Presentation is loading. Please wait.

Presentation is loading. Please wait.

The Radioactive Decay model.. In this presentation we will learn: 1.What is meant by the terms Probability of decay per second Activity Radioactive decay.

Published byStephanie Booker Modified over 8 years ago

Similar presentations

Presentation on theme: "The Radioactive Decay model.. In this presentation we will learn: 1.What is meant by the terms Probability of decay per second Activity Radioactive decay."— Presentation transcript:

1 The Radioactive Decay model.

2 In this presentation we will learn: 1.What is meant by the terms Probability of decay per second Activity Radioactive decay constant Becquerel 2. A simple mathematical model of how radioactive elements decay.

3 The decay of a radioactive element is totally random. (Rutherford found this hard to believe. He tried heating, pressure, cooling – to no avail). A particle has a small probability of being emitted from a nucleus in a given time. There is just one rule for each nucleus: It can decay with a fixed probability in a given time.

4 Predict a result when decay occurs. What happens to the population? It declines…….. …….the number left to decay gets less and less. But…the number decaying (proportional to the number left behind) also gets less. The population decline gets slower and slower. We’ll be dealing with a RATE of decline, which means using small time-chunks (  t).

5 It’s important to understand the idea of PROBABILITY of decay and PROBABILITY of decay PER SECOND. If each nucleus has a probability p to decay, and there are N nuclei at any moment, Number decaying = p N The longer you wait, the more chance there is for a decay. p   t p =  t p =  t is called the DECAY CONSTANT in s -1 is called the DECAY CONSTANT in s -1

6 This may seem confusing, so think of the decay constant as THE CHANCE OF DECAY IN ONE SECOND. Activity The activity of a radioactive source is THE NUMBER OF NUCLEI DECAYING PER SECOND. (UNITS: Bq or Bequerels) We can now link activity to probability. Activity a = NNNN tttt no. decaying per second

7 But p N =  t N So, Activity a =  t N  t N tttt And so a = N If you know the activity of the source and the number of nuclei (using Avogadro’s number) you can find the decay constant for any radioactive material. This is a very useful constant, as we shall find out later.

8 Fading away……. The number of nuclei present at any moment decreases at a rate equal to the activity. NNNN tttt = - N N = activity N = activity decay Differential of N wrt time

9 This equation captures the SMOOTH behaviour of decay. It works for many different types of decay – a very useful MODEL. This sort of equation, involving the RATE of CHANGE of a quantity, is called a DIFFERENTIAL EQUATION. It works for GROWTH as well as DECAY; just use a + instead of a – sign.

Download ppt "The Radioactive Decay model.. In this presentation we will learn: 1.What is meant by the terms Probability of decay per second Activity Radioactive decay."

Similar presentations

Radioactivity. Radioactivity – Particles are emitted from an unstable nuclei. positron High Energy Photons gamma β-β- Beta αAlpha symbolName β+β+

Radioactivity. Radioactivity – Particles are emitted from an unstable nuclei. positron High Energy Photons gamma β-β- Beta αAlpha symbolName β+β+
Ch 6.4 Exponential Growth & Decay Calculus Graphical, Numerical, Algebraic by Finney Demana, Waits, Kennedy.

Ch 6.4 Exponential Growth & Decay Calculus Graphical, Numerical, Algebraic by Finney Demana, Waits, Kennedy.
Radiometric Dating Half-life.

Radiometric Dating Half-life.
Exponential Growth and Decay

Exponential Growth and Decay
Do Now read page 43-44 Please open your books to show your half life graphs.

Do Now read page Please open your books to show your half life graphs.
- Composition Notebook Isotopes are atoms of the same element that have a different number of neutrons in their nuclei.

- Composition Notebook Isotopes are atoms of the same element that have a different number of neutrons in their nuclei.
Radioactive Decay Nuclear Physics Lesson 5. Learning Objectives Explain what is meant by the term half-life. Explain what is meant by the term half-life.

Radioactive Decay Nuclear Physics Lesson 5. Learning Objectives Explain what is meant by the term half-life. Explain what is meant by the term half-life.
Diff EQs 6.6. Common Problems: Exponential Growth and Decay Compound Interest Radiation and half-life Newton’s law of cooling Other fun topics.

Diff EQs 6.6. Common Problems: Exponential Growth and Decay Compound Interest Radiation and half-life Newton’s law of cooling Other fun topics.
The structure of nuclei Nuclei are composed of just two types of particles: protons and neutrons. These particles are referred to collectively as nucleons.

The structure of nuclei Nuclei are composed of just two types of particles: protons and neutrons. These particles are referred to collectively as nucleons.
LOJ Feb 2004 Radioactivity 1 What is radioactive decay?

LOJ Feb 2004 Radioactivity 1 What is radioactive decay?
Nuclear Reactions Emissions, Balancing, and predicting decays of Nuclear Reactions.

Nuclear Reactions Emissions, Balancing, and predicting decays of Nuclear Reactions.
Lecture 365/2/05 Tuesday 2:30 TSB 006. What does it mean to be radioactive?

Lecture 365/2/05 Tuesday 2:30 TSB 006. What does it mean to be radioactive?
Copyright © Cengage Learning. All rights reserved.

Copyright © Cengage Learning. All rights reserved.
PH 103 Dr. Cecilia Vogel Lecture 23. Review Outline  Nuclei   decays  Radiation damage  Nuclear physics  exponential decay  decay constant.

PH 103 Dr. Cecilia Vogel Lecture 23. Review Outline  Nuclei   decays  Radiation damage  Nuclear physics  exponential decay  decay constant.
What are we doing today Decay Types of Radiation Properties of nuclear radiation Decay and Probability Protactinium.

What are we doing today Decay Types of Radiation Properties of nuclear radiation Decay and Probability Protactinium.
6. Atomic and Nuclear Physics Chapter 6.6 Nuclear Physics.

6. Atomic and Nuclear Physics Chapter 6.6 Nuclear Physics.
Nuclear Chemistry By Robert Jakubek and Michael Maki.

Nuclear Chemistry By Robert Jakubek and Michael Maki.
Radioactivity refresher Radiation Protection of the Environment (Environment Agency Course, July 2015)

Radioactivity refresher Radiation Protection of the Environment (Environment Agency Course, July 2015)
1 Chapter 31 Nuclear Physics and Radioactivity. 2 1. Nuclear Structure a)Proton - positive charge - mass 1.673 x 10 -27 kg ≈ 1 u b) Neutron - discovered.

1 Chapter 31 Nuclear Physics and Radioactivity Nuclear Structure a)Proton - positive charge - mass x kg ≈ 1 u b) Neutron - discovered.
Warmup 1) 2). 6.4: Exponential Growth and Decay The number of bighorn sheep in a population increases at a rate that is proportional to the number of.

Warmup 1) 2). 6.4: Exponential Growth and Decay The number of bighorn sheep in a population increases at a rate that is proportional to the number of.

Similar presentations

Ads by Google