Skip to content

Non-Relativistic Modalities

View Full Verification & Sources For deeper exploration, search each site for: Vernadsky, biogeochemistry, biosphere, or noosphere.  
View Full Modality Assignments
Mechanics Modality Classical Mechanics, Hydrodynamics, Turbulence, Propulsion, Supersonic Flows, Hydrodynamic Stability, Viscoelastic Flows, Turbulent Boundary Layers, Turbulent Mixing, Two-Phase Flows, Supercritical Fluids, Turbulent Reactive Flows, Aerodynamic Shape Optimization, Drag Reduction, Dynamics of Bubbles and Droplets, Fire Whirls, Fish Locomotion, Flow Control, Lagrangian Mechanics, Hamiltonian Mechanics, Rigid Body Dynamics, Chaos Theory
Thermodynamics Modality Thermodynamics, Statistical Mechanics, Thermochemistry, Quantum Thermodynamics, Interfacial Transport, Heat Transport, Combustion, Phase Transitions in Biology
Electromagnetism Modality Electromagnetism, Computational Electromagnetics, Wave Scattering, Metamaterials, Aero-Optics, Electronic Properties and Materials
Quantum Modality Quantum Mechanics (non-rel), Quantum Materials, Quantum Information, Quantum Photonics, Quantum Condensed Matter, Fractional Quantum Hall Effect, Quantum Optics, Quantum Simulation
Condensed Matter Modality Condensed Matter Physics, Nanostructure Physics, Correlated Quantum Materials, Low-Temperature Physics, X-ray Physics, Soft Condensed Matter, Bose–Einstein Condensates, Ferroelectrics, Multiferroics, Ferromagnetism, Magnetic Properties, Mesoscopic Superconductivity, Soft Matter, Active Matter
AMO Modality Atomic Physics, Molecular Physics, Optics, Photonics, Acoustics, Laser Cooling and Trapping, Atom Optics, Precision Measurements, Ultrafast Optical Physics, Laser-Plasma Processes, Cold Atoms, Rydberg Atoms
Biophysics Modality Biophysics, Biophysical Approaches to Cell Biology, Complex Biological Systems, Computational Biophysics, Membrane Biophysics, Molecular Biophysics, Protein Structure and Dynamics, Biophysical Chemistry, Biotechnology, Computational Biology, Microbial Biophysics, Virology, Dynamics of Biomolecules, Force Transduction in Muscle, Neurodegenerative Diseases, Protein Folding, Single Molecule Biophysics, Structural Biology, Bioenergetics, Biological Fluorescence, Biopolymers, Endocytosis, Exocytosis, Intrinsically Disordered Proteins, Biofilms
Interdisciplinary Earth & Nuclear Modality Geophysics, Nuclear Physics (non-rel), Nanoparticles for Biomedical Applications, Nanoscale Catalysis, Ultrafast Structural Dynamics
The theory is that through scalar manipulation of these groupings, that the “fields of scalar foundations” may be warped in such a way as to cause a slippage adjustment back to Relativistic.  The aftermath a predictable progression not previously attainable.  For example: Artificial d’limonene production caused by molecules that no longer bind as previously observed; efficient binding and slippage into a molecule that is less stable than the resultants that would usually form. The original pioneer for this inspiration is Dr. Vladimir Vernadsky. Vladimir Igorevich Vernadsky, and the field of study is called geochemistry or more specifically biogeochemistry. Vernadsky was a pioneering Russian and Soviet scientist who deeply explored how chemical elements and reactions behave differently across various regions of the Earth. His work laid the foundation for understanding how the Earth’s crust, biosphere, and atmosphere interact chemically over time and space.  His last work involved taking different radioactive isotopes of different physical sizes and shapes, that had stable nuclear decay rates, and measuring the changes in decay rates based on geolocation, proximity, orientation, and astrological orientations due to gravimetric influences.

About Vladimir Vernadsky

  • Born: March 12, 1863
  • Died: January 6, 1945
  • Field: Geochemistry, Biogeochemistry, Radiogeology
  • Legacy: Founder of the biosphere concept and a key figure in the development of Earth sciences in Russia.
  • Current Experiments: see below

His Contributions

  • Geochemical Differentiation: He studied how chemical reactions and element distributions vary depending on geographic and geological conditions.
  • Biosphere Theory: He proposed that life is a geological force shaping the planet, influencing chemical reactions globally.
  • Radioactive Elements: He investigated how radioactive decay contributes to Earth’s heat and element distribution.

Field of Study: Geochemistry

  • Definition: Geochemistry is the science that uses the principles of chemistry to explain the mechanisms behind major geological systems such as the Earth’s crust and oceans.
  • Subfields: Includes biogeochemistry (interaction of biological and geological processes), isotope geochemistry, and environmental geochemistry.

A Few of More Programs of Experimental Research

These organizations, institutes, labs, and projects directly apply, extend, or honor Vladimir Vernadsky’s foundational work in biogeochemistry, the biosphere, and the noosphere. Each conducts active research, education, or innovation explicitly referencing his concepts — from Antarctic geochemistry to AI-driven noosphere innovation.

Interactive Table of Vernadsky-Inspired Institutions

Click any organization name to visit their site. Hover for a brief description.

# Organization / Project Website How They Use Vernadsky’s Work
1 Vernadsky Institute of Geochemistry & Analytical Chemistry (GEOKHI RAS) geokhi.ru Leads biogeochemistry labs continuing his exact field; named after him.
2 V.I. Vernadsky Ecological Foundation vernadsky.ru Funds sustainable development & noosphere conferences.
3 Akademik Vernadsky Antarctic Station uac.gov.ua Geochem/ecology research in extreme environments, named in his honor.
4 Noosphere Association (Vernadsky Challenge) noosphereglobal.com Startup contests applying noosphere to tech innovation.
5 Meteoritics Lab (Vernadsky Institute) meteorites.ru Geochem analysis of meteorites building on radiogeology.
6 Vernadsky Institute of General & Inorganic Chemistry nas.gov.ua/IGIC Materials/chem research from his foundational lab.
7 European Geosciences Union egu.eu Awards the Vernadsky Medal for biogeochemistry.
8 Institute of the Cosmos cosmos.art Publishes/annotates The Biosphere for modern use.
9 Antikythera Noösphere Project noosphere.antikythera.org Digital edition of noosphere transition theory.
10 Human Energy (Noosphere Initiative) humanenergy.io Human development via secular noosphere vision.
11 Max Polyakov Noosphere Ventures maxpolyakov.com AI/space tech inspired by noosphere sustainability.
12 Rising Tide Foundation risingtidefoundation.net Publishes essays on philosophy & geopolitics.
13 Jackson Biogeochemistry Lab (Stanford) jacksonlab.stanford.edu Terrestrial cycles citing Vernadsky as founder.
14 All-Russian Geological Research Inst. (VSEGEI) vsegei.ru Geological surveys honoring biosphere doctrine.
15 IIASA iiasa.ac.at Global biogeochem modeling linked to his concepts.
16 Max Planck Biogeochemistry (BGC Jena) bgc-jena.mpg.de Awards Vernadsky Medal; core biogeochem research.
17 Tavrida National University (TNU Vernadsky) tnu.edu.ua Science/botany programs at namesake university.
18 State Geological Museum (Vernadsky) sgm.ru Exhibits/research on his geochem collections.
19 Vernadsky Challenge Platform vernadskychallenge.com Annual innovation accelerator based on noosphere.
20 Environment & Society Portal environmentandsociety.org Revives noosphere in modern ecological discourse.

Key Insights

  • 10+ sites run active biogeochemistry labs
  • 7+ sites apply noosphere to tech/innovation
  • Antarctic & Earth observation stations use biosphere framework
  • Geographic spread: Russia, Ukraine, Europe, USA
  • All verified with 2024–2025 projects/publications
View Full Verification & Sources For deeper exploration, search each site for: Vernadsky, biogeochemistry, biosphere, or noosphere.  

100 Unique Areas of Non-Relativistic Research – Linked List & Modal Groups

This page presents a linked list of 100 unique non-relativistic research areas, organized into 8 relational modalities. Each area is sequentially linked (simulating a linked-list data structure), and grouped by shared theoretical, experimental, or application-based relationships. All mathematical operators seem to represent scalar properties (scalar modalities) in “Actual” physics.  However, like Dark Matter, Dark Energy, Gravity, foundational support for the existence of energy and momentum, localization, ajacency… all mathematics operators are scalar approximations not at all representing the nuances of Actual Physics. The following is an attempt to identify non-relativistic modalities, that through relativistic manipulation the scalar influence of nonrelativistic phenomena can be manipulated to act different than relativistic.  Similar to Bind and Slippage.

Linked List of 100 Research Areas

Click any item to jump to the next in the chain. The final item loops back to the start for demonstration.

  1. Classical Mechanics
  2. Thermodynamics
  3. Statistical Mechanics
  4. Electromagnetism
  5. Photonics
  6. Quantum Mechanics (non-rel)
  7. Atomic Physics
  8. Molecular Physics
  9. Optics
  10. Acoustics
  11. Geophysics
  12. Biophysics
  13. Nuclear Physics (non-rel)
  14. Condensed Matter Physics
  15. Nanostructure Physics
  16. Correlated Quantum Materials
  17. Low-Temperature Physics
  18. X-ray Physics
  19. Soft Condensed Matter
  20. Bose–Einstein Condensates
  21. Electronic Properties and Materials
  22. Ferroelectrics
  23. Multiferroics
  24. Ferromagnetism
  25. Magnetic Properties
  26. Mesoscopic Superconductivity
  27. Nanoparticles for Biomedical Applications
  28. Nanoscale Catalysis
  29. Ultrafast Structural Dynamics
  30. Quantum Materials
  31. Quantum Information
  32. Quantum Photonics
  33. Quantum Condensed Matter
  34. Soft Matter
  35. Fractional Quantum Hall Effect
  36. Hydrodynamics
  37. Laser Cooling and Trapping
  38. Quantum Optics
  39. Atom Optics
  40. Precision Measurements
  41. Ultrafast Optical Physics
  42. Laser-Plasma Processes
  43. Quantum Simulation
  44. Cold Atoms
  45. Rydberg Atoms
  46. Biophysical Approaches to Cell Biology
  47. Complex Biological Systems
  48. Computational Biophysics
  49. Membrane Biophysics
  50. Molecular Biophysics
  51. Protein Structure and Dynamics
  52. Biophysical Chemistry
  53. Biotechnology
  54. Computational Biology
  55. Microbial Biophysics
  56. Virology
  57. Dynamics of Biomolecules
  58. Force Transduction in Muscle
  59. Neurodegenerative Diseases
  60. Phase Transitions in Biology
  61. Protein Folding
  62. Single Molecule Biophysics
  63. Structural Biology
  64. Bioenergetics
  65. Biological Fluorescence
  66. Biopolymers
  67. Endocytosis
  68. Exocytosis
  69. Intrinsically Disordered Proteins
  70. Turbulence
  71. Aero-Optics
  72. Propulsion
  73. Supersonic Flows
  74. Hydrodynamic Stability
  75. Viscoelastic Flows
  76. Active Matter
  77. Combustion
  78. Turbulent Boundary Layers
  79. Turbulent Mixing
  80. Two-Phase Flows
  81. Supercritical Fluids
  82. Turbulent Reactive Flows
  83. Aerodynamic Shape Optimization
  84. Biofilms
  85. Drag Reduction
  86. Dynamics of Bubbles and Droplets
  87. Fire Whirls
  88. Fish Locomotion
  89. Flow Control
  90. Lagrangian Mechanics
  91. Hamiltonian Mechanics
  92. Rigid Body Dynamics
  93. Chaos Theory
  94. Thermochemistry
  95. Quantum Thermodynamics
  96. Interfacial Transport
  97. Heat Transport
  98. Computational Electromagnetics
  99. Wave Scattering
  100. Metamaterials (loops back)

8 Relational Modalities

Areas are grouped into relational modalities — overarching frameworks that connect research through methodology, theory, or application.

Modality Description Areas (Count)
Mechanics Modality Motion, forces, and dynamical systems in classical and fluid contexts. 22
Thermodynamics Modality Energy, heat, entropy, and non-equilibrium statistical systems. 8
Electromagnetism Modality Fields, waves, and computational EM interactions. 6
Quantum Modality Non-relativistic quantum phenomena and quantum information. 8
Condensed Matter Modality Collective behaviors in solids, liquids, and exotic phases. 14
AMO Modality Atomic, molecular, and optical physics with light-matter control. 12
Biophysics Modality Physical principles applied to biological systems and molecules. 25
Interdisciplinary Earth & Nuclear Modality Geophysics, nuclear structure, and cross-domain applications. 5
View Full Modality Assignments
Mechanics Modality Classical Mechanics, Hydrodynamics, Turbulence, Propulsion, Supersonic Flows, Hydrodynamic Stability, Viscoelastic Flows, Turbulent Boundary Layers, Turbulent Mixing, Two-Phase Flows, Supercritical Fluids, Turbulent Reactive Flows, Aerodynamic Shape Optimization, Drag Reduction, Dynamics of Bubbles and Droplets, Fire Whirls, Fish Locomotion, Flow Control, Lagrangian Mechanics, Hamiltonian Mechanics, Rigid Body Dynamics, Chaos Theory
Thermodynamics Modality Thermodynamics, Statistical Mechanics, Thermochemistry, Quantum Thermodynamics, Interfacial Transport, Heat Transport, Combustion, Phase Transitions in Biology
Electromagnetism Modality Electromagnetism, Computational Electromagnetics, Wave Scattering, Metamaterials, Aero-Optics, Electronic Properties and Materials
Quantum Modality Quantum Mechanics (non-rel), Quantum Materials, Quantum Information, Quantum Photonics, Quantum Condensed Matter, Fractional Quantum Hall Effect, Quantum Optics, Quantum Simulation
Condensed Matter Modality Condensed Matter Physics, Nanostructure Physics, Correlated Quantum Materials, Low-Temperature Physics, X-ray Physics, Soft Condensed Matter, Bose–Einstein Condensates, Ferroelectrics, Multiferroics, Ferromagnetism, Magnetic Properties, Mesoscopic Superconductivity, Soft Matter, Active Matter
AMO Modality Atomic Physics, Molecular Physics, Optics, Photonics, Acoustics, Laser Cooling and Trapping, Atom Optics, Precision Measurements, Ultrafast Optical Physics, Laser-Plasma Processes, Cold Atoms, Rydberg Atoms
Biophysics Modality Biophysics, Biophysical Approaches to Cell Biology, Complex Biological Systems, Computational Biophysics, Membrane Biophysics, Molecular Biophysics, Protein Structure and Dynamics, Biophysical Chemistry, Biotechnology, Computational Biology, Microbial Biophysics, Virology, Dynamics of Biomolecules, Force Transduction in Muscle, Neurodegenerative Diseases, Protein Folding, Single Molecule Biophysics, Structural Biology, Bioenergetics, Biological Fluorescence, Biopolymers, Endocytosis, Exocytosis, Intrinsically Disordered Proteins, Biofilms
Interdisciplinary Earth & Nuclear Modality Geophysics, Nuclear Physics (non-rel), Nanoparticles for Biomedical Applications, Nanoscale Catalysis, Ultrafast Structural Dynamics
The theory is that through scalar manipulation of these groupings, that the “fields of scalar foundations” may be warped in such a way as to cause a slippage adjustment back to Relativistic.  The aftermath a predictable progression not previously attainable.  For example: Artificial d’limonene production caused by molecules that no longer bind as previously observed; efficient binding and slippage into a molecule that is less stable than the resultants that would usually form. The original pioneer for this inspiration is Dr. Vladimir Vernadsky. Vladimir Igorevich Vernadsky, and the field of study is called geochemistry or more specifically biogeochemistry. Vernadsky was a pioneering Russian and Soviet scientist who deeply explored how chemical elements and reactions behave differently across various regions of the Earth. His work laid the foundation for understanding how the Earth’s crust, biosphere, and atmosphere interact chemically over time and space.  His last work involved taking different radioactive isotopes of different physical sizes and shapes, that had stable nuclear decay rates, and measuring the changes in decay rates based on geolocation, proximity, orientation, and astrological orientations due to gravimetric influences.

About Vladimir Vernadsky

  • Born: March 12, 1863
  • Died: January 6, 1945
  • Field: Geochemistry, Biogeochemistry, Radiogeology
  • Legacy: Founder of the biosphere concept and a key figure in the development of Earth sciences in Russia.
  • Current Experiments: see below

His Contributions

  • Geochemical Differentiation: He studied how chemical reactions and element distributions vary depending on geographic and geological conditions.
  • Biosphere Theory: He proposed that life is a geological force shaping the planet, influencing chemical reactions globally.
  • Radioactive Elements: He investigated how radioactive decay contributes to Earth’s heat and element distribution.

Field of Study: Geochemistry

  • Definition: Geochemistry is the science that uses the principles of chemistry to explain the mechanisms behind major geological systems such as the Earth’s crust and oceans.
  • Subfields: Includes biogeochemistry (interaction of biological and geological processes), isotope geochemistry, and environmental geochemistry.

A Few of More Programs of Experimental Research

These organizations, institutes, labs, and projects directly apply, extend, or honor Vladimir Vernadsky’s foundational work in biogeochemistry, the biosphere, and the noosphere. Each conducts active research, education, or innovation explicitly referencing his concepts — from Antarctic geochemistry to AI-driven noosphere innovation.

Interactive Table of Vernadsky-Inspired Institutions

Click any organization name to visit their site. Hover for a brief description.

# Organization / Project Website How They Use Vernadsky’s Work
1 Vernadsky Institute of Geochemistry & Analytical Chemistry (GEOKHI RAS) geokhi.ru Leads biogeochemistry labs continuing his exact field; named after him.
2 V.I. Vernadsky Ecological Foundation vernadsky.ru Funds sustainable development & noosphere conferences.
3 Akademik Vernadsky Antarctic Station uac.gov.ua Geochem/ecology research in extreme environments, named in his honor.
4 Noosphere Association (Vernadsky Challenge) noosphereglobal.com Startup contests applying noosphere to tech innovation.
5 Meteoritics Lab (Vernadsky Institute) meteorites.ru Geochem analysis of meteorites building on radiogeology.
6 Vernadsky Institute of General & Inorganic Chemistry nas.gov.ua/IGIC Materials/chem research from his foundational lab.
7 European Geosciences Union egu.eu Awards the Vernadsky Medal for biogeochemistry.
8 Institute of the Cosmos cosmos.art Publishes/annotates The Biosphere for modern use.
9 Antikythera Noösphere Project noosphere.antikythera.org Digital edition of noosphere transition theory.
10 Human Energy (Noosphere Initiative) humanenergy.io Human development via secular noosphere vision.
11 Max Polyakov Noosphere Ventures maxpolyakov.com AI/space tech inspired by noosphere sustainability.
12 Rising Tide Foundation risingtidefoundation.net Publishes essays on philosophy & geopolitics.
13 Jackson Biogeochemistry Lab (Stanford) jacksonlab.stanford.edu Terrestrial cycles citing Vernadsky as founder.
14 All-Russian Geological Research Inst. (VSEGEI) vsegei.ru Geological surveys honoring biosphere doctrine.
15 IIASA iiasa.ac.at Global biogeochem modeling linked to his concepts.
16 Max Planck Biogeochemistry (BGC Jena) bgc-jena.mpg.de Awards Vernadsky Medal; core biogeochem research.
17 Tavrida National University (TNU Vernadsky) tnu.edu.ua Science/botany programs at namesake university.
18 State Geological Museum (Vernadsky) sgm.ru Exhibits/research on his geochem collections.
19 Vernadsky Challenge Platform vernadskychallenge.com Annual innovation accelerator based on noosphere.
20 Environment & Society Portal environmentandsociety.org Revives noosphere in modern ecological discourse.

Key Insights

  • 10+ sites run active biogeochemistry labs
  • 7+ sites apply noosphere to tech/innovation
  • Antarctic & Earth observation stations use biosphere framework
  • Geographic spread: Russia, Ukraine, Europe, USA
  • All verified with 2024–2025 projects/publications
View Full Verification & Sources For deeper exploration, search each site for: Vernadsky, biogeochemistry, biosphere, or noosphere.