The closest approach that a 5.3 MeV alpha particle can make to a gold nucleus.

Question

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Answer 1

Question

Chapter 3, Problem 3.1P

To determine

The closest approach that a 5.3 MeV alpha particle can make to a gold nucleus.

Expert Solution & Answer

Answer to Problem 3.1P

d=4.29×10−14m

Explanation of Solution

Introduction:

When an alpha particle having kinetic energy ‘E_a’and charge ‘q’ is ejected on a gold nucleus, it undergoes repulsion. The force of repulsion increases with the decreasing distance between the two. On reaching the closest distance of approach ( d ), the total kinetic energy converts into potential energy hence, it comes to rest.

Formula:

d=(14πε0)qQEa

Consider an alpha particle of energy Ea=5.3 MeV= (5.3×106×1.6×10−19)

Using the formula, we get:

d=(14πε0)qQEa

d=9×109(2×1.6× 10 −19×79×1.6× 10 −195.3×10×61.6× 10 −19)

d=4.29×10−14m

Conclusion:

Therefore, the closest distance of approach ( d ) for a 5.3 MeV alpha particle is: d=4.29×10−14m .

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The isotope of Nickel, 66Ni decays by β emission, has a half-life of 2.3 days. and the β particles have an average energy of 65 keV. A source consisting of this isotope has an initial number of atoms N0 = 5 x 1020 atoms. What is the power per unit area initially deposited by this source in a small target placed at 1m distance from the source? Select one: a. 1.45 W/m2 b. 7.6 MW/m2 c. 4.5 kW/m2 d. 35 W/m2

Answer 2

Question

Chapter 3, Problem 3.1P

To determine

The closest approach that a 5.3 MeV alpha particle can make to a gold nucleus.

Expert Solution & Answer

Answer to Problem 3.1P

d=4.29×10−14m

Explanation of Solution

Introduction:

When an alpha particle having kinetic energy ‘E_a’and charge ‘q’ is ejected on a gold nucleus, it undergoes repulsion. The force of repulsion increases with the decreasing distance between the two. On reaching the closest distance of approach ( d ), the total kinetic energy converts into potential energy hence, it comes to rest.

Formula:

d=(14πε0)qQEa

Consider an alpha particle of energy Ea=5.3 MeV= (5.3×106×1.6×10−19)

Using the formula, we get:

d=(14πε0)qQEa

d=9×109(2×1.6× 10 −19×79×1.6× 10 −195.3×10×61.6× 10 −19)

d=4.29×10−14m

Conclusion:

Therefore, the closest distance of approach ( d ) for a 5.3 MeV alpha particle is: d=4.29×10−14m .

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Answer 3

Question

Chapter 3, Problem 3.1P

To determine

The closest approach that a 5.3 MeV alpha particle can make to a gold nucleus.

Expert Solution & Answer

Answer to Problem 3.1P

d=4.29×10−14m

Explanation of Solution

Introduction:

When an alpha particle having kinetic energy ‘E_a’and charge ‘q’ is ejected on a gold nucleus, it undergoes repulsion. The force of repulsion increases with the decreasing distance between the two. On reaching the closest distance of approach ( d ), the total kinetic energy converts into potential energy hence, it comes to rest.

Formula:

d=(14πε0)qQEa

Consider an alpha particle of energy Ea=5.3 MeV= (5.3×106×1.6×10−19)

Using the formula, we get:

d=(14πε0)qQEa

d=9×109(2×1.6× 10 −19×79×1.6× 10 −195.3×10×61.6× 10 −19)

d=4.29×10−14m

Conclusion:

Therefore, the closest distance of approach ( d ) for a 5.3 MeV alpha particle is: d=4.29×10−14m .

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Answer 4

Question

Chapter 3, Problem 3.1P

To determine

The closest approach that a 5.3 MeV alpha particle can make to a gold nucleus.

Expert Solution & Answer

Answer to Problem 3.1P

d=4.29×10−14m

Explanation of Solution

Introduction:

When an alpha particle having kinetic energy ‘E_a’and charge ‘q’ is ejected on a gold nucleus, it undergoes repulsion. The force of repulsion increases with the decreasing distance between the two. On reaching the closest distance of approach ( d ), the total kinetic energy converts into potential energy hence, it comes to rest.

Formula:

d=(14πε0)qQEa

Consider an alpha particle of energy Ea=5.3 MeV= (5.3×106×1.6×10−19)

Using the formula, we get:

d=(14πε0)qQEa

d=9×109(2×1.6× 10 −19×79×1.6× 10 −195.3×10×61.6× 10 −19)

d=4.29×10−14m

Conclusion:

Therefore, the closest distance of approach ( d ) for a 5.3 MeV alpha particle is: d=4.29×10−14m .

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Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 5

Chapter 3, Problem 3.1P

To determine

The closest approach that a 5.3 MeV alpha particle can make to a gold nucleus.

Expert Solution & Answer

Answer to Problem 3.1P

d=4.29×10−14m

Explanation of Solution

Introduction:

When an alpha particle having kinetic energy ‘E_a’and charge ‘q’ is ejected on a gold nucleus, it undergoes repulsion. The force of repulsion increases with the decreasing distance between the two. On reaching the closest distance of approach ( d ), the total kinetic energy converts into potential energy hence, it comes to rest.

Formula:

d=(14πε0)qQEa

Consider an alpha particle of energy Ea=5.3 MeV= (5.3×106×1.6×10−19)

Using the formula, we get:

d=(14πε0)qQEa

d=9×109(2×1.6× 10 −19×79×1.6× 10 −195.3×10×61.6× 10 −19)

d=4.29×10−14m

Conclusion:

Therefore, the closest distance of approach ( d ) for a 5.3 MeV alpha particle is: d=4.29×10−14m .

Answer 6

Chapter 3, Problem 3.1P

To determine

The closest approach that a 5.3 MeV alpha particle can make to a gold nucleus.

Expert Solution & Answer

Answer to Problem 3.1P

d=4.29×10−14m

Explanation of Solution

Introduction:

When an alpha particle having kinetic energy ‘E_a’and charge ‘q’ is ejected on a gold nucleus, it undergoes repulsion. The force of repulsion increases with the decreasing distance between the two. On reaching the closest distance of approach ( d ), the total kinetic energy converts into potential energy hence, it comes to rest.

Formula:

d=(14πε0)qQEa

Consider an alpha particle of energy Ea=5.3 MeV= (5.3×106×1.6×10−19)

Using the formula, we get:

d=(14πε0)qQEa

d=9×109(2×1.6× 10 −19×79×1.6× 10 −195.3×10×61.6× 10 −19)

d=4.29×10−14m

Conclusion:

Therefore, the closest distance of approach ( d ) for a 5.3 MeV alpha particle is: d=4.29×10−14m .

Answer 7

Chapter 3, Problem 3.1P

To determine

The closest approach that a 5.3 MeV alpha particle can make to a gold nucleus.

Answer 8

Expert Solution & Answer

Answer to Problem 3.1P

d=4.29×10−14m

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

Explanation of Solution

Introduction:

When an alpha particle having kinetic energy ‘E_a’and charge ‘q’ is ejected on a gold nucleus, it undergoes repulsion. The force of repulsion increases with the decreasing distance between the two. On reaching the closest distance of approach ( d ), the total kinetic energy converts into potential energy hence, it comes to rest.

Formula:

d=(14πε0)qQEa