Einstein Speaks!: October 2010

Tachyon

According to Einstein's Special Theory of Relativity, it is possible to go slower than light and faster than light, but it is impossible to go at the speed of light. Also, there is a particle called a tachyon which is supposed to go faster than light.

Tachyons are a putative class of particles which able to travel faster than the speed of light. Tachyons were first proposed by physicist Arnold Sommerfeld, and named by Gerald Feinberg. The word tachyon derives from the Greek (tachus), meaning "speedy." Tachyons have the strange properties that, when they lose energy, they gain speed. Consequently, when tachyons gain energy, they slow down. The slowest speed possible for tachyons is the speed of light.

Tachyons appear to violate causality (the so-called causality problem), since they could be sent to the past under the assumption that the principle of special relativity is a true law of nature, thus generating a real unavoidable time paradox (Maiorino and Rodrigues 1999). Therefore, it seems unavoidable that if tachyons exist, the principle of special relativity must be false, and there exists a unique time order for all observers in the universe independent of their state of motion.

Tachyons can be assigned properties of normal matter such as spin, as well as an antiparticle (the antitachyon). And amazingly, modern presentations of tachyon theory actually allow tachyons to actually have real mass (Recami 1996).

It has been proposed that tachyons could be produced from high-energy particle collisions, and tachyon searches have been undertaken in cosmic rays. Cosmic rays hit the Earth's atmosphere with high energy (some of them with speed almost 99.99% of the speed of light) making several collisions with the molecules in the atmosphere. The particles made by this collision interact with the air, creating even more particles in a phenomenon known as a cosmic ray shower. In 1973, using a large collection of particle detectors, Philip Crough and Roger Clay identified a putative superluminal particle in an air shower, although this result has never been reproduced.

Pi

Why is Pi important?

Pi is perhaps the most important mathematical constant. It appears in various formulas throughout math and science in fields as diverse as physics, statistics, and sociology. Although pi is defined in terms of the geometry of a circle, most applications of this number do not directly involve circles.

Since ancient times, people have been fascinated by pi. This is hardly a surprise, since the circle is one of the most basic, but nevertheless fascinating, geometric figures. Pi is defined as the ratio of the circumference to the diameter of a circle. (Any circle will work, since all circles are similar.) Rounded to 10 decimal places, its value is 3.1415926536.

Part of what makes pi fascinating is that it appears in several other formulas involving circles or spheres. For instance, the area of a circle is equal to pi times the square of its radius. Further, the surface area of a sphere is equal to 4 pi times the square of its radius, and its volume is equal to 4/3 pi times the cube of its radius. In fact, the formulas for the content of all higher dimensional analogs of the sphere also involve pi.

As mentioned, pi also appears in many formulas not directly involving circles or spheres. For instance, the periods of all the trigonometric functions are either equal to pi or 2 pi. Although trig functions may be defined in terms of a circle, they are usually used in contexts not directly involving circles. Another place pi is widely used is in the normal distribution, which is commonly used in statistics, whose formula involves the square root of pi.

The computation of pi has a long and fascinating history. Some of the most elaborate mathematical methods have been used in devising various formulas for pi. By the late 19th century, its value had been computed by hand to several hundred decimal places. Since the dawn of the computer age in the mid-20th century, the number of calculated digits of pi has skyrocketed. Since 2002, its value has been known to over a trillion decimal places - enough to fill a large library!

Part of the reason some mathematicians are fascinated with calculating so many digits of pi is in order to look for patterns in its digits. So far, no obvious ones have been found. It has been conjectured that pi is a normal number, meaning that every finite pattern of digits in every base occurs infinitely often in pi with the same frequency which would be expected if the digits were random.

In 1995, an amazing formula was found for pi, which allows one to compute hexadecimal (base 16) digits of pi without having to compute any previous digits. This formula was used in 2000 to compute the quadrillionth (10^15th) hexadecimal digit of pi, which happens to be 0. Several similar formulas have since been discovered, some in other bases, but none in base 10 have yet been found.

Mr. Slxpluvs in Yahoo! Answers answers:

Pi is involved with the length of the diameter a circle and it's radius. It sounds like you're in geometry, where just about all pi does is figure out the area of a circle. Later, in calculus, pi is used to go between different types of coordinates (from the grids you're used to into a system of circles that all have the same center (concentric)). There are a lot of math problems that would be almost impossible without using pi.
This doesn't sound like something that you'd use in everyday life, but it might be important when talking to someone who does work with this sort of math. Lawyers, secretaries, scientists, doctors, electricians, plumbers, warehouse workers and many other professions have to deal with (and understand!) people who use pi in everyday work. In geometry class, it's not as important to build skills you plan to use, but to understand the language of the people who do use similar (but more complicated) skills.

Want to memorize Pi until 9th decimal place?

here’s a solution:

If you need to remember Pi, just count the letters in each word in the sentence: "May I have a large container of coffee?" If you get the coffee and say "Thank you," you get two more decimal places. [3.141592653...]