Leading edge science recognizes the multi-dimensional interface characteristics of certain aluminum alloys. In addition, aluminum is undisturbed by electromagnetic interference. Its sustain is significantly longer than steel forks made to the same pitch. Aluminum is chosen for its tonal beauty and quality of sound. They are superior for their ability to deliver superb tone quality, lengthy sustain, and beautiful harmonic overtones. The tuning forks are made of a special sonically improved and polarized aluminum alloy. Others like to use them on and around their body, often by placing them on or near acupressure or meridian points and chakra points.
Many people love to sing and tone with the tuning forks. For those explorers of the ancient science of alphabet-number correlations known as Gematria, or Alphanumerics, we make tuning forks to numerical correspondences from Greek, Hebrew, and other languages and sacred texts.
These tuning fork sets are very unique in that they are backed by years of scientific and historical research into the unified field of sound, Sacred Geometry, color, ancient music traditions, and the harmonic proportions found in nature. It is like saying to the universe “let me hear and feel you more closely as we play in the Music of the Spheres.” These special tuning fork combinations assist people in becoming more attuned to the vibratory nature of our magnificent universe. Place your headphones on the affected area on your body. Keep reading to find out whether a tuning fork can make your teeth explode.The most well researched frequencies in the field. Due to cost considerations, however, most modern tuning forks are made out of stainless steel. Really soft metals like tin, gold and lead, meanwhile, won't make any noise at all. Soft metals like brass have a low, dull pitch. Dense metals like copper and steel vibrate with a crisp, high pitch. You can also adjust the pitch of a tuning fork by making it out of different materials. If someone ever finds a hammer big enough to hit it, the sound would most likely be too low to be heard by human ears. The largest tuning fork in the world, by the way, is a 45-foot (13.7-meter) sculpture in Berkeley, Calif. A loose string, on the other hand, takes longer to shudder back and forth, resulting in a lower tone. Without much room to wobble, a tight string vibrates quickly. It's the same principle as strings on a guitar. The smaller a tine, the less distance it has to move, and the faster it will be able to vibrate. To mimic the lowest key, on the other hand, it would only need to vibrate at 28 Hz.īut how do you adjust the speed at which a tuning fork vibrates? Well, first, you could adjust the length of your tuning fork. For instance, for a tuning fork to mimic the top key on a piano, it needs to vibrate at 4,000 Hz. The faster a tuning fork's frequency, the higher the pitch of the note it plays. The result is a steady collection of rarefactions and compressions that, together, form a sound wave. When the tines snap back toward each other, they suck surrounding air molecules apart, forming small, low-pressure areas known as rarefactions.
When a tuning fork's tines are moving away from one another, it pushes surrounding air molecules together, forming small, high-pressure areas known as compressions. The way a tuning fork's vibrations interact with the surrounding air is what causes sound to form.
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