A small particle of mass m move in such ...

A small particle of mass m move in such a way the potential energy `(U = (1)/(2) m^(2) omega^(2) r^(2))` when a is a constant and r is the distance of the particle from the origin Assuming Bohr's model of quantization of angular momentum and circular orbits , show that radius of the nth allowed orbit is proportional to in

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`F=(delU)/(delr)={-(1)/(2)mb^(2)r}=mb^(2)r`....(i)
Quantization of angular momentum
`L=(nh)/(2pi)`……(ii)
Centipetal force `=(mv^(2))/(r )`
`F` will provide centripetal force, So, from (i) `F`
So, `mb^(2)r=(mv^(2))/(r )`
`b^(2)r^(2)=v^(2)`
`v=br`.....(iii)
`L=mvr=mbr^(2)`
From (ii)
`mbr^(2)=(nh)/(2pi)`
`r^(2)=(n)/(mb)(h)/(2pi)`
So, `r propsqrt(n)` Hence proved.

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A small particle of mass m , moves in such a way that the potential energy U = ar^(3) , where a is position constant and r is the distance of the particle from the origin. Assuming Rutherford's model of circular orbits, then relation between K.E and P.E of the particle is :

`K.E = (3)/(2) U`

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A particle of mass m moves in circular orbits with potential energy N(r )=Fr , wjere F is a positive constant and r its distance from the origin. Its energies are calculated using the Bohr model. If the radius of the the n^(th) orbit (here h is the Planck's constant)

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A small particle of mass m moves in such a way that P.E. = -(1)/(2)mkr^(2) , where k is a constant and r is the distance of the particle from origin. Assuming Bohr's model of quantization of angular momentum and circular orbit, r is directly proportional to:

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