Fundamentally understanding what bonding/antibonding orbitals are was one of the core reasons why I began my journey into quantum physics. This lecture was a moment in my quest to know the universe that I'd been working for almost a year to arrive at. It may seem silly, but this is one of the most important milestones in education I have reached. Thank you for using that example. I cannot express in words the excitement it brought me. My heart is racing and I'm being flooded with serotonin right now! LFG!! MORE PHYSICS!! YES!!!
I think categorizing indistinguishable particles with antisymmetric wavefuntion would a more generalized definition of fermions Correct me if I am wrong, I am still trying to figure these things out
Fundamentally understanding what bonding/antibonding orbitals are was one of the core reasons why I began my journey into quantum physics. This lecture was a moment in my quest to know the universe that I'd been working for almost a year to arrive at. It may seem silly, but this is one of the most important milestones in education I have reached. Thank you for using that example. I cannot express in words the excitement it brought me. My heart is racing and I'm being flooded with serotonin right now! LFG!! MORE PHYSICS!! YES!!!
your videos are great!!
Thanks for the hard work producing them!
you're the best!
This has helped a lot!
32:50 "Because electrons are fermions" -- I was under the impression fermion == spin 1/2, but that statement was made in a context without spin?
I think categorizing indistinguishable particles with antisymmetric wavefuntion would a more generalized definition of fermions
Correct me if I am wrong, I am still trying to figure these things out
What if we add a third particle and try to swap them around? It can't possibly be that all 3 are the opposite phase as one another?
QM made easier thank you