kavic_Poster0216
... In our present work, we consider Yang-Mills theory in (2+1) and (3+1) dimensions with a large number of colors. The primary focus of our research is to construct the spectrum of gauge-invariant glueball states. In the 2+1 case, we use a Hamiltonian approach proposed by Karabali, Kim, and Nair (1997) ...
... In our present work, we consider Yang-Mills theory in (2+1) and (3+1) dimensions with a large number of colors. The primary focus of our research is to construct the spectrum of gauge-invariant glueball states. In the 2+1 case, we use a Hamiltonian approach proposed by Karabali, Kim, and Nair (1997) ...
Document
... / (such that to observe A(t) is the same as to evolve for time t and then observe A). The e / A(0)e observable A(t) satisfies the equation A'(t) = -i[A(t),H’]/h, and we have The two sides of this equation represent two pictures of quantum mechanics: Heisenberg's (observables change, states don't), a ...
... / (such that to observe A(t) is the same as to evolve for time t and then observe A). The e / A(0)e observable A(t) satisfies the equation A'(t) = -i[A(t),H’]/h, and we have The two sides of this equation represent two pictures of quantum mechanics: Heisenberg's (observables change, states don't), a ...
Lecture Set No. 1
... Example A U-tube manometer is used to determine the pressure drop across an orifice meter. The liquid flowing in the pipe line is a sulfuric acid solution having a specific gravity (60°/60°) of 1.250. The manometer liquid is mercury, with a specific gravity (60°/60°) of 13.56. The manometer reading ...
... Example A U-tube manometer is used to determine the pressure drop across an orifice meter. The liquid flowing in the pipe line is a sulfuric acid solution having a specific gravity (60°/60°) of 1.250. The manometer liquid is mercury, with a specific gravity (60°/60°) of 13.56. The manometer reading ...
