What is the threshold energy (or frequency) required for an electromagnetic field to transition from a near field to become self propagating (EMR), far field? (If I'm using the right definitions to ask the question correctly). Is this constant or are there other details needed to calculate this?
I'm reaching out for QM collaborators now and hope to find some shortly. Already have a PhD in mathematics that is agreeing to work with me. This new collaborator commented that the way I'm wording things people may interpret a classical physics perspective, as you did. He's helping me with...
Ah. My PhD is in Medical Science, being brought into learning about QM based on a discovery currently in review. I'm trying to understand how it ties to QM as links can be seen. New to the forum so now I understand that selecting "A" refers to level of question, not level of my training...
Thank you for your comments. They resonate well, very well actually. This is a quote from a manuscript (in review) of mine and when accepted (fingers crossed) you may find the work interesting. I'm brought into QM not as a destination of choice, but as a path that is leading me to be...
Thanks. I agree with seeing waves and wave functions as abstract tools. Any textbook you recommend so I can continue my studies? If I understand it right, each moment in time a particle is defined by conservation laws, but each moment changes from what was and what will be, thus appearing...
Excellent, that's how to explain it. So to get an electron cloud, would a continual, perhaps random, force need to be exerted on an election's angular momentum?
To clarify, the co-objects with no relative linear motion would be the observer and the centre of the circular orbit (where the planet would be if there was one to keep the analogy).
Not sure the term, it is the force that you feel when you try to tilt a gyroscope, the resistance to changing the tilt of angular momentum if I'm describing that right.
Imagine a theoretical (exploratory) concept where a particle is looked from an observer's point of view. The relative state between the co-objects would have no relative linear motion, zero velocity, and zero displacement, and the particle existed in a self-interference state (if I'm using that...
Thanks. Am curious if anyone has set up an experiment to change these properties to see what happens and if they influence an outcome in theoretically predictable ways.
Any spinning item, proton, electron, even planet, has angular momentum that creates force. How can an electron exist in a random orbital cloud around a spinning proton if it has an angular momentum and requires force to alter from any circular orbital plane (like a planet orbiting a star)?