Advertisements
Advertisements
प्रश्न
The Bohr model for the H-atom relies on the Coulomb’s law of electrostatics. Coulomb’s law has not directly been verified for very short distances of the order of angstroms. Supposing Coulomb’s law between two opposite charge + q1, –q2 is modified to |F| = `(q_1q_2)/((4πε_0)) 1/r^2, r ≥ R_0 = (q_1q_2)/(4πε_0) 1/R_0^2 (R_0/r)^ε, r ≤ R_0` Calculate in such a case, the ground state energy of a H-atom, if ε = 0.1, R0 = 1Å.
उत्तर
Let us consider the case, when r ≤ R0 = 1Å
Let ε = 2 + δ
F = `(q_1q_2)/(4πε_0) * R_0^δ/r^(2 + δ) = xR_0^δ/r^(2 + δ)`
Where, `(q_1q_2)/(4πε_0) = x = (1.6 xx 10^19)^2 xx 9 xx 10^9`
= `2.04 xx 10^-29 N m^2`
The electrostatic force of attraction between the positively charged nucleus and negatively charged electrons (Colombian force) provides the necessary centripetal force.
`(mv^2)/r = (xR_0^δ)/r^(2 + δ)` or `v^2 = (xR_0^δ)/(mr^(1 + δ)` ......(i)
`mvr = nh ⇒ r = (nh)/(mv) = (nh)/m [m/(xR_0^δ)]^(1/2) r^((1 + δ)/2)` ....[Applying Bhor's second postulates]
Solving this for r, we get `r_n = [(n^2h^2)/(mxR_0^δ)]^(1/(1 - δ))`
Where rn is the radius of nth orbit of the electron.
For n = 1 and substituting the values of constant, we get
`r_1 = [h^2/(mxR_0^δ)]^(1/(1 - δ)]`
⇒ `r_1 = [(1.05^2 xx 10^-68)/(9.1 xx 10^-31 xx 2.3 xx 10^-28 xx 10^+19)]^(1/29)`
= `8 xx 10^-11`
= 0.08 nm (< 0.1 nm)
This is the radius of orbit of electron in the ground state of hydrogen atom. Again using Bhor's second postulate, the speed of electron
`v_n = (nh)/(mr_n) = nh((mxR_0^δ)/(n^2h^2))^(1/(1 - δ)`
For n = 1, the speed of electron in ground state `v_1 = h/(mr_1) = 1.44 xx 10^6` m/s
The kinetic energy of electrons in the ground state
K.E. = `1/2 mv_1^2 - 9.43 xx 10^-19 J = 5.9 eV`
Potential energy of electron in the ground state till R0
U = `int_0^(R_0) Fdr = int_0^(R_0) x/r^2 dr = - x/R_0`
Potential energy from R0 to r, U = `int_(R_0)^r Fdr = int_(R_0)^r (xR_0^δ)/r^(2 + δ) dr`
U = `+ xR_0^δ int_(R_0)^δ (dr)/r^(2 + δ) = + (xR_0^δ)/(- 1 - δ) [1/r^(1 + δ)]_(R_0)^r`
U = `(xR_0^δ)/(1 + δ) [1/r^(1 + δ) - 1/R_0^(1 + δ)] = - x/(1 + δ) [(R_0^δ)/r^(1 + δ) - 1/R_0]`
U = `- x[(R_0^δ)/r^(1 + δ) - 1/R_0 + (1 + δ)/R_0]`
U = `- x[(R_0^-19)/r^(-0.9) - 1.9/R_0]`
= `2.3/0.9 xx 10^-18 [(0.8)^0.9 - 1.9]J = - 17.3 eV`
Hence total energy of electron in ground state = (– 17.3 + 5.9) = – 11.4 eV
APPEARS IN
संबंधित प्रश्न
With the help of a neat labelled diagram, describe the Geiger- Marsden experiment
Write two important limitations of Rutherford's nuclear model of the atom.
The first line of Balmer series (Hα) in the spectrum of hydrogen is obtained when an electron of hydrogen atom goes from ______.
The radius of electron's second stationary orbit in Bohr's atom is R. The radius of 3rd orbit will be:-
Which of the following transition in a hydrogen atom emit photon of the highest frequency:
The electron in a hydrogen atom is typically found at a distance of about 5.3 × 10−11 m from the nucleus which has a diameter of about 1.0 × 10−15 m. Assuming the hydrogen atom to be a sphere of radius 5.3 × 10−11 m, what fraction of its volume is occupied by the nucleus?
The energy levels of a certain atom for first, second and third levels are E, 4E/3 and 2E, respectively. A photon of wavelength λ is emitted for a transition 3 `→` 1. What will be the wavelength of emission for transition 2 `→` 1?
In the Rutherford experiment, α-particles are scattered from a nucleus as shown. Out of the four paths, which path is not possible?
How is the size of a nucleus found experimentally? Write the relation between the radius and mass number of a nucleus.
During Rutherford’s gold foil experiment, it was observed that most of the α-particles did not deflect. However, some showed a deflection of 180°.
What hypothesis was made to justify the deflection of α-particle by 180°?
