

This all accounts for about 80.92144004% of the weight for the car.This isn't at 100% but this is as much percentage of materials that could be found, so consider this a low-ball or a near complete fragmentation of a car.

Steel = an average of [https://en.wikipedia.org/wiki/Steel#Material_properties 7.9 g/cm³]

Synthetic Rubber = We[https://en.wikipedia.org/wiki/Polybutadiene will use polybutadiene since it is mostly used in car tires]. 0.925 g/cm^3

Steel = 113,924.0506 cm³

Aluminum = 66,694.81481 cm³

Copper = 2,480.580357 cm³

Glass = 9,071.84 cm³

Plastic = 81,890.1566 cm³

Natural Rubber = 6,902.486957 cm³

Synthetic Rubber = 13239.9827 cm³

Cast Iron = 18,051.73151 cm³

'''Energy to Fragment Materials'''

Steel = 208 j/cc

[http://www.matweb.com/search/DataSheet.aspx?MatGUID=f3cd25980ab24fdaa5893252cd2bc192 Cast Iron = 149 MPa or j/cc]

Glass = 0.75 j/cc

Aluminium = [https://www.experimentalaircraft.info/articles/aircraft-aluminum.php 40000 PSI = 275.79 megapascales = 275.79 J/cc ]

Copper = [https://www.copper.org/applications/architecture/arch_dhb/technical-discussion/fundamentals/intro.html 25,000 PSI = 172.36893 MPa = 172.36893 J/cc]

Plastic = It is insanely difficult for me to find plastic mechanical properties. Polypropylene will be used since it is used for most cars, especially in their bumpers. [https://www.makeitfrom.com/material-properties/Polypropylene-PP-Homopolymer an average of ]38.7 [https://www.makeitfrom.com/material-properties/Polypropylene-PP-Homopolymer MPa = ]38.7 [https://www.makeitfrom.com/material-properties/Polypropylene-PP-Homopolymer j/cc]

Natural Rubber =[http://web.mit.edu/course/3/3.225/book.pdf#page=114 0.001 GPa = 1 MPa = 1 J/cc]

Synthetic Rubber = [https://www.azom.com/properties.aspx?ArticleID=1719 4.285714286 MPa = 4.285714286 J/cc]

23,696,202.52 Joules for all the steel

2689707.995 Joules for all the iron

6803.88 Joules for all the glass

18,393,762.98 Joules for all the aluminum

3169149.06 Joules for all the plastic

427,574.9819 Joules for all the copper

56742.783 joules for Synthetic Rubber

6902.486957 Joules for all the natural rubber

 

===<u>'''Destroying a Tree'''</u>===

Plugging this into the formula for volume of a cylinder since tree trunks are cylindrical = 38 m^3

 

 

[https://www.fpl.fs.fed.us/documnts/fplgtr/fplgtr113/ch04.pdf The weakest wood that could be found comes from Ceiba pentandra at 350 PSI = 2.41317 MPa = 2.41317 J/cc. The hardest wood that could be found is Dalbergia nigra at 2360 PSI = 16.27163 MPa = 16.27163 J/cc]

Low End: 2.41317*38000000 = 9.1700460e7 Joules, 0.022 Tons of TNT, '''Small Building level'''

High End: 16.27163 x 38000000 = 6.1832194e8 Joules, 0.148 Tons of TNT '''Small Building level+'''

The high end is a low ball since Dalbergia nigra is not the hardest type of wood. The low end could go lower since wood like balsa is weaker than Ceiba pentandra.

This also doesn't take into account branches either.

===<u>'''Destroying a Wrecking Ball'''</u>===

[https://en.wikipedia.org/wiki/Wrecking_ball The weight of a wrecking ball ranges from 450 kg to 5400 kg and they are made of steel.]

450000/7.9 = 56962.02532 cc

 

5400000/7.9 = 683544.3038 cc

Steel = 208 J/cc

Low-end: 208*6962.02532 = 1.184810127e7 Joules, '''Wall level+'''

High-end: 208*683544.3038 = 1.421772152e8 Joules, or 0.034 Tons of TNT, '''Small Building level'''

===<u>'''Breaking off a Lock'''</u>===

'''Volume of shackle'''

[[File:MUL-T-LOCK-TSR25_size.png|thumb|400px]]

There will be no measurement to how much energy it takes to completely fragment a lock since most are just broken off. So, it will be just the measurement of the shackle and not the rest of the lock.