Threesology Research Journal

3-Part Solar Strobe Light Effect

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Visitors as of July 18th, 2025

Note: I am rushed this morning and threw together some information together after the Topic's heading came to mind. However, I am rushed to complete several other pages and have decide to delay the inclusion of images to accompany the different references of the radiant energy spectrum. Working with images can take an enormous amount of time.

In an early effort to come up with an idea to explain the incidence of a triplet Code in DNA as well as a recurrence of three-patterned structures in human anatomy (), as well as a recurring tripartite organizational theme which is reminiscent of a After Every Third value notation system, we have the contender phrased as a triple-patterned irradiation effect of the Sun, which would have been more poignant billions of years ago when the Earth's rotation was much faster.

The rate of the Earth's rotation rate billions of years ago during the period when life's Chemistry was developing as a photo-sensitive array of mini- midi- maxi molecular entities, is guesstimated to have been in the 2- to 6-hour range, in comparison to the present 23 hours, 56 minutes, 4.09 seconds by some accounts that generally reference the view of being 24 hours.

It is not difficult for anyone to recognize the difference in solar irradiation intensities for the phases/moments of the Sun know colloquially as Dawn- Noon- Dusk. Hence, it equally is not difficult to understand that a fast spinning Earth would have been effected in a 3-patterned accelerated way by the Sun, thus leaving a 3-patterned impression and biologically receptive survival requirement.

In an effort to provide a general understanding of the present idea, it is of need to provide information about the use of pulsating/flickering/flashing light as a therapeutic tool as well as how different populations are affected, and to acknowledge that the chemistry of life is photo-sensitive and photo-reactive:

AI response to the query "pulsating light effects on different populations":

Pulsating light, also known as flickering or flashing light, has various effects on both human and animal populations, depending on factors like frequency, intensity, duration of exposure, and individual sensitivities.

• Effects on humans:
  • Photosensitive Epilepsy: Individuals with photosensitive epilepsy can experience seizures triggered by flickering lights, particularly in the 10-25 Hz range, according to the Canadian Centre for Occupational Health and Safety.
  • Visual Discomfort: Even in individuals without epilepsy, flickering lights can cause discomfort, eye strain, headaches, fatigue, blurred vision, or reduced visual performance. This is especially true for flicker rates between 50-90 Hz.
  • Cognitive Function: Some studies suggest that flickering light, particularly at certain frequencies (e.g., 40 Hz), may impact cognitive functions like memory and attention, with potential benefits for neurological conditions like Alzheimer's disease by enhancing gamma waves in the brain.
  • Mood and Well-being: Pulsating light can affect mood and well-being. Some studies show that it can enhance emotional responses to music, particularly emotions related to "Joyful Activation". In contrast, others note that flicker from blue light can potentially exacerbate anxiety or disrupt sleep patterns. Additionally, the use of tunable white lighting and other forms of light therapy, which sometimes involve pulsation, are explored for mood regulation and mental health benefits.
• Effects on animals:
  • Behavioral Alterations: Flashing or flickering artificial light can alter animal behavior, influencing foraging, daily movements, and attraction to light sources.
  • Physiological Disruptions: Pulsating light can disrupt circadian rhythms and sleep patterns in animals. Studies on guinea pigs have even shown that exposure to flashing LED lights can induce myopia.
  • Avoidance and Attraction: The response to pulsating light can vary depending on the species and light wavelength. Some species may exhibit avoidance, while others may be attracted to it. For example, blue pulsing lights have been shown to enhance avoidance responses in birds under high ambient light conditions, while red lights might be counterproductive.
  • Critical Fusion Frequency (CFF): The ability of animals to perceive flickering light depends on their Critical Fusion Frequency (CFF). Some nocturnal and crepuscular animals have exceptionally high CFFs, meaning they might perceive artificial light as flashing even when humans don't.
• Factors influencing the effects:
  • Flicker frequency: Different flicker frequencies can have different effects, with specific frequencies potentially triggering seizures in sensitive individuals or inducing hallucinations.
  • Intensity and wavelength: The brightness, color, and wavelength of the light can also play a role in its effects.
  • Individual differences: Factors such as genetics, age, and pre-existing medical conditions can affect an individual's sensitivity to pulsating light.

In conclusion, pulsating light has a range of potential effects on different populations. While it may offer therapeutic benefits in some contexts, particularly for neurological and mood-related conditions, it's essential to consider individual sensitivities and potential risks, such as triggering seizures in susceptible individuals or causing visual discomfort, according to the Canadian Centre for Occupational Health and Safety.

It is of need to provide information about molecular photo-sensitivity:

AI response to query "molecular photosensitivity and reactivity to solar radiation"

Photosensitivity in molecules refers to their ability to undergo chemical or physical changes upon absorbing light, particularly solar radiation. These changes can range from simple alterations in electron distribution to the breaking of chemical bonds and the formation of new molecules.

• How does it happen?
  • Light Absorption: Molecules absorb photons from sunlight, boosting their electrons to higher energy levels (excited states).
  • Excited State Reactivity: The properties of these excited molecules differ greatly from their ground state. They may be stronger acids or reductants and can undergo various reactions such as dissociation, isomerization, and energy or electron transfer.
• Key examples of molecular photosensitivity and reactivity to solar radiation
  • Photosynthesis: Plants and other photosynthetic organisms utilize light-absorbing pigment molecules like chlorophyll to capture solar energy. This energy is then converted into chemical energy (ATP and NADPH) through a series of light-dependent reactions, ultimately leading to the formation of sugars.
  • Vitamin D Synthesis: In the skin of animals, including humans, sunlight exposure (specifically UV radiation) triggers a photochemical reaction that converts 7-dehydrocholesterol into vitamin D, essential for bone health and kidney function.
  • Ozone Formation and Depletion: In the stratosphere, UV radiation initiates the formation of ozone (O3) from oxygen molecules (O2). Ozone, in turn, absorbs harmful UV radiation, protecting life on Earth. However, ozone-depleting substances can disrupt this natural balance, leading to a reduction in ozone concentration and increased UV radiation reaching the surface.
  • DNA Damage: Excessive exposure to UV radiation can damage DNA strands, leading to mutations and potentially contributing to skin cancers.
  • Photodegradation: Many substances, such as plastics, can be broken down or degraded by exposure to sunlight, particularly UV radiation.
  • Photosensitivity in Skin: Certain molecules (photodynamic agents), whether ingested, applied topically, or produced by the body, can enhance the skin's sensitivity to sunlight, leading to abnormal reactions like rashes or sunburns.
• Factors affecting molecular photosensitivity and reactivity:
  • Wavelength and Intensity of Light: Different wavelengths of light carry different amounts of energy, with shorter wavelengths (like UV) being more energetic and potentially more damaging.
  • Molecular Structure: The chemical structure of a molecule dictates its ability to absorb light and the types of reactions it can undergo upon excitation.
  • Presence of Other Molecules: Interactions with other molecules in the environment can influence photochemical reactions, potentially enhancing or hindering their occurrence.

Understanding molecular photosensitivity and reactivity to solar radiation is crucial for various fields, including environmental science, medicine, and the development of new materials and technologies.

Every system of education... Public, Private, Religious, Secular— and porch swing, bar stool, sidewalk, Academic, lunchroom, cafe' table, art exposition, symphonic hall corridor, auction bench, picnic table, etc., encounter, will be affected. Geological time scale charts will be changed to include a representative time-line of Earth's rotation rate over time, and come to suggest that life, like geological processes may be rotation rate specific.

This idea not only explains in part where humanity came from, but where it present is, and makes projections for the future in regards to the necessity for adapting to an incremental deterioration time-line of the Earth in a planetary system withing a galaxy inside an as yet poorly defined Universal system of activity where the 3 geometries of the Universe (aka 3 manifolds) may represent 3 different vantage points of the same contextual scenario.

• Shape of the Universe (ten possibilities)
  • Ten possible shapes of the universe, as explored in mathematical topology and cosmology, include:
    • 3 standard views: Flat (Euclidean)- Spherical (positive curvature)- Hyperbolic (negative curvature)
    • Various "multiconnected" or "nontrivial" topologies like the 3-torus, 1/2-Twist Cube Space, and others. (These shapes are based on the geometry of space and how it curves, and whether it is finite or infinite.)

AI generated response to the query "3 standard and 7 non-standard views of the Universe":

Ten possible shapes of the universe, as explored in mathematical topology and cosmology, include: flat (Euclidean), spherical (positive curvature), hyperbolic (negative curvature), and various "multiconnected" or "nontrivial" topologies like the 3-torus, 1/2-Twist Cube Space, and others. These shapes are based on the geometry of space and how it curves, and whether it is finite or infinite.

3 standard views of the universe:

• The current standard model of cosmology, also known as the Lambda-CDM model, is widely accepted by cosmologists and is based on a few key concepts. Within this framework, three important "standard views" of the universe can be considered based on its geometry:
  • Flat Universe: This model suggests that space is Euclidean, meaning that on large scales, the geometry of the universe is flat. In a flat universe, parallel lines would remain parallel forever.
  • Spherical (Closed) Universe: In this view, space is curved like the surface of a sphere, possessing positive curvature. If you traveled in a straight line in a spherical universe, you would eventually return to your starting point, like circumnavigating a globe.
  • Hyperbolic (Open) Universe: This model describes space as having negative curvature, similar to the surface of a saddle. In a hyperbolic universe, parallel lines would diverge, and the universe would expand forever, according to the University of Oregon.
  • Current observations, particularly those related to the Cosmic Microwave Background (CMB) radiation, favor a spatially flat universe, although the other geometries remain possibilities within some theoretical frameworks.

7 non-standard views of the universe:

• While the Lambda-CDM model and the Big Bang theory are the prevailing scientific consensus, a variety of alternative or "non-standard" cosmological models have been proposed to address perceived shortcomings or explore different possibilities. It's important to note that many of these are speculative and have less empirical support than the standard model.
  • Steady State Theory: This model posits that the universe has always existed and will continue to exist in a constant, unchanging state, without a beginning or end. It suggests that new matter is continuously created to maintain a constant average density as the universe expands, according to Orbital Today.
  • Cyclic/Oscillating Universe: This theory proposes that the universe undergoes an infinite series of expansions and contractions, each starting with a Big Bang and ending in a "Big Crunch" that rebounds to start a new cycle. The universe is considered closed, meaning it contains enough matter to eventually halt expansion and trigger a contraction. A more recent version, inspired by brane cosmology, suggests an endless sequence of cosmic epochs with expansion and contraction facilitated by cosmic acceleration.
  • Eternal Inflation/Multiverse: This model, building on the Big Bang's inflationary phase, suggests that inflation, a period of extremely rapid expansion, may continue eternally in most regions of the universe. This would lead to a multiverse with an infinite number of universes, where only a tiny fractal volume ever ends inflation.
  • Plasma Cosmology: This model emphasizes the role of plasma and electromagnetic forces, rather than gravity alone, in shaping the structure and evolution of the universe. It suggests that electromagnetic forces, which are much stronger than gravity, could explain the formation of large-scale structures like galaxy clusters and cosmic voids.
  • Modified Newtonian Dynamics (MOND): As an alternative to dark matter, MOND suggests a modification to Newton's law of gravity at low accelerations, potentially explaining phenomena like galaxy rotation curves without needing to invoke the existence of unseen dark matter.
  • Simulation Hypothesis: This philosophical idea proposes that our reality is actually a sophisticated computer simulation created by a more advanced civilization. This speculative concept touches upon notions of higher realities and the nature of consciousness within a potentially simulated environment.
  • Mathematical Universe Hypothesis (MUH): Proposed by Max Tegmark, this hypothesis suggests that our external physical reality is a mathematical structure. It implies that the universe is not merely described by mathematics but is mathematics itself, and that all mathematically possible universes exist.

It's important to note that many of these non-standard views are currently not supported by the available observational evidence to the same extent as the standard Big Bang model. However, they represent ongoing areas of research and exploration as scientists continue to refine our understanding of the universe.

The Sun emits light across the entire electromagnetic spectrum, but most of its energy is concentrated in the visible light, infrared, and ultraviolet ranges. Specifically:

1. About 43% of solar radiation is in the visible light spectrum.
2. 49% is infrared.
3. 7% is ultraviolet.

While the Sun also emits smaller amounts of X-rays, gamma rays, and radio waves, these are less significant in terms of overall energy output.

• Visible Light:
  • This is the portion of the spectrum we can see, ranging from about 400 to 700 nanometers (nm). The Sun's visible light appears white, but when analyzed, it reveals a spectrum of colors with the green portion peaking in intensity when viewed from space, according to Wikipedia: Sun
• Infrared (IR):
  • This region of the spectrum has longer wavelengths than visible light and is associated with heat. Over half of the Sun's energy reaching Earth is in the infrared range, according to the UCAR Center for Science Education: Types of Energy from the Sun
• Ultraviolet (UV):
  • UV radiation has shorter wavelengths than visible light. While a significant portion of UV radiation is absorbed by the Earth's atmosphere, a small percentage still reaches the surface, including UV-A and some UV-B. Sources:
    1. The Solar Spectrum
    2. Electromagnetic specturm
• Other Radiation:
  • The Sun also emits other types of electromagnetic radiation, including X-rays, gamma rays, and radio waves, but these are a much smaller fraction of its total energy output.
    1. In what part of the electromagnetic spectrum does the Sun emit energy?
    2. Light From The Sun
• The intensity and distribution of these wavelengths change slightly depending on factors like the Sun's activity and atmospheric conditions. For example, the amount of UV radiation reaching the Earth's surface can be affected by the ozone layer,
  • Elecgtromagnetic Spectrum

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Page initially created: Friday, July 18th, 2025... 4:25 AM
Initial posting: Friday, July 18th, 2025... 6:15 AM