Greater Strength in Small Animals, Fae, Pixies, etc.

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For your holiday pleasure or need for nerdiness: This relates to a recent story, but also any story with small or shrinking beings/characters. This is just biophysics, no magic used!   The first part was written for something else.

Another factor in insects' strength relative to dogs, humans,
etc. is a scale factor.   Muscle strength is dependent on its cross section
area, the same with the strength of insect legs, however weight/mass is
dependent on volume.   Area takes 2 dimensions, but volume takes 3 dimensions.
As a primary dimension decreases, area decreases with the square of this
dimension ie. decreases faster and volume decreases with the cube of this
dimension ie decreases even faster than area.   What we get is strength to
weight ratio much higher than in larger animals.   This is also seen in the
jumping ability of small dogs, usually many times their height, compared to
that of elephants or even large mastiffs like 90kg.   

Here is an example:

Heavyweight class weight lifter (college or Olympic, no steroids) weight 100kg, lifts 300kg (maybe just lifts to his thigh ie. "dead lift"); 0.3m^2 cross-section (estimated) muscle area; height 1.8m; max. width 1m; typical thickness 0.556m; representative volume 1m^3 (not his actual volume, just a number to follow); muscle strength/ area = 1000kg/m^2 . I think best womyn weight lifters lift 75% of best men's lifts.   

Reduce linear dimension á·10 => (all dimensions stay in same proportion) volume .18*.1*.0556 = 0.001; weight 0.1kg; xsec 3*10^-3 m^2; lifts 3kg ie. 10x stronger per weight.   

This continues, volume and weight decrease with the cube of the linear dimension, muscle cross-section and strength decrease with the square of the linear dimension. Another 10x decrease: height 18mm; weight 0.1gram; strength 30grams. Insect size weight lifter lifts 300x his own weight.

Comments

Strength...

PattieBFine's picture

Many don't know that ants, spiders and other small creatures DON't even USE muscels to move about, but do so by way of hydrolics. most are exoskelatal though spiders may not seem to be so due to having a fine "fur" of hairs in theirs. This makes them a great deal stronger... and the way we use a floor-jack to lift a car, applies! The limits are then in the strength of their exoskelatons to hold the pressure generated there by.

Now to add another factor,

Now to add another factor, you need more than muscle to lift, you need a skeleton to support the weight. How does that affect the analysis? Insects have an exoskeleton rather than internal support. How is that a factor?

Kris

{I leave a trail of Kudos as I browse the site. Be careful where you step!}

Wait nobody said I had to

Wait nobody said I had to know maff.


I wear this crown of thorns
Upon my liar's chair
Full of broken thoughts
I cannot repair

It is said

Extravagance's picture

that Dung Beetles can lift almost a THOUSAND times their own weight.
No wonder they can take so much crap. :)

Catfolk Pride.PNG

I am

...BCTS's resident extravagant honorable Sighing dung beetle.

Words may be false and full of art;
Sighs are the natural language of the heart.
-Thomas Shadwell

Good Comments!

Pattie, thanks, I didn't know. Of course the cross section area also applies as in hydraulic cylinders. The force a cylinder can generate is the hydraulic pressure times the area of the cylinder piston. I was under the impression that arthropods have an open blood circulatory system, with many small openings letting in air, so body blood pressure would be very slight. I wonder how extensive a hydraulic system might be? Maybe each leg has it's own pump (muscular or just an array/layers of semipermiable membranes ?) and limited fluid; that way the animal can lose a leg and not lose all hydraulic pressure or large amounts of fluid. I think it's heart(s ?) is/are muscular. I guess blood is the leg, mandible, etc. hydraulic fluid, but maybe not! Wow, it's very cool to think of insects, etc. as hydraulically powered. The hydraulic pressure is the stored energy!

Kris, the analysis is the same. The strength and buckling resistance of any hollow column are proportional to cross section area. Whatever hydraulic pump force/membrane pressure is also based on area. There would be a ratio of "pump" volume or flow rate to the closed system volume indicating how fast pressure can be raised and how fast the leg can retract then extend again. This is all from mechanical engineering principles, life/organisms, of course, can be much more complex.

Thank you all for the comments. If anyone is writing a story and wants me to do strength or any other calculations, just PM me. (no calculus, I've already forgotten it. I'm slower and easily confused, but I think I can still do easier algebra and trigonometry problems.)

Hugs and Bright Blessings,
Renee

It's a good thing

that we humans don't have the blessings of the insects or animals.

    Stanman
May Your Light Forever Shine