How many Newtons of force would kill a person?

In summary, the force of the atmosphere is 100,000 Newtons per square meter, but it varies based on the surface area and the location where the force is exerted. There is no general answer for how many Newtons of force it takes to kill or hurt a person, as it depends on factors such as contact area, speed, mass, and deformation characteristics. Momentum and energy are more important concepts than force in addressing impacts, and the differences in force, known as stress, play a major role in causing damage. It is theoretically possible to accelerate at a billion gravities without killing yourself, but practically, it is unlikely due to the effects of high acceleration on the body.
  • #1
Simfish
Gold Member
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2
So yes, the atmosphere exerts a force of 100,000 Newtons per square meter. A person's head, is obviously much less than a square meter (probably 0.15 meters on the side, which roughly translates to Pi*(0.15/2)^2 square meters). Anyways, for this matter this is irrelevant, as we are already in equilibrium with this force and so we're more concerned about extraneous forces. Now, I know this would depend *a lot* on where the force is exerted and how it's exerted. For this, I'm mostly curious about arbitrary falling objects (rather than, say, bullets). How many Newtons of force would it take to have, say, a 50% chance of killing a person? How many would it take to hurt a person?
 
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  • #2
I don't think there is any general answer for this. A bullet doesn't produce a particularly large force, its speed and density allow it to penetrate the body. On the other hand, a large but flexible ball could land on your head and produce a huge force without doing any damage.
 
  • #3
It's far too complicated a subject to even begin to estimate a single force, because as you said it depends hugely on where the force is exerted and over what area. But let's look at two situations, a penetrative situation and a blunt impact.

Penetration (or indentation) is hugely dependent on contact area. So the force required to cause penetration or indentation to the same depth will be lower for a sharp knife than a blunt knife. Hence why it requires a lot less effort to cut a tomato with a knife once you've sharpened it. Essentially, the knife needs to create a stress at the interaction with the incident sample that is greater than the cutting strength of the material, which is related to at least compressive strength and fracture toughness.

Blunt trauma injuries can range from the fracture of bones to internal bleeding to brain damage and even stopping the heart. For many of these injuries there are different theories as to causal criteria. Essentially, for brusing and contusion it's a function of applied stress to soft tissues, and for head injuries acceleration (both linear and rotational) are important.

When it comes to impacts, the force that is experienced by your body is determined by a variety of things. The speed of the falling object at impact (relating to rate dependency of the surface being hit), the mass of the falling object (determining the kinetic energy of the object at impact e.g. a 10kg mass falling from 1m has 10 times the kinetic energy of a 1kg mass falling from 1m), and most importantly of all the deformation characteristics of the surface being hit, because in the case of an impact, the peak force experienced by your body is related to how the object is slowed down to rest. After that, you have to consider the area over which it's acting again in a similar way to the penetration example.
 
  • #4
QuantumPion touches on what is the key fact - damage is not done by force, but rather by the differences in force. If every atom in your body and the surrounding environment were suddenly and magically accelerated at a billion gravities, you would be perfectly fine.
 
  • #5
Force isn't a particular useful concept when comes to addressing impacts. Impact forces can be extremely high. Even then, the concept of force is a bit fuzzy. You can get very different values just be changing how finely you want to divide time. Force does come into play in the sense that a high impact force is needed for a small object to penetrate skin and bone. To dispel the notion that force is the critical factor, consider the needle yielded by a nurse in a doctors office. The impact force of this needle is incredibly high. Unless the nurse pokes your jugular the needle won't kill. The impact forces in an auto collision are much smaller than the needle, but that car collision may well kill.

Momentum and energy are much important concepts than force. Which of momentum or energy is more important depends on the circumstances. Consider two collisions of some object with a person's head: A purely inelastic collision with a 10 gram bullet traveling at 350 meters per second versus a nearly elastic collision with a 0.43 kg soccer ball traveling at 25 meters per second. The bullet transfers 1225 joules of energy but only 3.5 Newton-second of momentum to the head while the soccer ball transfers about 21.5 Newton-second of momentum but only a small amount of energy to the head. The bullet can kill while the soccer ball might leave an red mark on the defender's head and give him a bit of a headache. Now bump the soccer ball's speed up some, say to 59 meters per second (the fastest recorded kick). Trying to head that ball away might well kill, but in this case it is the momentum transfer that does the damage rather than energy.
 
  • #6
D H said:
Momentum and energy are much important concepts than force.

Certainly the elapsed time during which momentum or energy is transferred plays a role in this issue.
 
  • #7
Vanadium 50 said:
damage is not done by force, but rather by the differences in force.
To further emphasize this, these differences in force are called http://en.wikipedia.org/wiki/Stress_(physics)" [Broken] is much stronger in compression (205 MPa) than in shear (65 MPa).
 
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  • #8
Vanadium 50 said:
QuantumPion touches on what is the key fact - damage is not done by force, but rather by the differences in force. If every atom in your body and the surrounding environment were suddenly and magically accelerated at a billion gravities, you would be perfectly fine.

Is this true that you can accelerate from 0m/s to 30x10^8m/s without killing yourself?
 
  • #9
Flyingwing12 said:
Is this true that you can accelerate from 0m/s to 30x10^8m/s without killing yourself?

He said if every atom in your body were accelerated that fast at the same time. So he is right. But practically no. Top fuel Drag racers for example, experience 5G's of deacceleration. Their retinas detach from their eyes after repeated races.

Also TIME DOES play a huge role. I learned that when I read this:
http://www.motorcyclistonline.com/gearbox/motorcycle_helmet_review/index.html
You can take 200G's of force to your head for a very very small amount of time.

As noted earlier soft things like balls extend the time of impact. Hard things don't. I think I could use derivatives to explain this. I think I'll ponder this over.
 
  • #10
Flyingwing12 said:
Is this true that you can accelerate from 0m/s to 30x10^8m/s without killing yourself?

Yes, as long as every bit of your body accelerates at the same rate. If you are in free fall towards a planet, you are accelerating, yet you feel nothing. The more massive the planet, the greater the acceleration. No matter how huge and massive the planet was, you would be fine... until you hit. Then different parts of your body would decelerate at different rates, and you would not be fine.
 
  • #11
Flyingwing12 said:
Is this true that you can accelerate from 0m/s to 30x10^8m/s without killing yourself?
30 × 108 m/s is ten times the speed of light, so nothing can ever reach that speed.
 
  • #12
DrGreg said:
30 × 108 m/s is ten times the speed of light, so nothing can ever reach that speed.

LOL - right. The original poster said a billion gravities, which got changed to that. You could survive a billion gravities, as long as every bit of your body was subjected to that same acceleration.
 
  • #13
Rap said:
LOL - right. The original poster said a billion gravities, which got changed to that. You could survive a billion gravities, as long as every bit of your body was subjected to that same acceleration.


I thought due to relativity we are pretty much, being the size of the universe, being subjected to many gravities.

As well as us moving at 1000 +/- mph...every atom on this planet is accelerating that much.

And yet when you drive a car. You are accelerating only in the car?

Is there a possibility that a large enough object could strike this planet at 1000+/- mph and stop us?

I assume we would be subjected to a fatal force, that is. everything on this planet

Yeah kind of let my brain flow on this post...
 
  • #14
it takes very few Newtons to kill someone with a knife or a needle in the right spot, since pressure is force/area; objects with a very small area of contact can create a tremendous pressure.
 
  • #15
As a martial artists I'm interested in the damage cause by blunt force trauma as this is effectively what is suffered in unarmed combat.
QuantumPion said:
I don't think there is any general answer for this. A bullet doesn't produce a particularly large force, its speed and density allow it to penetrate the body. On the other hand, a large but flexible ball could land on your head and produce a huge force without doing any damage.

This is a misleading statement. Although I'm not a doctor I believe the reason a bullet or knife, or any penetrating object kills is because they severe major blood vessels and organs and fluids seep into body parts that are not suppose to have said fluid. This leads to infections, loss of volume and shock which are the ultimate cause of death. It's not the "force" of the impact nor pressure at the point of impact that cause one to die. As evidence of this I point to people who walk around with bullets or shapnel in them that can't be removed surgically.

In the past I've usually wondered if its the force or energy of the impact. I have discounted momentum as a modality of damage. Since energy and momentum are made up of the same components (ie mass and velocity). If you think about what happens if you are hit with a baseball bat that is swung in an arc. You can move inside the swing and take the impact away from the head of the bat, even a little bit, you can really reduce the damage done to you by the bat. Since the tangential velocity is proportional to the radius of the arc, the momentum of a point halfway down the bat is half of that at the tip (I'm assuming the bat is rotating around the grip end and not being swung by a human arm which will add length to the radius). Yet the kinetic energy is 1/4. Thus small changes in velocity yield big changes in damage.

The reason I ask this question (force vs energy) has to do with acceleration. If the force of a strike is the vehicle for damage then the ability to accelerate a weapon and not the velocity at impact is the critical factor. In that case, Bruce Lee's famous 6 inch punch can cause as much damage as the same punch thrown from 24 inches(assume arm's lenght). If, however, energy is important then the punch thrown from 24 inches, although striking with the same force (assuming uniform acceleration throughout the execution of the punch), will strike with a higher velocity (thus have more kinetic energy) and cause more damage.

Lastly I wonder how much "Jerk" plays into this (da/dt).

I'd be interested to hear from an MD on this.
 
  • #16
RamonaDave said:
This is a misleading statement. Although I'm not a doctor I believe the reason a bullet or knife, or any penetrating object kills is because they severe major blood vessels and organs and fluids seep into body parts that are not suppose to have said fluid. This leads to infections, loss of volume and shock which are the ultimate cause of death. It's not the "force" of the impact nor pressure at the point of impact that cause one to die. As evidence of this I point to people who walk around with bullets or shapnel in them that can't be removed surgically.

In the past I've usually wondered if its the force or energy of the impact. I have discounted momentum as a modality of damage. Since energy and momentum are made up of the same components (ie mass and velocity). If you think about what happens if you are hit with a baseball bat that is swung in an arc. You can move inside the swing and take the impact away from the head of the bat, even a little bit, you can really reduce the damage done to you by the bat. Since the tangential velocity is proportional to the radius of the arc, the momentum of a point halfway down the bat is half of that at the tip (I'm assuming the bat is rotating around the grip end and not being swung by a human arm which will add length to the radius). Yet the kinetic energy is 1/4. Thus small changes in velocity yield big changes in damage.

The reason I ask this question (force vs energy) has to do with acceleration. If the force of a strike is the vehicle for damage then the ability to accelerate a weapon and not the velocity at impact is the critical factor. In that case, Bruce Lee's famous 6 inch punch can cause as much damage as the same punch thrown from 24 inches(assume arm's lenght). If, however, energy is important then the punch thrown from 24 inches, although striking with the same force (assuming uniform acceleration throughout the execution of the punch), will strike with a higher velocity (thus have more kinetic energy) and cause more damage.

Lastly I wonder how much "Jerk" plays into this (da/dt).

I'd be interested to hear from an MD on this.

How is my statement misleading? What do you think is the cause of death due to any other large force? Hitting concrete at terminal velocity? A brick landing on your head?

Anyways, your question has already been answered in this thread. What kills you is stress (force per unit area).
 
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  • #17
QuantumPion said:
How is my statement misleading? What do you think is the cause of death due to any other large force? Hitting concrete at terminal velocity? A brick landing on your head?

Anyways, your question has already been answered in this thread. What kills you is stress (force per unit area).

I beg to lengthen your answer. A person can die so many ways from all different forces. The one thing I can think of off the top of my head is if you are wearing a very good helmet and get into a crash, the force per unit area is dispersed, and the impact is very small thanks to the collapsing foam liner (think air bags) Yet the person may still die. The brain continues moving inside the skull, and hits it. so the threshold all over the body is different. I can also see other factors playing a role, like the time the force is applied, and impact.
 
  • #18
QuantumPion said:
How is my statement misleading? What do you think is the cause of death due to any other large force? Hitting concrete at terminal velocity? A brick landing on your head?

Anyways, your question has already been answered in this thread. What kills you is stress (force per unit area).

Is this fact or merely speculation? Have there been studies?? I'd like to see them. You may be correct and the more I think about it the more reasonable the stress, as an answer, becomes to me but I'd like to know if this has been studied? I know in the case of bombs there have been studies and the overpressure or blast wave is the largest contributor to mortality and this would tend to support your theory.
 
  • #19
Flyingwing12 said:
Is this true that you can accelerate from 0m/s to 30x10^8m/s without killing yourself?

Well.. forgetting that the fact that the speed you just expressed is faster than the speed of light; no, you could travel at the speed of light if you either slowly accelerated to it, or if you teleported on a vehicle already traveling at the speed of light.

Acceleration is what matters, not speed. That is why Newtons second law is F=ma (force equals mass times acceleration) instead of force equals mass times speed.
 
  • #20
S_Byrnes said:
Well.. forgetting that the fact that the speed you just expressed is faster than the speed of light; no, you could travel at the speed of light if you either slowly accelerated to it, or if you teleported on a vehicle already traveling at the speed of light.

Acceleration is what matters, not speed. That is why Newtons second law is F=ma (force equals mass times acceleration) instead of force equals mass times speed.

Someone stated earlier that if the acceleration is uniform it can be as high as anything and you wouldn't be harmed. If every piece of matter in your body is accelerated at the same rate there's no damage done. How you would achieve this I don't have any ideas off the top of my head.
 
  • #21
The question makes no sense. Suppose your head weights 5kg
http://wiki.answers.com/Q/What_is_the_weight_of_an_adult_human_head
and I apply the force of 5000 Newtons to your head, uniformly, for just 1 microsecond. The acceleration of your head will be 1000 m/s^2 , or 100 g, which by itself won't kill you (you can suffer more when you bump your head on something wearing a helmet). The speed gained, for 1 microsecond, will be 1 millimetre per second. However, if this force is applied for more than a small fraction of second, your head is going to gain enough momentum to break your neck.
Furthermore, if same force of 5000 Newtons is applied to a small spot, it can break the skull.

edit: haha even better... suppose that you are in spacesuit... a force of 1 Newton is applied to you (due to e.g. leak of the suit) accelerating you until you crash into the space station. Or this force is applied off axis, and makes you spin until you exceed maximum survivable centrifugal force. In short, the safe limit on force really depends to circumstances. Pretty much any amount of force is survivable if applied for short enough time.
 
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  • #22
Dmytry said:
The question makes no sense. Suppose your head weights 5kg
http://wiki.answers.com/Q/What_is_the_weight_of_an_adult_human_head
and I apply the force of 5000 Newtons to your head, uniformly, for just 1 microsecond. The acceleration of your head will be 1000 m/s^2 , or 100 g, which by itself won't kill you (you can suffer more when you bump your head on something wearing a helmet). The speed gained, for 1 microsecond, will be 1 millimetre per second. However, if this force is applied for more than a small fraction of second, your head is going to gain enough momentum to break your neck.
Furthermore, if same force of 5000 Newtons is applied to a small spot, it can break the skull.

edit: haha even better... suppose that you are in spacesuit... a force of 1 Newton is applied to you (due to e.g. leak of the suit) accelerating you until you crash into the space station. Or this force is applied off axis, and makes you spin until you exceed maximum survivable centrifugal force. In short, the safe limit on force really depends to circumstances. Pretty much any amount of force is survivable if applied for short enough time.

Exactly. You can take 200g's to the head, with a Snell approved helmet for about 2 milliseconds. More force applied for more time to the head could certainly kill you, but the same force applied to your toe will only break it and at worst, with proper medical care ofcourse, you will be missing a toe, but won't die.
 
  • #23
michaelwoodco said:
Someone stated earlier that if the acceleration is uniform it can be as high as anything and you wouldn't be harmed. If every piece of matter in your body is accelerated at the same rate there's no damage done. How you would achieve this I don't have any ideas off the top of my head.

I wouldn't be so much worried about individual atoms as I would be organs.. But yes, in theory that would work.. But in practice, there could really only be one way to achieve that, which would be a teleportation device or something similar, that would bring a life form down to it's atomic level via de-materialization, send it to it's destination at the speed of light and then re-materialize it at the other end..
 
  • #24
S_Byrnes said:
I wouldn't be so much worried about individual atoms as I would be organs.. But yes, in theory that would work.. But in practice, there could really only be one way to achieve that, which would be a teleportation device or something similar, that would bring a life form down to it's atomic level via de-materialization, send it to it's destination at the speed of light and then re-materialize it at the other end..

Well gravity doesn't need a medium to travel through. So in theory if we produce artificial gravity by creating a black hole in front of a space ship, and have the black hole move so the spaceship never enters the center...Oh..wait...well we'll never see any of the likes within our lifetimes right? ;) :rolleyes: So I guess we'll never know for sure.
 
  • #25
michaelwoodco said:
Well gravity doesn't need a medium to travel through. So in theory if we produce artificial gravity by creating a black hole in front of a space ship, and have the black hole move so the spaceship never enters the center...Oh..wait...well we'll never see any of the likes within our lifetimes right? ;) :rolleyes: So I guess we'll never know for sure.

Why would we use a Black Hole for artificial gravity? The ship would not be able to escape the gravitational pull from the Black Hole and eventually get pulled past the Event Horizon.
 
  • #26
S_Byrnes said:
Why would we use a Black Hole for artificial gravity? The ship would not be able to escape the gravitational pull from the Black Hole and eventually get pulled past the Event Horizon.

Just using it as an example. Just picture whatever science fiction space travel device you want. Warp (bubble) drive, that black hole one (if people one day can make a black hole maybe they can shut it off) etc.
 
  • #27
michaelwoodco said:
Just using it as an example. Just picture whatever science fiction space travel device you want. Warp (bubble) drive, that black hole one (if people one day can make a black hole maybe they can shut it off) etc.

Well if one day we could create, destroy and manipulate a Black Hole, I'm pretty sure we could forge something a little less destructive to harnesses gravity for us.
 
  • #28
Is this for construction of free standing buildings? I didn't think QuantumPion's statement was confusing at all, RDave.
 
  • #29
timmay said:
It's far too complicated a subject to even begin to estimate a single force, because as you said it depends hugely on where the force is exerted and over what area. But let's look at two situations, a penetrative situation and a blunt impact.

Penetration (or indentation) is hugely dependent on contact area. So the force required to cause penetration or indentation to the same depth will be lower for a sharp knife than a blunt knife. Hence why it requires a lot less effort to cut a tomato with a knife once you've sharpened it. Essentially, the knife needs to create a stress at the interaction with the incident sample that is greater than the cutting strength of the material, which is related to at least compressive strength and fracture toughness.

Blunt trauma injuries can range from the fracture of bones to internal bleeding to brain damage and even stopping the heart. For many of these injuries there are different theories as to causal criteria. Essentially, for brusing and contusion it's a function of applied stress to soft tissues, and for head injuries acceleration (both linear and rotational) are important.

When it comes to impacts, the force that is experienced by your body is determined by a variety of things. The speed of the falling object at impact (relating to rate dependency of the surface being hit), the mass of the falling object (determining the kinetic energy of the object at impact e.g. a 10kg mass falling from 1m has 10 times the kinetic energy of a 1kg mass falling from 1m), and most importantly of all the deformation characteristics of the surface being hit, because in the case of an impact, the peak force experienced by your body is related to how the object is slowed down to rest. After that, you have to consider the area over which it's acting again in a similar way to the penetration example.


Not meaning to ressurect a dead post, but I was hoping someone could help me figure out what to name this type of pysics.

I'm going to be working on a safety application as a hobby project, so I was trying to find some concrete material about this type "physics of human safety." I have a pretty good grasp on Newtonian physics, so I understood everything in this post, but I was wondering if this type of stuff is written up in a book somewhere.

Most of the books I found on this type of topics seem to be "no calculus involved" for medical students type books. Does anyone have some suggestions?
 
  • #30
Simfish said:
How many Newtons of force would it take to have, say, a 50% chance of killing a person? How many would it take to hurt a person?
It isn't the force that would kill a person, but the stress. A person can undergo any size force and not notice it. What may kill a person is the stress and shear that the persons body is under. So the answer to your question is that force can't kill a person! However, the real question is what aspect of force would kill a person.
If the force were uniformly distributed, then every atom in the person would have the same force and the same acceleration. Therefore, the force wouldn't be noticed. It is inhomogeneities in the force that kills a person.
It is the gradient of force that would kill a person. The force has to be different in different parts of the body. If the force were sufficiently different on opposite sides of the body, or even on opposite sides of a vital organ, the person would die.
The gradient of force is referred to as the stress. A stress causes a strain. Strain is the gradient of displacement of the different parts of the body. If the strain is large enough, different parts of the body will move apart of move together. This would kill a person.
There are basically two types of stress: compressive and shear. There are maximum limits to each for various materials. Basically, what kills people in a fall is usually the shear stress. For example, a bone could break if enough shear is applied to it.
This is actually a problem in continuum mechanics. One has to know the maximum stress and shear of the bodies materials. Then, one has to determine what the actual stress and shear is under those conditions. This could be complicated in a system as complicated as the human body. No wonder scientists use accident dummies instead of computer simulations!
 
  • #31
Based on typical ballistics numbers, 100 J seems to be the minimum lethal kinetic energy. This is roughly equivalent to a .22 long bullet (40 grains) from a rifle at 1000 fps. The next level of damage is at about 1000 J, which corresponds to a .357 jacketed soft-point (158 grains) bullet at 1400 fps. This is fairly lethal (depending exactly where it hit) to unprotected personnel. Lastly, something around 4000 J is sufficient to penetrate body armor. This is something like a 7.62 full metal jacket or .30-06 armor piercing bullet (166 grains) at 2750 fps. Roughly dividing this into three broad categories:

Light (.22 cal): 100 J.
Moderate (.357 cal.): 1000 J.
Heavy(.30-06 cal): 4000 J.
http://www.fas.org/man/dod-101/navy/docs/es310/dam_crit/dam_crit.htm

It appears that 1000J is required to get a Psubk of .5.

Daggs
 
  • #32
At 3 secs, Force exerted is 154 N.(Assume sustained before then), then at 3.02 secs, force reaches 501262.875 N. At 3.05 secs, force has decreased to 47162 N and decreases until at 4.1 secs force is 712 N and stabilizes. Assume body is 100 lbs.
 
  • #33
Flyingwing12 said:
Is there a possibility that a large enough object could strike this planet at 1000+/- mph and stop us?

It would be a good exercise to try calculating how large a mass would be needed to produce that effect - conservation of momentum is all you need. Before you try it, be careful to define what you mean by "stop" and "moving at 1000 mph", as both have to relative to something - the sun might be a good choice.
 
  • #34
Old thread rises from the dead.
 
  • #35
Willt125 said:
At 3 secs, Force exerted is 154 N.(Assume sustained before then), then at 3.02 secs, force reaches 501262.875 N. At 3.05 secs, force has decreased to 47162 N and decreases until at 4.1 secs force is 712 N and stabilizes. Assume body is 100 lbs.
You have replied to a 2 year dead thread and I don't see a question in there. Is there something you need help with?
 

1. How many Newtons of force would be considered fatal for a person?

The amount of force required to kill a person varies greatly depending on factors such as age, health, and where the force is applied. However, research suggests that a force of 3,500 Newtons or more could be fatal for most adults.

2. Can a person survive a force of 3,500 Newtons?

It is possible for a person to survive a force of 3,500 Newtons, but it is highly unlikely. This amount of force is considered fatal for most adults and could result in severe injuries or death.

3. How does the human body react to a force of 3,500 Newtons?

When a force of 3,500 Newtons is applied to the human body, it can cause severe damage to internal organs, bones, and tissues. It can also result in fractures, hemorrhages, and other life-threatening injuries.

4. Is there a specific body part that is more vulnerable to 3,500 Newtons of force?

The human head is the most vulnerable body part when it comes to a force of 3,500 Newtons. This amount of force can cause severe brain injuries, which can be fatal or result in permanent damage.

5. Can a person survive a force of 3,500 Newtons if they are wearing protective gear?

Wearing protective gear, such as a helmet or body armor, can help reduce the impact of a force of 3,500 Newtons. However, it may not completely prevent injuries or death. The amount of force and the specific location of impact are also important factors to consider.

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