Nonfiction is the New Black
French aristocrat Baron Pierre de Coubertin (1863–1937) was a scholar of ancient Greece. With the sting of France’s defeat in the Franco-Prussian War in 1871 in his mind, he believed that strong young men were better able to fight wars. He especially admired the English school system, in which academic learning and physical fitness worked side by side. His studies convinced him that this harmony of mind and body originated in the gymnasia of ancient Greece.
This harmony reached its highest level in the Olympics, which originated in the Greek village of Olympia in 776 BCE. They continued every four years until being suppressed in 393 CE as a pagan ritual. The Games began with a single event—a sprint of about 200 yards—and eventually encompassed a wide variety of sports. The Games were so prestigious among the Greeks that winners were set up for the rest of their lives.
To reintroduce this sporting ideal into the modern world, de Coubertin proposed reviving the Olympics. Olympia was too small and too remote to serve as the site, so de Coubertin and his associates chose Athens, the Greek capital and largest city, instead.
Two hundred forty one athletes from 14 nations descended on Athens in April 1896 to compete in nine sports: track and field, cycling, fencing, gymnastics, shooting, swimming, tennis, weightlifting, and wrestling. Only track and wrestling had been part of the ancient Olympics.
Another event not in the original Games was the marathon run. Organizers wanted a signature event to recall the glory of ancient Greece. In 490 BCE, a messenger supposedly ran from the plain of Marathon to Athens to announce a stunning victory over a much larger invading Persian army. So the route of the first-ever “marathon race” was about 22 miles, from the battlefield to the Olympic Stadium. The winner, Spiridon Loues, had done no formal training. His occupation of water carrier in the hills overlooking Athens gave him considerable stamina and he became an instant national hero. A prominent Greek industrialist reportedly offered his daughter in marriage. Loues was already engaged. He settled for a horse and cart for his business instead.
Today the Olympics are regarded as the premier sporting event in the world. In the 2012 Olympics in London, England, 10,768 athletes from 204 nations competed in 26 sports. Nearly 4,800 were women—something that never happened in the original Olympics. All the entrants then were men.
Jim Whiting has written a book on the ancient Greek writer Herodotus, who is known as the father of history. Herodotus provides most of what is known about one of the most important periods in world history. It began in 490 BCE. An invading Persian army was defeated at the Battle of Marathon. It concluded just over ten years later with Greek victories at Salamis and Plataea. The triumph allowed the Greeks to develop ideas and institutions in politics, economics, science, and even sports. These are the bases for how the Western world thinks and acts today. For more information, click here.
MLA 8 Citation
Whiting, Jim. "Reviving the Olympics." Nonfiction Minute, iNK Think Tank, 20
Feb. 2018, www.nonfictionminute.org/the-nonfiction-minute/
When you think of the Olympics you think of the sports: Speed skating, Bobsled. Snowboarding. Track, Gymnastics. Swimming. Tennis. Just to name a few.
You may even think about some of the Olympians: Snowboarders Shaun White and Kelly Clark. Speed skater Apollo Ohno. Swimmers Michael Phelps and Katie Ledecky. Or even gymnast Simone Biles and sprinter Usain Bolt.
But do you ever think about the science behind each sport? You should. Math and physics play a huge part in every part in the Olympics. Think about it. One of the most basic forces, friction, is a factor in everything an athlete does. What is friction? It’s the force that pushes back on you as you swim through the water or run through the air. Friction not only affects an athlete, but also the object they may be throwing, hitting, or kicking—like a baseball, a tennis ball, or a soccer ball.
Movement of any kind deals with physics of air flow, engineering design, and (unfortunately) sometimes collision. The verdict? Athletes need to know a LOT of science to do well in their sports.
Science is not just found in the activities themselves but also in the equipment they use and clothes they wear. Most of today’s superstar athletes rely on clothing and equipment enhanced with nanotechnology. What is nanotechnology? Nanotechnology is the science of the super small—microscopic even. One nanowire is 1,000 time thinner than a single strand of human hair. Now that is SMALL! Materials made with nanotechnology are stronger, more durable, and yet lighter and more flexible.
Nanotechnology produces swimsuits that allow the athlete to glide through the water faster, golf clubs that hit the ball farther, and tennis rackets that flex more easily to provide the hard smash across the net. This innovative new technology has already been used in the Olympics. In 2008, swimmers Michael Phelps and Natalie Coughlin wore swimsuits that were created with nanofibers. These nanofibers are woven tightly so that the swimmer’s bodies become more streamlined (like a shark!) allowing them to glide through the water faster. In the 2014 winter Olympics, the U.S. speed skaters wore specially created vented suits (like the swimsuits—to reduce drag), and in the 2018 winter Olympics, the USA Snowboarders will be wearing snow gear inspired by the space program.
Nanotechnology is a cutting-edge science that is changing the world of sports—and in particular the Olympics— as we know it. Will you make nanotechnology part of your game?
The LZR Racer is a line of completion swimsuits manufactured by Speedo using a high-technology swimwear fabric. In March 2008, athletes wearing the LZR Racer broke 13 swimming world records. Much like other suits used for high competition racing, LZR Racers allow for better oxygen flow to the muscles, and hold the body in a more hydrodynamic position, while repelling water and increasing flexibility. Kathy Barnstorff via Wikimedia Commons
Serena Williams uses a nanotech racket and Phil Mickelson uses nanotech technology in his game. Seems to be going well for both of them. (l) Wikimedia Commons (R) Photo by Siyi Chen via Wikimedia Commons
A graphic highlighting all of the ways nanotechnology enhances the effectiveness of sports equipment. Nanowerk via Wikimedia
You would have to increase a carbon nanotube x100,000 to make it the size of a strand of hair.
Want to know more? Jennifer Swanson's Super Gear: Nanotechnology and Sports Team Up was listed as one of the 2016 Best STEM Books by the National Science Teachers Association.
Colorfully illustrated by photos, this book introduces "the science of the very small" as applied to sports equipment and clothing.
MLA 8 Citation
Swanson, Jennifer. "The Science Behind the Olympics." Nonfiction Minute, iNK
Think Tank, 7 Feb. 2018, www.nonfictionminute.org/the-nonfiction-minute/