Physics for Scientists and Engineers With Modern Physics
Physics for Scientists and Engineers With Modern Physics
9th Edition
ISBN: 9781133953982
Author: SERWAY, Raymond A./
Publisher: Cengage Learning
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Chapter 43, Problem 56AP

(a)

To determine

To show that the force exerted on an ionic solid is F=αkee2r[1(r0r)m1]

(a)

Expert Solution
Check Mark

Answer to Problem 56AP

It is showed that the force exerted on an ionic solid is F=αkee2r[1(r0r)m1].

Explanation of Solution

Write the expression for the total potential energy of an ionic solid.

  Utotal=αkee2r+Brm                                                                                                   (I)

Here, Utotal is the potential energy of the solid, α is the Madelung constant, ke is the coulomb constant, e is the electronic charge, B is a constant and m is a constant.

The ionic bond formation will take place at equilibrium spacing where potential energy takes it minimum value.

Write the expression for the interatomic force.

  F=dUdr                                                                                                                 (II)

Let r0 is the equilibrium spacing.

Write the expression for the equilibrium condition for the force

  F=dUdr|r=r0                                                                                                             (III)

Here, F is interatomic force between the ions and r0 is he equilibrium forces.

Conclusion:

Take the derivative of the equation (II) to get expression of force.

  F=d(αkee2r+Brm)dr=[(αkee2r2)+(mBrm+1)]=(αkee2r2)+(mBrm+1)                                                                               (IV)

Use equation (II) in equation (III) to get value of B.

  [(αkee2r2)+(mBrm+1)]r=r0=0[(αkee2r02)+(mBr0m+1)]=0

Rearrange above equation to get B.

  (mBr0m+1)=(αkee2r02)B=(αmkee2r02(r0m+1))=αkee2mr0m1

Substitute αkee2mr0m1 for B in equation (I) to get F.

  F=(αkee2r2)+(mαkee2mr0m1rm+1)=αkee2r2[1(r0r)m1]                                                                              (V)

Therefore, it is showed that the force exerted on an ionic solid is F=αkee2r[1(r0r)m1].

(b)

To determine

To show that the restoring force experienced by ion is F=Ks, where K=αkee2r03(m1), by assuming that an ion in the solid is displaced a small distance s from r0.

(b)

Expert Solution
Check Mark

Answer to Problem 56AP

It is showed that the restoring force experienced by ion is F=Ks, where K=αkee2r03(m1).

Explanation of Solution

Rewrite expression for the force from equation (V).

  F=αkee2r[1(r0r)m1]

Assume that the ion in the solid is displaced a small distance s from r0.

Conclusion:

Let r=r0+s, so that r0=rs.

Substitute rs for r0 in above equation to get expression for the force.

  F=αkee2r2[1(rsr)m1]=αkee2r2[1(1sr)m1]                                                                                    (VI)

Expand (1sr)m1 using binomial expansion.

   (1sr)m1=1(m1)sr=1(m1)sr+(m1)(m)2!(sr)2......

Take the first two terms of the binomial expansion.

Substitute 1(m1)sr for (1sr)m1 in equation (VI) to get F.

  Fαkee2r2[1(1(m1)sr)]=αkee2r2[(m1)sr]

Substitute r0 for r in above equation to get restoring force at equilibrium spacing.

  Fαkee2r02[(m1)sr0]αkee2r03(m1)s

The above equation indicates that the force is proportional to displacement from equilibrium position and force acts in the opposite direction of displacement. Therefore above equation is equivalent to restoring force.

Write the above expression in generalized form.

  F=Ks

Here, K is stiffness constant.

Compare above two expressions to get K.

  K=αkee2r03(m1)                                                                                                     (V)

Therefore, it is showed that the restoring force experienced by ion is F=Ks, where K=αkee2r03(m1).

(c)

To determine

The frequency of vibration of a Na+ ion in NaCl using the result of part(b).

(c)

Expert Solution
Check Mark

Answer to Problem 56AP

The frequency of vibration of a Na+ ion in NaCl using the result of part(b) is 9.18THz.

Explanation of Solution

In figure 38.22, the distance from sodium ion to sodium ion is 0.562737nm.

Then interatomic spacing in NaCl is half of the distance between sodium ion to sodium ion.

Therefore, calculate the spacing in NaCl.

  r0=0.562737nm2=0.281369×109m

Write the expression for the ionic cohesive energy.

  U0=αkee2r0(11m)                                                                                                (VI)

Here, U0 is the ionic cohesive energy.

Use expression (V) to get stiffness constant.

Write the expression for frequency of vibration of sodium ion.

  f=12πKm                                                                                                             (VII)

Here, m is the mass of eh sodium atom and f is the frequency of vibration.

Conclusion:

The ionic cohesive energy for the crystal is 7.84eV.

Substitute 1.7476 for α, 7.84eV for U0, 8.99×109Nm2/C2 for ke, 1.60×1019C for e and 8 for m in equation (VI).

  7.84eV=(1.7476)(8.99×109Nm2/C2)(1.60×1019C)2r0(118)r0=(1.7476)(8.99×109Nm2/C2)(1.60×1019C)27.84eV(118)=2.81×1010m

Substitute 1.7476 for α, 8.99×109Nm2/C2 for ke, 1.60×1019C for e, 8 for m and 2.81×1010m for r0 in equation (V) to get K.

  K=(1.7476)(8.99×109Nm2/C2)(1.60×1019C)2(2.81×1010m)3(81)=127N/m

Substitute 127N/m for K and 23.0u for m in equation (VII) to get f.

  f=12π127N/m23.0u×1.66×1027kg1u=9.18×1012Hz×1THz1012Hz=9.18THz

Therefore, the frequency of vibration of a Na+ ion in NaCl using the result of part(b) is 9.18THz.

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Chapter 43 Solutions

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