At `200^(@)C`, hydrogen molecule have velocity `2.4 xx 10^(5)" cm s"^(-1)`. The de Broglie wavelength in this case is approximately.

At 200^o C, hydrogen molecules have velocity 1.4 × 10^5cm s^(−1) . The de Broglie wavelength in this case is approximately :

At 200^o C, hydrogen molecules have velocity 3.4 × 10^4cm s^(−1) . The de Broglie wavelength in this case is approximately :

At 200^o C, hydrogen molecules have velocity 4 × 10^4cm s^(−1) . The de Broglie wavelength in this case is approximately :

At 200^o C, hydrogen molecules have velocity 5 × 10^4cm s^(−1) . The de Broglie wavelength in this case is approximately :

At 200^o C, hydrogen molecules have velocity 7 × 10^4cm s^(−1) . The de Broglie wavelength in this case is approximately :

If the velocity of hydrogen molecule is 5 xx 10^4 cm sec^-1 , then its de-Broglie wavelength is.

An electron travels with a velocity of x ms^(-1). For a proton to have the same de-Broglie wavelength, the velocity will be approximately:

A ball of mass 200g was thrown with the velocity of 20m/s. The de Broglie wavelength is:

A ball of mass 200g was thrown with the velocity of 30m/s. The de Broglie wavelength is:

A ball of mass 200g was thrown with the velocity of 50m/s. The de Broglie wavelength is: