Heimdall
New member
As an electric current goes through a quartz crystal in a watch, it will vibrate at the specific frequency of the quartz, always giving the correct time. This is called the "Piezoelectric effect". In the same way our chakras will vibrate their base metals at their specific optimal frequency when they are fully open, correctly aligned, and receive the correct amount of bioenergy. The different colors of the chakras, are their energy vibrated at their particular frequency, as seen in the visible light spectrum.
Different metals can vibrate at different frequencies due to their unique molecular structures and properties. The design and shape of the metal also influence the specific frequencies at which they vibrate.
Common Metals and Their Vibration Characteristics:
Metal Density Typical Vibration Frequency Range
(G/CM3)
SILVER 10.49 Higher frequencies (e.g., 200-300 Hz)
IRON 7.87 Lower frequencies (e.g., 100 200 Hz)
LEAD 11.34 Lower frequencies (e.g., 50-150 Hz)
Different metals can vibrate at different frequencies due to their unique molecular structures and properties. The design and shape of the metal also influence the specific frequencies at which they vibrate.
The primary factors that influence these frequencies include:
- Material Properties: Each metal has unique physical properties, such as density and elasticity, which affect how it vibrates.
- Molecular Structure: Metals have a well-organized crystal lattice structure. This structure allows for efficient transmission of vibrations, leading to distinct vibrational characteristics.
- Shape and Size: The dimensions and shape of a metal object, such as a tuning fork or a rod (chakra), can also determine its natural frequency of vibration.
Common Metals and Their Vibration Characteristics:
Metal Density Typical Vibration Frequency Range
(G/CM3)
SILVER 10.49 Higher frequencies (e.g., 200-300 Hz)
IRON 7.87 Lower frequencies (e.g., 100 200 Hz)
LEAD 11.34 Lower frequencies (e.g., 50-150 Hz)
