Uncanny physics of comic book superheroes

Can you teach a physics class with only comic books to illustrate the principles? University of Minnesota physics professor James Kakalios has been doing it since 1995, when he explained the principle of conservation of momentum by calculating the force of Spider-Man’s web when it snagged the superhero’s girlfriend as she plummeted from a great height. “Comic books get their science right more often than one would expect,” said the gregarious Kakalios. “I was able to find examples in superhero comic books of the correct descriptions of basic physical principles for a wide range of topics, including classical mechanics, electricity and magnetism, and even quantum physics.”From the University of Minnesota:Professor to describe ‘uncanny physics of comic book superheroes’

Can you teach a physics class with only comic books to illustrate the principles? University of Minnesota physics professor James Kakalios has been doing it since 1995, when he explained the principle of conservation of momentum by calculating the force of Spider-Man’s web when it snagged the superhero’s girlfriend as she plummeted from a great height.

Kakalios will describe a freshman seminar class he teaches, “Physics of Comic Books,” at 11 a.m. Sunday, Feb. 15, during the American Association for the Advancement of Science meeting in Seattle. His talk is part of the symposium “Pop Physics: The Interface Between Hard Science and Popular Culture,” one of two symposia in the Science, Entertainment and the Media category.

“Comic books get their science right more often than one would expect,” said the gregarious Kakalios. “I was able to find examples in superhero comic books of the correct descriptions of basic physical principles for a wide range of topics, including classical mechanics, electricity and magnetism, and even quantum physics.”

Take, for example, the strength of Superman. To leap a 30-story building in a single bound, Superman’s leg muscles must produce nearly 6,000 pounds of force while jumping, Kakalios calculates. The Man of Steel was that strong because he was designed to resist Krypton’s powerful gravity. But for a planet with an Earth-like surface to have so much stronger gravity, it would need neutron star material in its core–a highly unstable situation. No wonder the planet exploded. Other topics considered in Kakalios’ class include:

# Is it possible to read minds as Prof. X of the X-Men does?
# If Spider-Man’s webbing is as strong as real spider silk, could it support his weight as he swings between buildings?
# Can the mutant master of magnetism Magneto levitate people using the iron in their blood?
# If you could run as fast as the Flash, could you run up the side of a building or across the ocean, and how often would you need to eat?

“Once the physical concepts such as forces and motion, conservation of energy, electricity and magnetisms, and elementary quantum mechanics are introduced to answer these and other questions, their real-world applications to automobile airbags, cell phones, nanotechnology and black hole formation are explained,” said Kakalios. “The students in this class ranged from engineering to history majors, and while not all were comic book fans, they all found it an engaging and entertaining way to learn critical thinking and basic physics concepts.”


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