Saturation ionization current

Question

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Answer 1

Question

Chapter 9, Problem 9.22P

To determine

Saturation ionization current

Expert Solution & Answer

Answer to Problem 9.22P

Saturation ionization current is 7.8×10−13 A

Explanation of Solution

Given:

(370−Bq) 210Po = 370 nucleus disintegrate second

The rate of alpha from source, N=(25%)(370αs )=92.5αs

Kinetic Energy of the alpha particle emitted from ²¹⁰Po, E¯ = 5.3 MeV

The density of air, ρair=1.293×10−3g/cm3=1.293 mg/cm3

Window density thickness, tw = 2 mgcm2

Wall is at 1 cm from source, ta=1 cm

Density thickness of air, td=ρairta=1.293 mgcm3×1 cm=1.293mg/cm2

Mean energy loss per ion-pair, w = 35.5 eVion

Formula used:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2

Where, E is maximum energy of alpha.

Ionization current

I=(Nαs)⋅(E¯ eVα)⋅(1.6× 10 −19C ion )w eV ion ⋅1AC/s

N=Number of alpha particle per second from sourceE¯ = Remaining energy after passing through medium.w = Mean energy loss per ion-pair

Calculation:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2=0.322 (5.3 MeV)3/2=3.93 cm

The range of alpha in areal density,

R=1.293mgcm3×3.93 cm = 5.08mgcm2

Alpha must pass through air and window.

1.293mgcm2+2mgcm2=3.293mgcm2

Alpha particle remaining kinetic energy,

E¯=5.01mg cm2−3.293mg cm25.01mg cm2×5.3MeV=1.816 MeV

Ionization current

I=( N α s )⋅( E ¯ eV α )⋅( 1.6× 10 −19 C ion )w eV ion ⋅1AC/sI=( 92.5 α s )×( 1.81× 10 6 eV α )×( 1.6× 10 −19 C ion )35.5 eV ionI=7.8×10−13C/sec = 7.8×10−13 A

Conclusion:

Saturation ionization current is 7.8×10−13 A

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Answer 2

Question

Chapter 9, Problem 9.22P

To determine

Saturation ionization current

Expert Solution & Answer

Answer to Problem 9.22P

Saturation ionization current is 7.8×10−13 A

Explanation of Solution

Given:

(370−Bq) 210Po = 370 nucleus disintegrate second

The rate of alpha from source, N=(25%)(370αs )=92.5αs

Kinetic Energy of the alpha particle emitted from ²¹⁰Po, E¯ = 5.3 MeV

The density of air, ρair=1.293×10−3g/cm3=1.293 mg/cm3

Window density thickness, tw = 2 mgcm2

Wall is at 1 cm from source, ta=1 cm

Density thickness of air, td=ρairta=1.293 mgcm3×1 cm=1.293mg/cm2

Mean energy loss per ion-pair, w = 35.5 eVion

Formula used:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2

Where, E is maximum energy of alpha.

Ionization current

I=(Nαs)⋅(E¯ eVα)⋅(1.6× 10 −19C ion )w eV ion ⋅1AC/s

N=Number of alpha particle per second from sourceE¯ = Remaining energy after passing through medium.w = Mean energy loss per ion-pair

Calculation:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2=0.322 (5.3 MeV)3/2=3.93 cm

The range of alpha in areal density,

R=1.293mgcm3×3.93 cm = 5.08mgcm2

Alpha must pass through air and window.

1.293mgcm2+2mgcm2=3.293mgcm2

Alpha particle remaining kinetic energy,

E¯=5.01mg cm2−3.293mg cm25.01mg cm2×5.3MeV=1.816 MeV

Ionization current

I=( N α s )⋅( E ¯ eV α )⋅( 1.6× 10 −19 C ion )w eV ion ⋅1AC/sI=( 92.5 α s )×( 1.81× 10 6 eV α )×( 1.6× 10 −19 C ion )35.5 eV ionI=7.8×10−13C/sec = 7.8×10−13 A

Conclusion:

Saturation ionization current is 7.8×10−13 A

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Answer 3

Question

Chapter 9, Problem 9.22P

To determine

Saturation ionization current

Expert Solution & Answer

Answer to Problem 9.22P

Saturation ionization current is 7.8×10−13 A

Explanation of Solution

Given:

(370−Bq) 210Po = 370 nucleus disintegrate second

The rate of alpha from source, N=(25%)(370αs )=92.5αs

Kinetic Energy of the alpha particle emitted from ²¹⁰Po, E¯ = 5.3 MeV

The density of air, ρair=1.293×10−3g/cm3=1.293 mg/cm3

Window density thickness, tw = 2 mgcm2

Wall is at 1 cm from source, ta=1 cm

Density thickness of air, td=ρairta=1.293 mgcm3×1 cm=1.293mg/cm2

Mean energy loss per ion-pair, w = 35.5 eVion

Formula used:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2

Where, E is maximum energy of alpha.

Ionization current

I=(Nαs)⋅(E¯ eVα)⋅(1.6× 10 −19C ion )w eV ion ⋅1AC/s

N=Number of alpha particle per second from sourceE¯ = Remaining energy after passing through medium.w = Mean energy loss per ion-pair

Calculation:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2=0.322 (5.3 MeV)3/2=3.93 cm

The range of alpha in areal density,

R=1.293mgcm3×3.93 cm = 5.08mgcm2

Alpha must pass through air and window.

1.293mgcm2+2mgcm2=3.293mgcm2

Alpha particle remaining kinetic energy,

E¯=5.01mg cm2−3.293mg cm25.01mg cm2×5.3MeV=1.816 MeV

Ionization current

I=( N α s )⋅( E ¯ eV α )⋅( 1.6× 10 −19 C ion )w eV ion ⋅1AC/sI=( 92.5 α s )×( 1.81× 10 6 eV α )×( 1.6× 10 −19 C ion )35.5 eV ionI=7.8×10−13C/sec = 7.8×10−13 A

Conclusion:

Saturation ionization current is 7.8×10−13 A

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Answer 4

Question

Chapter 9, Problem 9.22P

To determine

Saturation ionization current

Expert Solution & Answer

Answer to Problem 9.22P

Saturation ionization current is 7.8×10−13 A

Explanation of Solution

Given:

(370−Bq) 210Po = 370 nucleus disintegrate second

The rate of alpha from source, N=(25%)(370αs )=92.5αs

Kinetic Energy of the alpha particle emitted from ²¹⁰Po, E¯ = 5.3 MeV

The density of air, ρair=1.293×10−3g/cm3=1.293 mg/cm3

Window density thickness, tw = 2 mgcm2

Wall is at 1 cm from source, ta=1 cm

Density thickness of air, td=ρairta=1.293 mgcm3×1 cm=1.293mg/cm2

Mean energy loss per ion-pair, w = 35.5 eVion

Formula used:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2

Where, E is maximum energy of alpha.

Ionization current

I=(Nαs)⋅(E¯ eVα)⋅(1.6× 10 −19C ion )w eV ion ⋅1AC/s

N=Number of alpha particle per second from sourceE¯ = Remaining energy after passing through medium.w = Mean energy loss per ion-pair

Calculation:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2=0.322 (5.3 MeV)3/2=3.93 cm

The range of alpha in areal density,

R=1.293mgcm3×3.93 cm = 5.08mgcm2

Alpha must pass through air and window.

1.293mgcm2+2mgcm2=3.293mgcm2

Alpha particle remaining kinetic energy,

E¯=5.01mg cm2−3.293mg cm25.01mg cm2×5.3MeV=1.816 MeV

Ionization current

I=( N α s )⋅( E ¯ eV α )⋅( 1.6× 10 −19 C ion )w eV ion ⋅1AC/sI=( 92.5 α s )×( 1.81× 10 6 eV α )×( 1.6× 10 −19 C ion )35.5 eV ionI=7.8×10−13C/sec = 7.8×10−13 A

Conclusion:

Saturation ionization current is 7.8×10−13 A

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Answer 5

Chapter 9, Problem 9.22P

To determine

Saturation ionization current

Expert Solution & Answer

Answer to Problem 9.22P

Saturation ionization current is 7.8×10−13 A

Explanation of Solution

Given:

(370−Bq) 210Po = 370 nucleus disintegrate second

The rate of alpha from source, N=(25%)(370αs )=92.5αs

Kinetic Energy of the alpha particle emitted from ²¹⁰Po, E¯ = 5.3 MeV

The density of air, ρair=1.293×10−3g/cm3=1.293 mg/cm3

Window density thickness, tw = 2 mgcm2

Wall is at 1 cm from source, ta=1 cm

Density thickness of air, td=ρairta=1.293 mgcm3×1 cm=1.293mg/cm2

Mean energy loss per ion-pair, w = 35.5 eVion

Formula used:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2

Where, E is maximum energy of alpha.

Ionization current

I=(Nαs)⋅(E¯ eVα)⋅(1.6× 10 −19C ion )w eV ion ⋅1AC/s

N=Number of alpha particle per second from sourceE¯ = Remaining energy after passing through medium.w = Mean energy loss per ion-pair

Calculation:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2=0.322 (5.3 MeV)3/2=3.93 cm

The range of alpha in areal density,

R=1.293mgcm3×3.93 cm = 5.08mgcm2

Alpha must pass through air and window.

1.293mgcm2+2mgcm2=3.293mgcm2

Alpha particle remaining kinetic energy,

E¯=5.01mg cm2−3.293mg cm25.01mg cm2×5.3MeV=1.816 MeV

Ionization current

I=( N α s )⋅( E ¯ eV α )⋅( 1.6× 10 −19 C ion )w eV ion ⋅1AC/sI=( 92.5 α s )×( 1.81× 10 6 eV α )×( 1.6× 10 −19 C ion )35.5 eV ionI=7.8×10−13C/sec = 7.8×10−13 A

Conclusion:

Saturation ionization current is 7.8×10−13 A

Answer 6

Chapter 9, Problem 9.22P

To determine

Saturation ionization current

Expert Solution & Answer

Answer to Problem 9.22P

Saturation ionization current is 7.8×10−13 A

Explanation of Solution

Given:

(370−Bq) 210Po = 370 nucleus disintegrate second

The rate of alpha from source, N=(25%)(370αs )=92.5αs

Kinetic Energy of the alpha particle emitted from ²¹⁰Po, E¯ = 5.3 MeV

The density of air, ρair=1.293×10−3g/cm3=1.293 mg/cm3

Window density thickness, tw = 2 mgcm2

Wall is at 1 cm from source, ta=1 cm

Density thickness of air, td=ρairta=1.293 mgcm3×1 cm=1.293mg/cm2

Mean energy loss per ion-pair, w = 35.5 eVion

Formula used:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2

Where, E is maximum energy of alpha.

Ionization current

I=(Nαs)⋅(E¯ eVα)⋅(1.6× 10 −19C ion )w eV ion ⋅1AC/s

N=Number of alpha particle per second from sourceE¯ = Remaining energy after passing through medium.w = Mean energy loss per ion-pair

Calculation:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2=0.322 (5.3 MeV)3/2=3.93 cm

The range of alpha in areal density,

R=1.293mgcm3×3.93 cm = 5.08mgcm2

Alpha must pass through air and window.

1.293mgcm2+2mgcm2=3.293mgcm2

Alpha particle remaining kinetic energy,

E¯=5.01mg cm2−3.293mg cm25.01mg cm2×5.3MeV=1.816 MeV

Ionization current

I=( N α s )⋅( E ¯ eV α )⋅( 1.6× 10 −19 C ion )w eV ion ⋅1AC/sI=( 92.5 α s )×( 1.81× 10 6 eV α )×( 1.6× 10 −19 C ion )35.5 eV ionI=7.8×10−13C/sec = 7.8×10−13 A

Conclusion:

Saturation ionization current is 7.8×10−13 A

Answer 7

Chapter 9, Problem 9.22P

To determine

Saturation ionization current

Answer 8

Expert Solution & Answer

Answer to Problem 9.22P

Saturation ionization current is 7.8×10−13 A

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Given:

(370−Bq) 210Po = 370 nucleus disintegrate second

The rate of alpha from source, N=(25%)(370αs )=92.5αs

Kinetic Energy of the alpha particle emitted from ²¹⁰Po, E¯ = 5.3 MeV

The density of air, ρair=1.293×10−3g/cm3=1.293 mg/cm3

Window density thickness, tw = 2 mgcm2

Wall is at 1 cm from source, ta=1 cm

Density thickness of air, td=ρairta=1.293 mgcm3×1 cm=1.293mg/cm2

Mean energy loss per ion-pair, w = 35.5 eVion

Formula used:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2

Where, E is maximum energy of alpha.

Ionization current

I=(Nαs)⋅(E¯ eVα)⋅(1.6× 10 −19C ion )w eV ion ⋅1AC/s

N=Number of alpha particle per second from sourceE¯ = Remaining energy after passing through medium.w = Mean energy loss per ion-pair

Calculation:

The range (in cm) of air, R_a, at 0°C and 760 mm Hg

Ra=0.322E3/2=0.322 (5.3 MeV)3/2=3.93 cm

The range of alpha in areal density,

R=1.293mgcm3×3.93 cm = 5.08mgcm2

Alpha must pass through air and window.

1.293mgcm2+2mgcm2=3.293mgcm2

Alpha particle remaining kinetic energy,

E¯=5.01mg cm2−3.293mg cm25.01mg cm2×5.3MeV=1.816 MeV

Ionization current

I=( N α s )⋅( E ¯ eV α )⋅( 1.6× 10 −19 C ion )w eV ion ⋅1AC/sI=( 92.5 α s )×( 1.81× 10 6 eV α )×( 1.6× 10 −19 C ion )35.5 eV ionI=7.8×10−13C/sec = 7.8×10−13 A