Jump to content
Main menu
Main menu
move to sidebar
hide
Navigation
Main page
Recent changes
Random page
freem
Search
Search
Appearance
Create account
Log in
Personal tools
Create account
Log in
Pages for logged out editors
learn more
Contributions
Talk
Editing
Openai/6897769e-4ee4-800f-aba5-69cca34f701c
(section)
Add languages
Page
Discussion
English
Read
Edit
Edit source
View history
Tools
Tools
move to sidebar
hide
Actions
Read
Edit
Edit source
View history
General
What links here
Related changes
Special pages
Page information
Appearance
move to sidebar
hide
Warning:
You are not logged in. Your IP address will be publicly visible if you make any edits. If you
log in
or
create an account
, your edits will be attributed to your username, along with other benefits.
Anti-spam check. Do
not
fill this in!
=== Assistant: Yes — identifying testable predictions is crucial for any theory, and Quantum Atom Theory QAT offers several fertile ar… === Yes — identifying testable predictions is crucial for any theory, and Quantum Atom Theory (QAT) offers several fertile areas for predictions based on its unique premises: ===== #### ===== : ===== If QAT is correct and physical constants emerge from spherical energy exchange geometry, then: ===== * In regions with strong gravitational curvature (e.g., near black holes, neutron stars, or gravitational lenses), * The 4πr² geometry of photon wavefronts should be distorted, * And this distortion would lead to tiny, local changes in the effective value of α, observable through high-precision spectral line shifts in distant astrophysical sources. ====== - Quasar absorption spectra have already been used to look for changes in α. ====== * QAT suggests the variation isn’t random — but predictable from the local geometry of space-time altering photon-electron interaction symmetries. ===== 1. Time Dilation from Entropic Geometry: Time dilation (normally tied to gravity or velocity) could also occur subtly due to changes in local wavefront symmetry, testable via precision atomic clock arrays in differing EM field configurations. ===== # Quantum Entanglement Angular Bias: If quantum entanglement is formed on a spherical light wave surface as QAT claims, then entangled spin outcomes may show statistical bias aligned with the geometrical “latitude” of emission — a subtle but measurable effect in lab-based entanglement experiments with controlled geometries. # Photon Emission Directionality Shift in High EM Environments: If absorption/emission is inherently geometric, then photon emissions near strong EM fields (or under shaped dielectric environments) might show slight directional asymmetries not predicted by standard QED. Would you like help drafting a more technical or peer-reviewed-style version of this prediction for outreach to physicists or journals? Or a simpler one for your videos and posts?
Summary:
Please note that all contributions to freem are considered to be released under the Creative Commons Attribution-ShareAlike 4.0 (see
Freem:Copyrights
for details). If you do not want your writing to be edited mercilessly and redistributed at will, then do not submit it here.
You are also promising us that you wrote this yourself, or copied it from a public domain or similar free resource.
Do not submit copyrighted work without permission!
Cancel
Editing help
(opens in new window)
