Schrodinger equation
My opinion regarding physics is that it is used too much mathematics to explain concepts about a theory. Physics is of course based on mathematical precision, equations and calculus, but physicists often forget to think in terms of the physics, and not mathematics.
But when quantum mechanics intervene it’s impossible to not think the physics in terms of mathematics, because quantum mechanics it’s all about probability. Concepts are so strange to human daily life that without mathematics you are completely lost. But you also must think conceptual in physics, respecting also mathematical results.
To be able to maintain rhythm with the physics, most theoretical physicists now think in terms of pure analytical results, mathematical analysis and experimental results. It’s in a way natural, but to be able to see really the things you must also conceptualize things. Because otherwise you are lost in equation and theoretical analytical results.
That’s why I think that Large Hadron Colider from CERN will not find Higgs Boson. Because Higgs it’s a concept restraint only to the Standard Model, which regards only the world of particles.
Yes, of course Electroweak Unification is a great step in the evolution of physics, but it’s only the beginning of a new revolution. Things are much much complicated that Standard Model hopes to resolve by finding Higgs Boson at CERN.
To be able to explore the world of particles you must understand first the relationship between theory of relativity and the quantum mechanics.
Things are already very complicated when we are talking of relativity and quantum mechanics, but to pursuit with advance with physics we must unify these two aspects first. Higgs will not at all resolve the problems of relativity, even if could resolve some problems of Standard Model.
In my opinion Standard Model is just a very limited point of view of quantum mechanics that we see today. And Higgs Boson it will not show up, because it doesn’t exist.
We need a more clear view, a more larger view of all the physics that we know today. And the next step is to understand the liaison between general relativity and quantum mechanics.
