Presentation is loading. Please wait.

Presentation is loading. Please wait.

Example Example 1: A number of lead blocks and aluminium plates are placed in front of a radioactive source. The source emits ,  and  radiation.

Published byVivian Butler Modified over 5 years ago

Similar presentations

Presentation on theme: "Example Example 1: A number of lead blocks and aluminium plates are placed in front of a radioactive source. The source emits ,  and  radiation."— Presentation transcript:

1 Example Example 1: A number of lead blocks and aluminium plates are placed in front of a radioactive source. The source emits ,  and  radiation.

2 Example 1 mm aluminium plate 5 mm aluminium plate Lead blocks
Radioactive source X Y Z GM counter GM tube

3 Example a) What is the function of the two lead blocks?
The lead blocks provide a narrow opening through which the radiation passes. This prevents scattering of the particles.

4 Example b) What kind(s) of radiation can be found between X and Y?
Only  and  radiation are found between X and Y because the  particles are stopped by the 1mm thick aluminium plate.

5 Example c) What would happen to the count rate if the detector were placed at Z? If the detector were at Z, the count rate would drop because the  particles are stopped by the 5 mm thick aluminium plate. However, we can still detect  radiation.

6 Example d) Explain briefly why the Geiger-Muller counter still records some counts when the radioactive source is removed. When the radioactive source is removed, the Geiger-Muller counter still records the background radiation.

7 Example Example 2: In a paper-making factory, the thickness of the paper produced is detected using a  source and a detector, as shown.

8 Example radioactive source paper feeding through rollers rollers
GM tube GM counter

9 Example a) Explain how changes in the thickness of the paper can be detected.  particles do not have great penetrating power so any change in the thickness of the paper will affect the number of particles that reaches the counter.

10 Example b) Why are  and  sources not suitable for this process?
 particles would be absorbed by the paper.  rays would not be stopped by the paper at all because of its high penetrating power.

11 Example Example 3: A Geiger-Muller tube is placed at Y, 25 cm from a radioactive source that emits ,  and  radiation. lead container GM tube radioactive source S Y 25 cm

12 Example a) What is the purpose of the lead container?
The lead container prevents scattering of the radiation. b) What possible types of radiation may be received by the Geiger-Muller tube? The possible types of radiation received are  and  radiation.

13 Example c) (i) When a magnetic field is applied at right angles to the page, as shown below, the recorded count rate is reduced. Explain briefly. lead container GM tube X Y S Z radioactive source magnetic field pointing out of paper

14 Example magnetic field pointing out of paper radioactive source lead container GM tube S X Y Z The count rate drops because the  and  particles are deflected by the magnetic field.

15 Example c) (ii) What happens to the count rate when the Geiger-Muller tube is placed at X and Z? At X, only the  radiation is recorded, so the count rate is lower. At Z, only the background radiation is recorded, which is much lower.

16 Example d) If a sheet of lead about 25 mm thick is placed in front of the Geiger-Muller tube at position Y, what happens to the recorded count rate? 25 mm of lead will block half of the  rays, so the recorded count rate will be halved. End

Download ppt "Example Example 1: A number of lead blocks and aluminium plates are placed in front of a radioactive source. The source emits ,  and  radiation."

Similar presentations

Radiation True or False?

Radiation True or False?
Radioactivity 1 輻 射 Presented by Mr. Y. N. Chan LIU PO SHAN MEMORIAL COLLEGE.

Radioactivity 1 輻 射 Presented by Mr. Y. N. Chan LIU PO SHAN MEMORIAL COLLEGE.
Causal Explanation. As shown in the figure, a beam of α-particles emitted from a radioactive resource enters the space between a pair of metal plates.

Causal Explanation. As shown in the figure, a beam of α-particles emitted from a radioactive resource enters the space between a pair of metal plates.
Radioactivity Radiation: –stream of particles/waves Radioactive Materials: –material that emit penetrating/dangerous radiation –radiation comes from nucleus.

Radioactivity Radiation: –stream of particles/waves Radioactive Materials: –material that emit penetrating/dangerous radiation –radiation comes from nucleus.
Radioactivity.

Radioactivity.
Radiation Detector 3 Gold Leaf electroscope Geiger Muller Tube.

Radiation Detector 3 Gold Leaf electroscope Geiger Muller Tube.
Trefoil Symbol – symbol for ionising radiation The Discovery of Radioactivity Henri Becquerel (1896): Investigated the effect of sunlight on crystals.

Trefoil Symbol – symbol for ionising radiation The Discovery of Radioactivity Henri Becquerel (1896): Investigated the effect of sunlight on crystals.
Radiation L.O: Describe an isotope understand properties of alpha, beta and gamma radiation Explain background radiation.

Radiation L.O: Describe an isotope understand properties of alpha, beta and gamma radiation Explain background radiation.
Alpha, Beta and Gamma Radiation

Alpha, Beta and Gamma Radiation
1 Alpha Emissions (How a Smoke Alarm Works). 2 Radioactive Emissions (Radiation) Penetrating Power SymbolEquivalentDescriptionType He Stopped by thick.

1 Alpha Emissions (How a Smoke Alarm Works). 2 Radioactive Emissions (Radiation) Penetrating Power SymbolEquivalentDescriptionType He Stopped by thick.
Unit P2 - Radiation Lesson 01 – Introduction to Radiation

Unit P2 - Radiation Lesson 01 – Introduction to Radiation
Radioactivity I §Content: §Radioactive substance §Three types of radiation §Properties of radiation §To investigate the radiation by apparatus §To summarize.

Radioactivity I §Content: §Radioactive substance §Three types of radiation §Properties of radiation §To investigate the radiation by apparatus §To summarize.
To know how different forms of radiation behave. Who am I? 1.Not dangerous from a distance. 2.Travels as a wave. 3.Can pass through paper. 4.Has a helium.

To know how different forms of radiation behave. Who am I? 1.Not dangerous from a distance. 2.Travels as a wave. 3.Can pass through paper. 4.Has a helium.
Unstable nuclei Some nuclei are unstable, for example Uranium 235 (it’s to do with the relative numbers of protons and neutrons) Hi! I’m uranium-235 and.

Unstable nuclei Some nuclei are unstable, for example Uranium 235 (it’s to do with the relative numbers of protons and neutrons) Hi! I’m uranium-235 and.
Genre Exercise ︰ Rearranging sentences. Exercise ︰ Rearranging sentences The set-up as shown in the following figure is used to study β radiation emitted.

Genre Exercise ︰ Rearranging sentences. Exercise ︰ Rearranging sentences The set-up as shown in the following figure is used to study β radiation emitted.
Uses of Radioactivity • Measuring the thickness of foil

Uses of Radioactivity • Measuring the thickness of foil
Beta and paper mills.

Beta and paper mills.
Do now! Can you look through your books and read the comments? Can you also look through the tests and make sure that Ms Lee has added the marks up correctly?

Do now! Can you look through your books and read the comments? Can you also look through the tests and make sure that Ms Lee has added the marks up correctly?
19.3 Detection of radioactivity

19.3 Detection of radioactivity
The atom orbiting electrons Nucleus (protons and neutrons)

The atom orbiting electrons Nucleus (protons and neutrons)

Similar presentations

Ads by Google