Frequency doesn't look like anything?
Nothing is physics anymore!
Many processes in nature follow a simple principle: rhythm.
Long before modern science existed, people observed that health and well-being are closely linked to rhythm and balance in the body .
In Traditional Chinese Medicine, this relationship is described as Qi, in Ayurveda as Prana. Both systems assume that the organism functions as a dynamic equilibrium of internal processes .
With the development of modern physics in the 19th century , scientists began to investigate such rhythms scientifically. It became clear that energy is often organized into frequencies and oscillations – from acoustic resonances to electromagnetic waves such as light.
In the 20th century , scientists finally began to apply this perspective to biological systems as well.
One example of this is the work of biophysicist Fritz-Albert Popp , who in the 1970s investigated extremely weak light emissions from living cells . These so-called biophotons are now the subject of a research field known as biophotonics.
At the same time, modern neurophysiology has shown that the human brain also works in rhythmic activity patterns .
Rhythm in the brain
Stanford University School of Medicine - Department of Ophthalmology
University of California –
Vision Science Research
Electrical activity in the brain can be measured using an electroencephalogram (EEG).
This shows that neuronal activity is organized in characteristic frequency patterns that may be associated with different states of the brain – such as attention, perception or relaxation .
Neurophysiology investigates how rhythmic external stimuli can interact with these activity patterns.
A related phenomenon is called Frequency Following Response.
Light as a biological signal
Harvard Medical School –
Division of Sleep Medicine
Brigham and Women's Hospital-Harvard Chronobiology Program
Light does not only affect vision.
It is also an important time cue for the body.
Chronobiology investigates how light controls biological rhythms – such as the circadian rhythm, which regulates sleep-wake cycles, hormonal processes and parts of the autonomic nervous system .
One of the fundamental studies in this field shows that bright light can influence the circadian rhythm of humans.
Cell energy and light
Harvard Medical School –
Wellman Center for Photomedicine
Inside cells are mitochondria , often referred to as the "powerhouses of the cell". They produce the energy molecule ATP, which is needed for almost all processes in the body.
One research area in biophysics investigates the interaction of specific wavelengths of light with molecular structures in mitochondria. This approach is called photobiomodulation .
Studies suggest that light can influence cellular energy metabolism processes under certain conditions .
Electricity inside the cell
Tufts University –
Allen Discovery Center for Bioelectricity
In addition to neural networks, individual cells also work with electrical signals .
Every cell has a membrane potential – an electrical voltage across its cell membrane, which is created by ion channels and charge differences.
In recent years, this has developed into a growing field of research: bioelectricity.
This shows that electrical gradients between cells can be involved in complex regulatory processes , such as development, tissue pattern formation and regeneration .
Licht steuert den
menschlichen Biorhythmus.
1995
Rhythmische Reize
im Gehirn
2015
Bioelectricity and
regeneration
2021
Water is particularly sensitive to frequencies – and our bodies are made up of approximately 70% water. Cell communication itself occurs via electrical impulses . If this flow of information is disrupted, an energetic imbalance arises, which – in the long term – can also manifest physically.
What is interfering with our frequency field?
electromagnetic fields (Wi-Fi, Bluetooth, mobile communications)
Electrical interference sources in the living space (power grids, sockets)
Chronic stress, emotional strain, lack of sleep
Inappropriate diet, mineral deficiency
These factors throw our system out of coherence – out of the state in which everything vibrates in balance .
Masaru Emoto & the Language of Water
The Japanese scientist Masaru Emoto (1943–2014) dedicated himself to the question of how vibration and information influence water structures . In his experiments, he spoke to water in different languages or played music – then froze it and photographed the crystal structures.
His observation: Words, sounds, and intentions changed the symmetry and clarity of the crystals.
Even though his research is controversial , it is considered an important impetus for understanding subtle influences on matter .
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