Is Bigger Better?

@MinuteEarth, could you please include the metric system? I am from the United States, but I use this international system of measurement for reasons of international collaboration and convenience. I used to rely on the expendable US customary system or Imperial System, but now I comprehend how simple, feasible and constructive really is as it has metric prefixes that are denote to either multiply or divide by 10. Many hospitals, NASA and the U.S. Military use the metric system for the same reasons.
Take NASA's Mars Climate Orbiter which launched on Friday, December 11, 1998, to study the atmosphere and climate of Mars. But the space probe crashed on the planet on Thursday, September 23, 1999, due to an error in calculating between US customary units and metric units. Because of this, NASA uses the metric system for all intents and purposes.

I think the first title was better

​@@alphaapple1375get rekd metric user

What's the name of this piece of music? Assumed to be composed by Nathaniel Schroeder?

​@@alphaapple1375
*Revelation 3:20*
Behold, I stand at the door, and knock: if any man hear my voice, and open the door, I will come in to him, and will sup with him, and he with me.
HEY THERE 🤗 JESUS IS CALLING YOU TODAY. Turn away from your sins, confess, forsake them and live the victorious life. God bless.
Revelation 22:12-14
And, behold, I come quickly; and my reward is with me, to give every man according as his work shall be.
I am Alpha and Omega, the beginning and the end, the first and the last.
Blessed are they that do his commandments, that they may have right to the tree of life, and may enter in through the gates into the city.

im actually not really sure about this
cause a large mantis will take between 40 mins and up to over 1 hour to finish her molting
thats a logn time without oxygen if it would be true
but when a adult mantis (if its infestet with horsehairworms)
goes into the water it drowns in less then 10 mins when submerged

@@Kurominos1 Does it die because it drowned or because of the combination of trauma and drowning. Who knows, in general insects can survive a long time underwear, some more than a day.

@@Kurominos1 I mean its not quite the same but I know that tarantulas can go for a long time without much oxygen, my baby tarantulas I keep in small vials with no ventilation since the vials are so small any ventilation would cause them to dry out too fast. They can go weeks completely sealed and the only reason I choose to open them up regularly is to prevent mold and check on the slings. Also I assume that some oxygen will diffuse into the semi permeable skin while molting, just not enough to sustain larger sizes which is why the max size of insects is smaller than that of arachnids and land crustaceans.
I generally keep them this way until they are around an inch in size, depending on the species this can take a while as some arid species like those of the genus Aphonopelma grow very slowly and therefore eat very infrequently. Female tarantulas in this genus can live 30+ years and even males can live 6 or more years.

​@@Kurominos1
*Revelation 3:20*
Behold, I stand at the door, and knock: if any man hear my voice, and open the door, I will come in to him, and will sup with him, and he with me.
HEY THERE 🤗 JESUS IS CALLING YOU TODAY. Turn away from your sins, confess, forsake them and live the victorious life. God bless.
Revelation 22:12-14
And, behold, I come quickly; and my reward is with me, to give every man according as his work shall be.
I am Alpha and Omega, the beginning and the end, the first and the last.
Blessed are they that do his commandments, that they may have right to the tree of life, and may enter in through the gates into the city.

Same

especially flaaffy

same I love all the Pokemon references I these videos 😊

I wish I had a exoskeleton

Fr fr

but in the same maner you can take a Beetle and a tarantula who are the same size
drop them from the same height
and the tarantula will get injured but the beetle will not
exoskeletons can differ a lot
spiders,caterpillars and so one have really soft ones
while beetles ,ants etc have fairly sturdy and hard ones

​@@Kurominos1some ants in the genus acromyrmex even have mineral reinforced exoskeletons made of dolomite-like material

This is a bit dishonest, you’re generalizing the exoskeleton of a very heavy bodied, fossorial arthropod that would normally never venture more than a foot above the ground. Those burrowing tarantulas don’t need armored abdomens as they as usually tucked away safe in their burrow, so they can afford to lose the extra weight and it even helps them molt easier. They also grow super massive compared to other arthropods, making their heavy weight much more of an issue when falling, which only happens in captivity with owners lifting their pets high above the ground. In the wild they would never put themselves in a position where they can fall. The exoskeletons of almost any other arthropod are far more durable, able to take large falls without any risk of breakage. Some, like the ironclad beetle, can even withstand being run over by a car with minimal damage.

Yeah they probably could hold their breath long enough as dolphins do

It's likely due to their metabolism. Us vertebrates tend to consume a LOT more oxygen and energy than invertebrates to our muscles' hungrier energy needs, as well as having more complex brains. For mammals, we also have our internal temperature regulation, which consumes SO much energy that the same amount of food needed to feed one lion could feed ten crocodiles.

I would have thought that insects like dragonflies do need a lot of energy and have a high metabolism due to flight. As the currently living species do moult and we do have fossil evidence of huge dragonflies from the carboniferous period, I am not sure if metabolism could be the only reason here. I could be wrong :)

@@w0tch That is a good point regarding dolphins but then doesn't it kind of go against the argument made in the video. I thought the whole point was that a bigger body requires more time for moulting and during moulting we are unable to breathe. And there is not enough oxygen stored away for a big organism to stay alive without breathing. We are basically asking if a dolphin or any other marine mammal can keep enough oxygen for a moulting time period comparable to its body size

Insect respiration isn't entirely passive/osmosis driven, there is still some active transfer (similar to the lungs moving oxygen into the blood vessels) but its a lot lower effort and less required. They can also control their rate of metabolism (basically stop their muscles moving much). Before moulting insects will provide extra energy to their respirator organs so more oxygen is pumped into the body, they then stop all unnecessary motion and moult with as little excess motion as possible.
They essentially take an extra deep breath. There also isn't zero respirating going on whilst moulting. Just inefficient, slower respiration.
So when giant insects were moulting they were able to take much more air into their tracheae (their bodies could also just store lots more oxygen), slow down their metabolism while moulting and still get MUCH more oxygen from the slow respiration than they would in the current environment.

I'd have a heart attack.

After reaching a certain mass, insects become dramatically weaker because the shell has to be thicker, but this thickening reduces the size of muscles that can fit inside it

​@@deadmeme8973Now, if a ant is the size of a rat would it be stronger?

@alphasuperior558 it depends on multiple factors. If you take an ant and increase its size isometrically, it might have stronger jaws but overall it will be weaker. Now, if the ant is adapted for being that size, it might work kind of like a large beetle or giant cricket. So it will be clumsy, slow, but powerful

I’d say “do even mew bro?”

Turtles are reptiles. Its skin and shell is made of layers of scales, the new ones pushing the older ones. Also, the scales fall individually, don't messing with the mobility of the turtle. Also (again 😂), the inner shell is made of bones, they grow the same way than the human teen bones grows.

Great question! It comes down to atmospheric oxygen density versus metabolic rate. Basically, the higher the oxygen level, the more oxygen that can diffuse into the body. Right now, our atmosphere is something like 21% oxygen, but during the Carboniferous period, it was as high as 35 percent! forces.si.edu/atmosphere/02_02_06.html
Also, if your curious - a deep dive into that oxygen constraint: www.ncbi.nlm.nih.gov/pmc/articles/PMC2880098/

​@@MinuteEarthThat article only mentions molting in passing, so anyone seeing this comment might easily miss it, so it might be better to answer directly. To wit: Arthropod tracheae are not entirely passive, just low-pressure; in preparation for molting, they increase respiration and decrease metabolism. Basically, they take a deep breath and then try not to move much while they've got to hold their breath.

​@@tildessmoo To my knowledge this article mentions only mayflies and specifically cloeon dipterum larvae, these are aquatic and poses "gills" now whether these actively diffuse oxygen or simply circulate water idk but they do flap them around while stationary meaning they need to do this to breathe so it makes sense in this specific species molting would hamper breathing. I'm not aware of any info aside this that says insects can not breathe while molting, maybe there is but to state for a fact that just because it causes problems to this specific species which has mobile gills and is freaking aquatic that all insects can not breathe while molting is pretty ignorant.

@@CMZneu For the "can't breathe during molting" part I'm going off of the video we're both commenting on. (I've also seen it elsewhere, along with the fact that insect tracheae are low-pressure but not entirely passive, but not scholarly sources so not much point in linking them.) What I was digging through the paper for is how they _deal with_ not breathing when they molt, which is by taking a deep breath and lowering their metabolic rate beforehand. Which is also what MinuteEarth linked the article for in the first place; I just figured I should put it directly in a comment since it's such a brief throwaway line somewhere in the middle (I already forgot exactly where, and it's only been like a week).

@@tildessmoo It makes sense that normal tracheal respiratory systems they aren't entirely passive, also the flapping of the gills in mayflies is definitely not passive. Hey what about other arthropods not all have tracheae but do have exoskeletons and molt, most extreme example would be coconut crabs, i really doubt those big boys are holding their breath while they change outfits and i'm pretty sure they take their sweet time, definitely hours if not days.

Great Q! The answer is basically yes; water gives them more buoyancy, plus crustaceans use gills rather than trachea so they can diffuse oxygen better. Also the biggest tend to live in colder water and thus have slower metabolisms.

@@MinuteEarth laughs in coconut crabs which are the most massive arthropod on earth and live pretty much entirely on land

Coconut crabs breath with gills on land
same as woodlice
its a diffrent thing then how insects breath @@DJFracus

They can not take credit for that one.
The Comicbook Superhero "Antman" can sometimes grow and then is often called "Giant Man".

Yep link belike give me my hat I've been wearing for 30 yesrs

I think that's actually wrong because you're comparing apples to oranges. If you had the same mass of mice vs elephants, the elephants would require far fewer resources than the mice. Efficiency increases with scale, read economies of scale. It's just that the elephants have more total mass to deal with compared to the mice.

Then imagine how big the ant pile would be.

2:12 looks more like iron treads

​@@sarthaksharma9129No. Iron treads is different. It has a robotic face, doesn't have ears, have a pair of 'spike' on its side, and it has a curled trunk
The Pokemon actually looks like a regular Donphan with mettalic body

​​@@21LazuliIt could be an intermediate step from Donphan to Iron Treads as I see traits from both.

if bugs were that big they would collapse under their own weight, unable to move. then they would promptly suffocate and die. I personally don't really like these comparisons. in my mind they're just fantastical, as in they are fantasy

some insects "breathe" by flexing their abdomen repeatedly. very easy to notice on highly active ones like hornets and wasps. seems not to be as great as having lungs or gills. I do wonder what has stopped them from developing lungs? perhaps the ancient marine arthropods made do without a swim bladder or similar outpouching of the gut? who knows. surely if they could have they would have by now it has been quite some time

also maybe their circulatory system just isn't up to par with ours. we take our 4 chambered hearts for granted. maybe there is just no way to make something like the vertebrate heart and vasculature in that arthropod genome. just speculating wildly

Crabs and hummers also have exoskeletons and they are big. Coconut crab. Surely it could get theoretically bigger , if we bred em that way like dogs. Can breathe on land,needs water to do so. I doubt there's specifically something stopping it it just doesn't happen. No route. The intermediate stage where it would be useless is too long. If everything but insects disssapeared and the niches would get filled, then maybe it would happen.

We'd end up needing far more resources for all of this extra stuff, and evolution really does not like that. If evolution was not a 'give it the old college try barely pass C student', maybe it could be possible, it just won't naturally because of the huge tug on resources! I was wondering this myself, good question.

There's a reason arachnids get bigger than insects: they've got the same semi-passive tracheae, but also a set of accordion-like lungs called "book lungs"!

Look up coconut crabs, they have an organ called branchiostegal lung that allows them to grow into pretty massive sitzes for a terrestrial arthropod.

@@DramaticBloodyBirds true, but evolution doesn’t seem to be survival of the most efficient, either (not even gonna bother with examples I know almost everyone is instantly gonna think of sloths or koalas). It seems to be a roll of the dice and seeing if it sticks. Of course, there's also the fact that from a perspective that takes cold-blooded animals to be standard, warm-bloodedness also seems to be a badly overexpensive (energy-wise) choice, but it does still not only exist but even flourish well in this world. So it seems that if the appropriate mutations occur for the aforementioned advantages to apply to large animals, and the ecosystem can support it, then it's bound to become widespread... All a matter of chance though, nobody knows what might go wrong and result in the whole lineage failing :P

@@tildessmoo I wonder if this system would allow for even greater size, even mega fauna, if it developes into more sophisticated systems like what has happened with vertebrate hearts...

That one goes to our illustrator Arcadi! He drew the cap on that ant in the very first storyboard.

Turtles! Though they usually don't maximize in the strength department (TMNT not withstanding)

There are crustaceans with a lung like structure that are about as close as we are likely to see. While they are relatively large, the benefit of exoskeletons still is subject to square cube law. It gains mass faster than strength as it scales up. Armadillos, turtles and similar have evolved compromise options, but the larger an exoskeleton gets, the more expensive it is to carry around and the less beneficial it is in defense and strength.
When oxygen rates in the atmosphere were higher, insects did grow much larger, but you won't see an elephant sized one.

The 2 main factors are:
Smaller ratio of mass to cross sectional area means lower terminal velocities -> less inpact forces.
And for impacts at the same speeds, the smaller animals have less mass and thus the collision impulse & associated forces will be lower (momentum p = mv, impulse j = Ft = ∆p). This means their tissues areless likely to have their strength overwhelmed and tear apart/shatter.
Basically, throw and ant and an elephant off the empire state building and the elephant hits the ground at 140mph and explodes, the ant then lands next to the gore pile at 4mph and goes crazy about all the food it just found and needs to tell its colony about. (Ignoring all other consequences of these actions, for the hypothetical)

simply, more surface area than volume means more air resistance and slower
less surface area than volume means splat

the biggest thing i leanred about it was back then there where no terrestial (exept some amphibians who stayed most of theyr time in water) verdebrates who would competet with these giant inverdebrates
so they had all the food and stuff for themself
then you can be gigantic cause nothign will bother you
but as soon as somethign else shows up and competes with you for food and space
you could consider taking other places ,,eat other food
or for inverdibrates ..just get smaller and dont competet with verdebrates at all

it’d probably get eaten while molting

I mean, generally. There are some pretty large spiders and crabs, but they are definitely exceptions as opposed to the rule, and there are always exceptions.

also back then there whrere not many verdebrates to competet with them
jsut to be clear ,,, crabs and stuff also have exosceletons
and lobsters get quite large
and if we take a coconut crab ,,, this guys get gigantic and life 95 % of theyr life entirely on land

That too, competition is another thing limiting their size
Very true, and there are still some other arthropods that manage to get fairly large, like the goliath beetle and some tarantulas

yep the better these inverdebrates are at competing defending themself agaisnt verdebrates the larger they can get
like giant centipedes who can hunt mice,frogs ,snakes and bats @@garg4531

No

Hmmmm... a hypothetical video exploring the possibilities could be fun.