Crystals and Physics
Physical Properties and Effects of Crystals
Crystalline Structures, Crystal Lattices
Minerals and gemstones were already referred to as crystals by the Greeks because their purity and clarity made them appear like frozen ice. Properties that were confirmed 2,000 years later with the lattice structure of crystal systems, according to which they are classified.
These internal degrees of order arise from the different conditions under which crystals form and subsequently determine their shape, hardness, brittleness, transparency, and surface texture.
They can be trigonal (triangular), cubic (square), tetragonal (quadrilateral), hexagonal (hexagonal), rhombic (diamond-shaped), monoclinic (parallelogram-shaped), or triclinic (trapezoidal).
There are also amorphous minerals that have not had time to form crystals (e.g., opals, amber, obsidian).
In analytical crystal healing, an interesting symmetry is considered between the conditions under which the respective crystal structure was formed and the patient’s lifestyle (see Michael Gienger: Die Steinheilkunde, Handbuch).
For his writings on the lattice theory of crystals, “The Dynamics of Crystal Lattices,” Prof. Max Born received the Nobel Prize in Physics in 1954, thus laying the foundation for the study that interests us here: the effects and properties of crystal lattices and their frequency effects, including for therapy.
Max Born demonstrated that the first quality of the spatial lattice is crucial for the following effects:
- Elasticity (ability to move and return to the original position, triggered by internal and external forces)
- Piezoelectricity (mechanical deformation of the crystals generates electrical charge and vice versa)
- Dielectric excitability and dispersion (electrical excitability also by light waves, vibrational resonance)
- Specific heat (this arises from the resonant movement of the atoms according to the elastic eigenvibrations and light waves, as well as possibly acoustic waves in the crystal)
- Optical effects: formal crystal optics (propagation at the speed of light) and optical activity (birefringence in several directions, etc.)
At least since the frequency measurement of individual cells and organs, it has been known that the countless crystal structures with atoms as building blocks, even in the body of a living being, exhibit different eigenfrequencies and vibration patterns.
If we consider this in conjunction with the conclusion drawn from point 4 above, which Max Born draws from the specific heat of crystal lattices, the decision to work specifically with crystals in body therapy also becomes obvious.
In addition, we can derive far-reaching therapeutic possibilities from point 5, the laws of optics, i.e., the refraction, resonance, and propagation of light in the crystal lattice, its color and prism effects.
Especially when viewed in the context of the biophoton activity of our cells:
Crystal Optics and BioPhotons
Prof. Dr. Fritz Albert Popp has built a crucial bridge here with his research findings on biophotons: “The Light in Our Cells,” “Biophotons – New Horizons in Medicine.”
Together with A.V. Budagovsky, Alexander Gurwitsch, Georges Lakhovsky, and Luc Montaignier, he provided evidence of cellular oscillation.
Biophotons are at the source of life. They are weak, coherent, electromagnetic emissions continuously emitted by living cells (from their DNA); their wavelengths are in the optical range.
Through their interference, through the superposition of light waves (constructive, destructive, or harmonizing), electromagnetic communication occurs in living organisms. This allows countless amounts of information to be transmitted. The endless spectral range of the wavelengths present in nature and used liberally enables life in the biophoton field: through their resonance, individual organs, organelles, cells, and cell groups can be controlled and influenced (F.A. Popp, “Biophotons – New Horizons in Medicine” Karl F. Haug 2006, Chapter 4.3), and signals/vibrations can be transmitted between the organism and its environment, as well as within each cell and cell group.
Biophotons control in real time, thus representing the fastest means of information and stimulus transmission between nerve cells, organs, organ parts, and cell organelles, alongside the familiar chemical messengers, hormones, and neurotransmitters. They thus ensure repair, immune stimulation, growth, and biological rhythms. The smallest number of photons in the cells is sufficient to take over the entire regulatory processes.
From them, shape, form, and function emerge according to holographic and fractal principles. Field and matter are connected through feedback.
As an antenna system for biophotons, light pulses, and energy within cells and organs, as well as externally (the body’s own radiation source), our DNA functions like our telomeres (the ends of the chromosomes that determine our aging/lifespan) due to its bipolar structure of individual spiral bands.
Our DNA, as an organic superconductor, receives and transmits and is therefore also called a “morphogenetic field initiator.”
The natural frequency of DNA corresponds to the resonant frequency of the Earth’s electromagnetic fields as a carrier frequency. This corresponds to a wavelength of 2 m (=length of DNA); 8 Hz is usually imprinted on it (which in turn corresponds to the so-called “alpha state” created by brain waves).
If gemstones and crystals are worn on the body, the following physical effects also result from Max Born’s fifth conclusion: we can use the crystal as an (inter)active carrier and generator (see also Prof. Gariajew’s “DNA as an Antenna” Wave Genetics – “Restorative Music” for the Cell).
Due to the weak electrical forces in the crystal lattice, incoming light waves are not simply reflected by the crystal, but are also emitted into the body through birefringence. The more intense the birefringence, the more strongly the crystal’s natural frequencies can be excited to resonance by light.
The frequencies of these waves are specific and characteristic of the crystal lattice vibration or vibrational complex (a multitude of frequencies).
Crystals and Physics
Physical Properties and Effects of Crystals
Crystalline Structures, Crystal Lattices
Minerals and gemstones were already referred to as crystals by the Greeks because their purity and clarity made them appear like frozen ice. Properties that were confirmed 2,000 years later with the lattice structure of crystal systems, according to which they are classified.
These internal degrees of order arise from the different conditions under which crystals form and subsequently determine their shape, hardness, brittleness, transparency, and surface texture.
They can be trigonal (triangular), cubic (square), tetragonal (quadrilateral), hexagonal (hexagonal), rhombic (diamond-shaped), monoclinic (parallelogram-shaped), or triclinic (trapezoidal).
There are also amorphous minerals that have not had time to form crystals (e.g., opals, amber, obsidian).
In analytical crystal healing, an interesting symmetry is considered between the conditions under which the respective crystal structure was formed and the patient’s lifestyle (see Michael Gienger: Die Steinheilkunde, Handbuch).
For his writings on the lattice theory of crystals, “The Dynamics of Crystal Lattices,” Prof. Max Born received the Nobel Prize in Physics in 1954, thus laying the foundation for the study that interests us here: the effects and properties of crystal lattices and their frequency effects, including for therapy.
Max Born demonstrated that the first quality of the spatial lattice is crucial for the following effects:
- Elasticity (ability to move and return to the original position, triggered by internal and external forces)
- Piezoelectricity (mechanical deformation of the crystals generates electrical charge and vice versa)
- Dielectric excitability and dispersion (electrical excitability also by light waves, vibrational resonance)
- Specific heat (this arises from the resonant movement of the atoms according to the elastic eigenvibrations and light waves, as well as possibly acoustic waves in the crystal)
- Optical effects: formal crystal optics (propagation at the speed of light) and optical activity (birefringence in several directions, etc.)
At least since the frequency measurement of individual cells and organs, it has been known that the countless crystal structures with atoms as building blocks, even in the body of a living being, exhibit different eigenfrequencies and vibration patterns.
If we consider this in conjunction with the conclusion drawn from point 4 above, which Max Born draws from the specific heat of crystal lattices, the decision to work specifically with crystals in body therapy also becomes obvious.
In addition, we can derive far-reaching therapeutic possibilities from point 5, the laws of optics, i.e., the refraction, resonance, and propagation of light in the crystal lattice, its color and prism effects.
Especially when viewed in the context of the biophoton activity of our cells:
Crystal Optics and BioPhotons
Prof. Dr. Fritz Albert Popp has built a crucial bridge here with his research findings on biophotons: “The Light in Our Cells,” “Biophotons – New Horizons in Medicine.”
Together with A.V. Budagovsky, Alexander Gurwitsch, Georges Lakhovsky, and Luc Montaignier, he provided evidence of cellular oscillation.
Biophotons are at the source of life. They are weak, coherent, electromagnetic emissions continuously emitted by living cells (from their DNA); their wavelengths are in the optical range.
Through their interference, through the superposition of light waves (constructive, destructive, or harmonizing), electromagnetic communication occurs in living organisms. This allows countless amounts of information to be transmitted. The endless spectral range of the wavelengths present in nature and used liberally enables life in the biophoton field: through their resonance, individual organs, organelles, cells, and cell groups can be controlled and influenced (F.A. Popp, “Biophotons – New Horizons in Medicine” Karl F. Haug 2006, Chapter 4.3), and signals/vibrations can be transmitted between the organism and its environment, as well as within each cell and cell group.
Biophotons control in real time, thus representing the fastest means of information and stimulus transmission between nerve cells, organs, organ parts, and cell organelles, alongside the familiar chemical messengers, hormones, and neurotransmitters. They thus ensure repair, immune stimulation, growth, and biological rhythms. The smallest number of photons in the cells is sufficient to take over the entire regulatory processes.
From them, shape, form, and function emerge according to holographic and fractal principles. Field and matter are connected through feedback.
As an antenna system for biophotons, light pulses, and energy within cells and organs, as well as externally (the body’s own radiation source), our DNA functions like our telomeres (the ends of the chromosomes that determine our aging/lifespan) due to its bipolar structure of individual spiral bands.
Our DNA, as an organic superconductor, receives and transmits and is therefore also called a “morphogenetic field initiator.”
The natural frequency of DNA corresponds to the resonant frequency of the Earth’s electromagnetic fields as a carrier frequency. This corresponds to a wavelength of 2 m (=length of DNA); 8 Hz is usually imprinted on it (which in turn corresponds to the so-called “alpha state” created by brain waves).
If gemstones and crystals are worn on the body, the following physical effects also result from Max Born’s fifth conclusion: we can use the crystal as an (inter)active carrier and generator (see also Prof. Gariajew’s “DNA as an Antenna” Wave Genetics – “Restorative Music” for the Cell).
Due to the weak electrical forces in the crystal lattice, incoming light waves are not simply reflected by the crystal, but are also emitted into the body through birefringence. The more intense the birefringence, the more strongly the crystal’s natural frequencies can be excited to resonance by light.
The frequencies of these waves are specific and characteristic of the crystal lattice vibration or vibrational complex (a multitude of frequencies).