Question

In the late 19th century, great interest was directed toward the study of electrical discharges in gases and the nature of so-called cathode rays. One remarkable series of experiments with cathode rays, conducted by J. J. Thomson around 1897, led to the discovery of the electron.

With the idea that cathode rays were charged particles, Thomson used a cathode-ray tube to measure the ratio of charge to mass, q/m, of these particles, repeating the measurements with different cathode materials and different residual gases in the tube.

Part A

What is the most significant conclusion that Thomson was able to draw from his measurements?

a. He found a different value of q/m for different cathode materials.
b. He found the same value of q/m for different cathode materials.
c. From measurements of q/m he was able to calculate the charge of an electron.
d. From measurements of q/m he was able to calculate the mass of an electron.

Part B

What is the distance Δy between the two points that you observe? Assume that the plates have length d, and use e and m for the charge and the mass of the electrons, respectively.

Express your answer in terms of e, m, d, v0, L, and E0.

Part C

Now imagine that you place your entire apparatus inside a region of magnetic field of magnitude B0 (Figure 2) . The magnetic field is perpendicular to E⃗ 0 and directed straight into the plane of the figure. You adjust the value of B0 so that no deflection is observed on the screen.

What is the speed v0 of the electrons in this case?

Express your answer in terms of E0 and B0.

Part D

In your experiment, you measure a total deflection of 4.12 cm when an electric field of 1.10×103V/m is established between the plates (with no magnetic field present). When you add the magnetic field as described in Part C, to what value do you have to adjust its magnitude B0 to observe no deflection?

Assume that the plates are 6.00 cm long and that the distance between them and the screen is 12.0 cm.

Express your answer numerically in tesla.

Answer 1

b. He found the same value of q/m for different cathode materials

Step-by-step explanation:

The correct answer is b. He found the same value of q/m for different cathode materials.

As stated in the question Thomson thought the cathode rays were charged particle. From his experiments he was able to show that the particles in his cathode rays were negatively charged.

He went on to calculate the ratio q/m (charge to mass) by measuring amounts of delflection of the cathode beams.

By utilizing different cathode materials and different gases, he found that q/m was independent of both suggesting that the particles were fundamental and the same for all atoms, as the electron is a an elementary fundamental particle.

As you can conclude a. is false since it is the opposite of the experimental result.

c, d are also false.

Thomson found the ratio q/m, and it was until MIlikans oil dro experiment experiment that the determination of the charge of the electron was made.