Chapter 25 Nuclear Chemistry

25.2 Nuclear Transformations

Chemistry

Today we are learning to:-

1. See what determines the type of decay a radioisotope

undergoes

2. Understand what we mean by the term half-life

3. Calculate how much of a sample remains after each half-life

4. Understand the 2 ways that transmutation reactions can occur

A force called the nuclear force is responsible for holding the nuclei of

atoms together. It is stronger than the electromagnetic force over extremely

short distances, so nuclei don’t fly apart (1.7fm) (1 femtometer = 1.0 x 10−15

meters or 0.000,000,000,000,001,7m).

More than 1,500 different nuclei are known. Of those, only 264 are stable

and do not decay or change with time. These nuclei are in a region called the

band of stability.

Nuclear TransformationsNuclear Stability and Decay

Nuclear Stability and DecayNuclear Transformations

Nuclear Stability and DecayNuclear Transformations

A nucleus lying outside the band of stability will be unstable and decay into

a more stable isotope

The neutron-to-proton ratio determines the type of decay that occurs

If a nucleus has too many neutrons, a neutron can change into a proton

and a high energy electron (beta particle) is shot out of the nucleus.

1 1 0

n → p + e0 +1 -1

Nuclear Stability and DecayNuclear Transformations

Other types of decay processes other than alpha emission and beta emission

are:

i. Electron capture: where an electron captured by a nucleus

transforms a proton into a neutron.

ii. Positron emission: Where a proton in the nucleus changes into

a neutron with the emission of a positively charged electron (positron).

1 0 1

p + e → n+1 -1 0

1 1 0

p → n + e+1 0 +1

Nuclear Stability and Decay25.2

Homework questions: Answer Questions 33-37 on page 821 of your text book for next day (use a periodic table to help identify products.)

Half-LifeNuclear Transformations

The rate of decay of an unstable radioisotope is measured by its half-life

A half-life (t1/2) is the time required for one-half of the nuclei of a

radioisotope sample to decay to products

After each half-life, half of the existing radioactive atoms have decayed into

atoms of a new element.

Half-lives can range from fractions of a second to billions of years

Nuclear TransformationsHalf-Life

Nuclear TransformationsHalf-Life

Half-Life25.2

Stable Isotope

Uranium 238 decays through a series of unstable isotopes until it reaches the stable isotope of lead-206.Because of the long half live of uranium -238 its ratio to other isotopes in rocks can be used to date them.

Half-LifeNuclear Transformations

The ratio of Carbon-14 to stable carbon in the remains of an organism changes in a predictable way that enables the archaeologist to obtain an estimate of its age.

Carbon-14 dating (detailed)

Carbon-14 dating (simple)

25.1

for Sample Problem 25.1

Practice Problem (page 806).

Homework: Questions 46, 50, 54, 55, 57, 58, 60, 61 and 65On pages 882-883 of your Chemistry text book.

Transmutation Reactions

The conversion of one atom of one element to a different element is called

transmutation

Transmutation can occur by:

i. radioactive decay

ii. when particles bombard the nucleus of an atom.

The first artificial transmutation reaction involved bombarding nitrogen

gas with alpha particles.

Transmutation Reactions

25.1

• The first artificial transmutation reaction involved bombarding nitrogen gas with alpha particles.

Transmutation ReactionsNuclear Transformations

Transmutation ReactionsNuclear Transformations

Bombardment by alpha particle:

14  7

N + 42 He → 17

  8O +

11

H

9  4

Be + 42 He → 12

  6C +

10

n

Ex. 1.

Ex. 2.

• The elements in the periodic table with atomic numbers above 92, the atomic number of uranium, are called the transuranium elements.

» All transuranium elements undergo transmutation.

» None of the transuranium elements occur in nature, and all of them are radioactive.

» Transuranium elements are synthesized in nuclear reactors and nuclear accelerators.

25.2 Section Quiz.

1. During nuclear decay, if the atomic number decreases by one but the mass number is unchanged, the radiation emitted is

a. a positron.

b. an alpha particle.

c. a neutron.

d. a proton.

25.2 Section Quiz.

2. When potassium-40 (atomic number 19) decays into calcium-40 (atomic number 20), the process can be described as

a. positron emission.

b. alpha emission.

c. beta emission.

d. electron capture.

25.2 Section Quiz.

3. If there were 128 grams of radioactive material initially, what mass remains after four half-lives?

a. 4 grams

b. 16 grams

c. 8 grams

d. 32 grams

25.2 Section Quiz.

4. When transmutation occurs, the ________ always changes.

a. number of electrons

b. mass number

c. atomic number

d. number of neutrons

25.2 Section Quiz

5. Transmutation occurs by radioactive decay and also by

a. extreme heating.

b. chemical reaction.

c. high intensity electrical discharge.

d. particle bombardment of the nucleus.

2.3 Vocabulary 25.1 Vocabulary• Radioactivity: process where materials give off high energy rays• Radiation: name give to these penetrating rays and particles• Radioisotopes: unstable isotopes that will decay into a different element• Alpha particle: high energy helium nuclei containing 2 protons and 2

neutrons• beta particle: high energy electron emitted from a nucleus• Gamma particle: high energy electromagnetic radiation emitted from a

nucleus

25.2 Vocabulary• Nuclear force: attractive force acting between nuclear particles close

together• Band of stability: region of stable isotopes• Positron: particle with the mass of an electron but a +1 charge• Half-life: time taken for half of a radioisotope to decay• Transmutation: conversion of an atom of one element to an atom of another• Transuranium element: elements with atomic numbers above 92

END OF SHOW