Just as the force of gravity limits the maximum size of Earth’s mountains, so it limits the range of forms that natural selection can create, restricting the overall size of organisms that live on its surface. Four hundred years ago, Galileo Galilei explored the factors that define how big an animal can be; in common with Kepler and his snowflakes, he was operating at the edge of knowledge and ahead of his time. Discourses and Mathematical Demonstrations Relating to Two Sciences was Galileo’s final book, written whilst under house arrest and published in 1638 by the Dutch publisher Lodewijk Elzevir, because no country in the grip of the Inquisition would touch it. Any scientist reading this book will recognise the name: the Elsevier company, which took the publisher’s name, is today a leading scientific publisher. Galileo’s book is written in the style of a conversation between three men, Simplicio, Sagredo and Salviati, who each represent the author at a different age, and with a different level of knowledge. The characters wander from question to question during a conversation lasting four days, discussing and debating each subject before moving on to the next. The book has something of the voyeuristic pleasure of overhearing a conversation on a park bench – albeit in a park frequented by unusually thoughtful individuals. Galileo covers large swathes of the physics of the day, including a critical look at Aristotelian physics, accelerated motion, the motion of projectiles and the nature of infinity. His investigations also turned to the strength of materials and the limits placed on the size and form of structures, both animate and inanimate, by the laws of Nature.
From what has already been demonstrated, you can plainly see the impossibility of increasing the size of structures to vast dimensions, either in art or in Nature. Likewise the impossibility of building ships, palaces or temples of enormous size in such a way that their oars, yards, beams, iron-bolts and, in short, all their other parts will hold together. Nor can Nature produce trees of extraordinary size, because the branches would break under their own weight; so also it would be impossible to build up the bony structures of men, horses or other animals so as to hold together and perform their normal functions if these animals were to be increased enormously in height. For this increase in height can be accomplished only by employing a material which is harder and stronger than usual, or by enlarging the size of the bones, thus changing their shape until their form and appearance suggest a monstrosity.
Galileo states, for the first time, the relationship between volume and area, known today as the square–cube law; as an object grows in size, the volume grows faster than the surface area. Consider the example of a cube of sides measuring 2cm. The surface area is 6 x 2 x 2 = 24cm2. The volume is 2 x 2 x 2 = 8cm3. If we double the length of the sides, the surface area is 96cm2 and the volume is 64cm3. Double the length of the sides again and the surface area increases to 384cm2 whilst the volume is 512cm3. And so on.
This means that, as animals get larger, their volume, and therefore their mass, increases more rapidly than their surface area and the cross-sectional area of their bones. The consequence of this is that animals can’t simply be ‘scaled up’ in size. A mouse can’t be expanded to the size of an elephant because its skeleton would give way; that’s why an elephant has thicker legs relative to the rest of its body than a mouse. This ultimately places a fundamental limit on the maximum size of living things on land; the structural strength of bone, or wood in the case of trees, limits the mass of the organism in the same way that the structural strength of the rocks of the Earth’s crust limits the size of a mountain. On Mars, elephants could have thinner legs.
Galileo realised there was an exception to this rule. Whereas gravity imposes a limit to the size and shape of animals on land, the constraints placed on living things by physical laws are different in water. Marine animals float, which means the effects of gravity are not relevant. With the necessity for strong bones to support their weight removed, their forms are freed from this particular constraint. Here is how Simplicio, Sagredo and Salviati put it, from their metaphorical park bench. I can’t help but hear them as a sort of three-way Renaissance version of Pete and Dud…
Simplicio: This may be so; but I am led to doubt it on account of the enormous size reached by certain fish, such as the whale which, I understand, is ten times as large as an elephant; yet they all support themselves.
You read that in a Dagenham accent, didn’t you?
Simplicio: A very shrewd objection! And now, in reply, tell me whether you have ever seen fish stand motionless at will under water, neither descending to the bottom nor rising to the top, without the exertion of force by swimming?
Simplicio: In aquatic animals therefore circumstances are just reversed from what they are with land animals inasmuch as, in the latter, the bones sustain not only their own weight but also that of the flesh, while in the former it is the flesh which supports not only its own weight but also that of the bones. We must therefore cease to wonder why these enormously large animals inhabit the water rather than the land, that is to say, the air.
Sagredo: I am convinced and I only wish to add that what we call land animals ought really to be called air animals, seeing that they live in the air, are surrounded by air, and breathe air.
Salviati: I have enjoyed Simplicio’s discussion, including both the question raised and its answer. Moreover I can easily understand that one of these giant fish, if pulled ashore, would not perhaps sustain itself for any great length of time, but would be crushed under its own mass as soon as the connections between the bones gave way.
Freed from the tyranny of gravity, aquatic animals can be larger than their land-based cousins, but they don’t have complete freedom from the laws of physics.
Every winter the warm waters of Florida are home to one of Nature’s apparently less elegant shapes. The caveat is important, because the clumsy-looking manatee is as well adapted to its environment as the most aesthetically refined butterfly. The West Indian manatee is the largest living example in the Sirenia order of wholly aquatic, herbivorous mammals. A less-than-taxonomically accurate but nonetheless accurate image can be conjured by imagining a 4m-long aquatic cow with no legs, unhurriedly grazing on the sea grasses that grow in the slow-moving waterways along the Floridian coast.
During the summer months the manatee roam as far north as Massachusetts, but as the seasonal temperatures fall they must return to warmer seas. They are unable to survive in waters below 20 degrees Celsius for long. The need for warm winter waters drives the manatees to congregate in large groups around the warm springs that dot the Florida coast, where temperatures remain above 22 degrees Celsius all year round. They also take advantage of human activity, gathering in the outflows of power plants near Apollo Beach and Fort Myers. The manatee is a strange animal indeed; it is more closely related to an elephant than to the other marine mammals – they share a common ancestor around 60 million years ago, not long after the dinosaurs became extinct. The ancestor may have looked like the modern-day hyrax, which at around 50cm in length looks nothing like an elephant or a manatee; 60 million years is plenty of time for the un-directed tinkering sieve of natural selection to sculpt an animal to take advantage of an environmental niche.
The elephant’s niche is to be the biggest land animal, which undoubtedly gives it an advantage against predators, but it also displays the anatomical evidence of a tussle with gravity. As dictated by the square-cube law, the elephant has evolved with exceptionally thick legs to support its substantial weight. There is also the matter of cooling; heat escapes from an organism through its surface. As the volume of the animal increases, so does the amount of heat it generates, but its surface area decreases in proportion, according to the square-cube law. This presents a problem for a land-dwelling animal, and the elephant has solved it by developing an ingenious cooling system – its big ears.
The manatee filled a different niche. The transition from a coastal land-dweller to an aquatic mammal saw their front limbs