The potential energy of a particle varies as .
`U(x) = E_0 ` for ` 0 le x le 1`
`= 0` for `x gt 1 `
for `0 le x le 1` de- Broglie wavelength is `lambda_1` and for `xgt1` the de-Broglie wavelength is `lambda_2`. Total energy of the particle is `2E_0`. find `(lambda_1)/(lambda_2).`

The potential energy of a partical varies as . U(x) = E_0 for 0 le x le 1 = 0 for x gt 1 For 0 le x le 1 , de- Broglie wavelength is lambda_1 and for xgt the de-Broglie wavelength is lambda_2 . Total energy of the partical is 2E_0. find (lambda_1)/(lambda_2).

The potential energy of particle of mass m varies as U(x)={(E_(0)"for"0lexle1),(0" for " gt 1):} The de Broglie wavelength of the particle in the range 0lexle1 " is " lamda_(1) and that in the range xgt1" is "lamda_(2) . If the total of the particle is 2E_(0)," find "lamda_(1)//lamda_(2) .

The potential energy of a particle of mass m is given by U(x){{:(E_(0),,,0lexlt1),(0,,,xgt1):} lambda_(1) and lambda_(2) are the de-Broglie wavelength of the particle, when 0le x le1 and x gt 1 respectively. If the total energy of particle is 2E_(0) , then the ratio (lambda_(1))/(lambda_(2)) will be

The de Broglie wavelength (lambda) of a particle is related to its kinetic energy E as

Derive the relation between the wavelength (lambda) of the de broglie wave and kinetic energy (E ) of a moving particle

Kinetic energy of the particle is E and it's De-Broglie wavelength is lambda . On increasing it's KE by delta E , it's new De-Broglie wavelength becomes lambda/2 . Then delta E is

An electron in a hydrogen like atom makes transition from a state in which itd de Broglie wavelength is lambda_(1) to a state where its de Broglie wavelength is lambda_(2) then wavelength of photon ( lambda ) generated will be :

If the de-Broglie wavelength is lambda_(0) for protons accelerated through 100 V, then the de-Broglie wavelength for alpha particles accelerated through the same voltage will be