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Chapter 10: Q9Q (page 410)

Give an example of what we can learn about matter through the use of momentum and energy conservation applied to scattering experiments. Explain what it is that we cannot learn this way, for which we need to measure the distribution of scattering angles.

Short Answer

Expert verified

A matter can be analyzed by scattering experiments like the structure of atoms

Step by step solution

01

Given information

The momentum and energy conservation applied to scattering experiments.

02

The concept of conservation of momentum and energy

The law of conservation of momentum asserts that if a system of bodies has no net external forces acting on it, the total momentum remains constant at all times (it is conserved). If all forces, external or internal, can be given a potential, then the total energy remains constant as well.

03

The merits and demerits for what we can learn about matter through the use of momentum and energy conservation applied to scattering experiment

Scattering tests can be used to identify subatomic particles and disclose the structure and behavior of atoms, nuclei, and other tiny particles in matter. (For example, Rutherford identified the nucleus by measuring alpha particle scattering against a very thin gold foil, using the momentum conservation principle).

Scattering angle distributions provide a broader view of the situation (for example, the relative sizes, the incident flux and angular size)

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Most popular questions from this chapter

A uranium atom traveling at speed4ร—104m/scollides elastically with a stationary hydrogen molecule, head-on. What is the approximate final speed of the hydrogen molecule?

Consider a head-on collision between two objects. Object 1, which has mass m1, is initially in motion, and collides head-on with object 2, which has massm2and is initially at rest. Which of the following statements about the collision are true?

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(4) Ifm1โ‰ซm2, then the final speed of object 2 is less than the initial speed of object 1.

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