> the need to stay warm sets a floor for the body size of oceanic mammals, while the need to eat sets a ceiling. And the gap between them, Gearty found, is surprisingly narrow—and far more so than on land.
Interesting. If the range is so narrow for mammals, how did Dinosaurs get big?
1. The snippet you're quoting is about marine mammals
2. Dinosaurs were not aquatic
3. The biggest aquatic reptiles were much smaller than modern whales (plesiosaurs and ichthyosaurs topped up around 15m long and 2 tons, which is 2x the length but 1/3rd the weight of a male Orca and nowhere near large whale league)
4. Dinosaurs weren't necessarily homeotherms and may have thus had a larger (but lower) range of efficiency
5. As the snippet notes the upper bound has to do with food limitations, and large sauropods largely evolved ways to mow down ridiculous surfaces (and thus amounts of food), which could have combined with higher plant growth/density from higher O2 levels to put a higher cap on food issues
Your point of #3 is probably wrong. It’s harder to get fossils of aquatic creatures so there’s likely a vast number of animals that we will never know about. Saying with certainty that the biggest aquatic reptiles were smaller than whales is a logical fallacy. Only the ones we know about are smaller but we don’t know if there ever were, we might get lucky and find a fossil that is larger.
Dinosaurs were not mammals. The jury is still out on whether they were warm blooded (but most people agree that not quite as warm-blooded as mammals). The upper limit on size (according to the article) is defined by food availability and energy consumption, so I would guess food was simply more plentiful, or their energy demands were lower (due to lower core temperature). Thus they grew bigger.
Also, average ambient temperatures in the Jurassic were significantly higher than today - up to 8C warmer according to some estimates, and even higher in the Cretaceous.
Warm blood was less of a requirement for dinosaurs than it would be today.
I don't understand how mammalian evolution worked through this period. Temperatures rose even further after the KT crash, so there would be no evolutionary benefit to being warm blooded. And yet - here we are.
> Also, average ambient temperatures in the Jurassic were significantly higher than today - up to 8C warmer according to some estimates, and even higher in the Cretaceous.
Note that this is not necessarily an advantage for large land-bound animals, an elephant's biggest thermal issue is getting rid of heat not producing it.
Surely there degree (no pun intended) to which a species can be"warm blooded" is a gradient. Even fractional presence of temperature regulation could have allowed for species to live in colder parts of the planet.
My recollection of theory is many mammals (that we know survived to evolve) at the time of the KT crash were tiny, and burrowers and able to use both of these (less exposure to damage from initial strike and need less resources to survive/procreate) to out survive the dinosaurs.
The variable he's not talking about in that equation is body temperature. If you cut the difference between body temp and ambient temp, you proportionally cut energy needed to maintain that difference. I wonder what fundamental physiological force is keeping these mammals from evolving a lower body temperature ...
Isn't it the temperature needed for enzymes to properly work their metabolic magic (1) temperature helps reaction rates 2) enzymes need a certain temperature to maintain their shapes)
It affects peak efficiency of enzymatic reactions, but that's a tradeoff because now the species has to maintain internal temperature within a narrow band or they die. A common alternative is to allow more fluctuation of core temperature at the cost of a lower overall efficiency. That's basically mammals and birds versus reptiles and fishes.
Not just less food - they produced less heat. A mammal the size of a dinosaur would not have enough surface area to get rid of the internally-produced heat.
Many reasons, but one reason cited for huge dragonfly-like creatures was the richer oxygen content of the air, allowing more primitive lung-like systems to support larger bodies.
But birds need more food than mammals. And birds are a group of dinosaurs. Under some classification systems dinosaurs (including birds) are in the reptile tree, but in others they aren't.
Rexxar's point was about mechanisms of locomotion and body size. While we generally expect birds to have a faster metabolism than mammals because they're small and because flying takes so much energy, the reverse would probably be the case when comparing ostriches and bats. The ostrich is a 250-pound non-flying bird, and bats are very light flying mammals. In that case, we expect the mammal to have the higher metabolism.
I've also wondered if non-flying birds defecate less often, and flying mammals more often. I always assumed that birds emptied out so frequently because it's important to keep your weight down if you're flying, and much less important if you're walking.
Flying takes a ton of energy. Hummingbirds are an extreme example but they have the highest metabolism of any animal and can eat multiples of their body weight in food each day
I wonder if this could be related to the size of pacific islanders. I remember reading somewhere that is was somewhat of a paradox how people living on small islands for so long became so large.
People from the pacific have been long been adept fisherman using techniques such as deep diving spearfishing.
Pacific islanders are also enormous. They're overrepresented in the NFL for a good reason. Anyone who has ever met a family of Samoans knows that these people have very different genes.
Interestingly, species will both grow or shrink, depending on their initial niche before becoming an island population, as well as local resource availability.
I've heard a different explanation (from Jared Diamond): it's because of the introduction and proliferation of high calorie, cheap foods. You see this in many 3rd world countries (e.g. central/south America, many poor towns in the US, etc) that have easy access to type of food.
Have a look at what the ancestors of the current Pacific Islanders were doing for a few thousand years. They lived in an environment where growing food is easy and starvation almost unknown, contagious disease minimal, yet the population static. Which of the four horsemen was responsible?
>And they evolved a foraging technique called lunge feeding, where they accelerate into a shoal of prey, open their ballooning mouths, and suck in vast volumes of water.
interesting article, but there’s a small mistake. i don’t think it’s accurate to say that sea otters spend a lot of time on land. i think it’s actually fairly rare for them to go on land.
It's borderline, but still makes perfect sense. In academia, more seasoned professors generally fall into a higher pay grade. Hence he's argued with people that in theory have more experience than he (or she).
And expressions out of context make absolutely no sense. His usage was borderline but still applies.
Perhaps, rather than sit up on that high horse, you should come back down here and figure out that explaining an expression like that is HELPFUL in a discussion full of people from across the world that may or may not have ever heard it.
https://en.wikipedia.org/wiki/Cope%27s_rule
not as an explanation of why whales are big, just a sort of interesting bit of related history.