[" 0.The binding energy of a "H" -atom,considering an "],[" electron moving around a fixed nuclei (proton),is "],[qquad B=-(me^(4))/(8n^(2)varepsilon_(0)^(2)h^(2))(m=" electron mass) "],[qquad B=-(Me^(4))/(8n^(2)varepsilon_(0)^(2)h^(2))(M=" proton mass "]

The binding energy of a H-atom considering an electron moving around a fixed nuclei (proton), is B = - (me^(4))/(8n^(2)epsi_(0)^(2)h^(2)) (m= electron mass) If one decides to work in a frame of refrence where the electron is at rest, the proton would be movig around it. By similar arguments, the binding energy would be : B = - (me^(4))/(8n^(2)epsi_(0)^(2)h^(2)) (M = proton mass) This last expression is not correct, because

The binding energy of a H-atom considering an electron moving around a fixed nuclei (proton), is B = - (me^(4))/(8n^(2)epsi_(0)^(2)h^(2)) (m= electron mass) If one decides to work in a frame of refrence where the electron is at rest, the proton would be movig around it. By similar arguments, the binding energy would be : B = - (me^(4))/(8n^(2)epsi_(0)^(2)h^(2)) (M = proton mass) This last expression is not correct, because

The binding energy of a H-atom, considering an electron moving around a fixed nucleus (proton), is B=-(me^4)/(8n^2epsilon_0^2h^2) (m=electron mass) If one decides to work in a frame of reference where the electron is at rest, the proton would be moving around it. By similar arguments, the binding energy would be B=-(me^4)/(8n^2epsilon_0^2h^2) (M=proton mass). This last expression is not correct because.

The binding energy of a H atom, considering an electron moving around a fixed nuclei (proton), is B=(me^4)/(8n^2in_0^2h^2) (m="mass of electron") if one decides to work in a frame of refrence where the electron is at rest , the proton would be moving around it. By similar arguments , the binding energy would be B=(Me^4)/(8n^2in_0^2h^2) (M="mass of proton") This last expression is not correct because

The electron of hydrogen atom is considered to be revolving around the proton in circular orbit of radius (h^(2))/(me^(2)) with velocity (e^(2))/(h) , where h=(h)/(2pi) . The curret I is

If m,e,epsilon_(0) h and c denote mass ,electron , change of electron, plank 's constant and speed of light , respectively , then the dimensions of (me^(4))/(epsilon_(0)^(2) h^(2) c) are