Radioactivity Clip.

Slides:



Advertisements
Similar presentations
AMOLE Radioactivity. Science Park HS -- Honors Chemistry Early Pioneers in Radioactivity Roentgen: Discoverer of X- rays 1895 Becquerel: Discoverer of.
Advertisements

Chapter 9 pages And Chapter 18 pages
DIFFERENTIATE BETWEEN FISSION AND FUSION.
Radiation: Particles and Energy.
Nuclear Chemistry Nuclear chemistry is the study of the structure of atomic nuclei and the changes they undergo.
Anatomy of an Atom Parts of an Atom Nucleus (positive, mass of 1 amu) Neutron (, mass of 1 amu) Electron Cloud Electrons (, negligible mass)
1. 1. Differentiate among alpha and beta particles and gamma radiation. 2. Differentiate between fission and fusion. 3. Explain the process half-life.
1 Nuclear Changes Physical Science Chapter Radioactive decay  The spontaneous breaking down of a nucleus into a slightly lighter nucleus, accompanied.
Radioactivity SPS3. Students will distinguish the characteristics and components of radioactivity. Differentiate among alpha and beta particles and gamma.
Radioactivity!.
Section 1Nuclear Changes Section 1: What is Radioactivity?
Clip. Radiation Radiation: The process of emitting energy in the form of waves or particles.
Radioactivity Nucleus – center of the atom containing protons and neutrons –How are the protons and neutrons held together? Strong Force - an attractive.
Chapter 10 Nuclear Chemistry.
1 Clip. 1. Differentiate among alpha and beta particles and gamma radiation. 2. Differentiate between fission and fusion. 3. Explain the process half-life.
Nuclear Chemistry. Radioactivity The process by which materials give off such rays radioactivity; the rays and particles emitted by a radioactive source.
NUCLEAR CHANGES. Nuclear Radiation Radioactivity: process by which an unstable nucleus emits one or more particles or energy in the form of electromagnetic.
1 Clip. 1. Differentiate among alpha and beta particles and gamma radiation. 2. Differentiate between fission and fusion. 3. Explain the process half-life.
Radioactivity Elements that emit particles and energy from their nucleus are radioactive. Some large atoms are unstable and cannot keep their nucleus together.
1 Clip. 1. Differentiate among alpha and beta particles and gamma radiation. 2. Differentiate between fission and fusion. 3. Explain the process half-life.
What is radiation  A form of energy that can move through empty space.  Transfer of energy by electromagnetic waves.
Unit 4 Lesson 3 Nuclear Reactions
Radioactivity Clip.
CONCURRENT ENROLLMENT CHEMISTRY
Radioactivity Nucleus – center of the atom containing protons and neutrons How are the protons and neutrons held together? Strong Force - an attractive.
Radioactivity Clip.
Chapter 9 – Radioactivity and Nuclear Reactions
Chapter 19 Radioactivity
Unit 4 Lesson 3 Nuclear Reactions
Chemistry Nuclear Chemistry.
The Atomic Nucleus & Radioactive Decay
GET fill in the blank notes and let’s start
Radioactive Decay.
Nuclear Chemistry.
Radioactivity Clip.
Radioactive Decay.
Nuclear Radiation.
The Atomic Nucleus & Radioactive Decay
Radioactivity.
Nuclear Chemistry.
25.3 Fission and Fusion of Atomic Nuclei
Nuclear Decay Song on Youtube
E = mc2 If you can’t explain it simply, you haven’t learned it well enough. Einstein.
RADIOACTIVITY.
Physics 1: Warm-Up 1/4/17 What are the parts of the atom? Draw a diagram. What is atomic mass? What is atomic number? What is an isotope?
Chapter 4: Atomic Energy
Nuclear Reactions.
Satish Pradhan Dnyanasadhana college, Thane
Notes Nuclear Chemistry
Radioactive Decay Section 21.2.
Nuclear Chemistry.
Radioactivity Clip.
Radioactivity Clip.
Radioactivity.
Nuclear Decay Song on Youtube
Nuclear Radiation GPS:
Chapter 16 Radioactivity.
Radioactivity If a nucleus is radioactive it is unstable and will decay (breakdown), which causes the nucleus to change and release energy as radiation.
Radioactivity Henri Becquerel discovered X-rays in As a result of his experiments, he also discovered other forms of rays that could be emitted.
Unit: Nuclear Chemistry
Unit 4 Lesson 3 Nuclear Reactions
Radioactivity.
Chapter 14.4 Learning Goals
Radioactivity Clip.
RADIOACTIVITY.
Fission & Fusion.
Part 5: Radioactive Decay
Alpha, Beta, and Gamma Decay
Unit: Nuclear Chemistry
Nuclear Chemistry Bravo – 15,000 kilotons.
Presentation transcript:

Radioactivity Clip

1 . Differentiate among alpha and beta particles and gamma radiation . 2 . Differentiate between fission and fusion . 3 . Explain the process half-life as related to radioactive decay . 4. Describe nuclear energy , its practical application as an alternative energy source , and its potential problems.

Stability Atomic Stability Equal protons and electrons Ions (+/-) Nuclei Stability The ratio of neutrons to protons is related to the stability of the nucleus 1:1 (N:P+) in less massive elements 3:2 (N:P+) in heavier elements Small Nuclei (under 83 protons) tend to be more stable due to strong forces Nuclei with too many / too few neutrons compared to protons are unstable Atoms with unstable Nuclei are known as Radioactive

After decaying, radioactive atoms “change” into other atoms Radioactivity is the spontaneous disintegration of atomic nuclei. The nucleus emits α particles, ß particles, or electromagnetic rays during this process. After decaying, radioactive atoms “change” into other atoms Clip

Why does the atom do this? the nucleus of an atom attempts to become more stable In some instances, a new element is formed and in other cases, a new form of the original element, called an isotope, appears. this process of change is often referred to as the decay of atoms. The rate of Radioactive decay is described in half-lives.

Energy is released during radioactive decay

TED ed: Radioactivity: Expect the Unexpected

Types of Nuclear Radiation When an unstable nucleus decays, particles and energy are given off from the decaying nucleus. α and β radiation is in the form of particles γ radiation is in the form of waves-kind of like light but higher frequency TED ed video Clip

Neutron decays into a proton & an electron is given off Nuclear Decay 2 protons & 2 neutrons Neutron decays into a proton & an electron is given off Only Energy is release

Alpha particles consist of two protons and two neutrons, identical to the nucleus of a helium atom. A sheet of paper or a person’s surface layer of skin will stop them. Alpha particles are only considered hazardous to a person’s health if they are ingested or inhaled and thus come into contact with sensitive cells such as in the lungs, liver and bones. 8

Beta particles are electrons emitted from the nuclei of many fission products. They can travel a few feet in air but can usually be stopped by clothing or a few centimeters of wood. They are considered hazardous mainly if ingested or inhaled, but can cause radiation damage to the skin if the exposure is large enough. Unstable Neutron decays into a proton.

Gamma rays are a form of electromagnetic radiation (like light, radio, and television) that come from the nucleus of a radioactive atom. Occurs when an unstable nucleus emits electromagnetic radiation. The radiation has no mass, and so its emission does not change the element. They penetrate matter easily and are best stopped by water or thick layers of lead or concrete. Gamma radiation is hazardous to people inside and outside of the body. However, gamma radiation often accompanies alpha and beta emission, which do change the element's identity. Gamma rays have the lowest ionizing power, but the highest penetrating power.

Biological Effects of Radiation: Ionizing radiation causes physical damage to cells and DNA. Radiation can excite DNA and result in the destruction on the DNA backbone. At high doses of radiation (10,000 - 15,000 rads), death occurs in a few hours because of neurological and cardiovascular breakdown (Central Nervous Syndrome). 14

Biological Effects of Radiation: Medium doses, 500 - 1200 rads, causes death to occur in a few days because of the destruction of the gastrointestinal mucosa. Lower doses, 250 - 500 rads, causes death to occur after several weeks due to damage of the blood forming organs (hematopoietic syndrome).

Radiation is used positively in a variety of ways Medicine For example, radiation and radioactive tracers are used to diagnose and treat medical problems. A radioactive tracer is a radioactive isotope that is added to a substance so that the substance can be detected later. Radioactive tracers are used to locate tumors, to study the functioning of a particular organ, or to monitor the flow of blood. For example, radioactive iodine-131 is used to diagnose thyroid problems. Radiation therapy used to treat cancer may involve the use of implanted radioactive isotopes such as gold-198 or iridium-192.

Industry Manufacturers can also use radiation to check the thickness of metal containers by measuring the amount of radiation that passes through. Small amounts of radioactive isotopes, like magnesium-28, can be introduced in a water source to determine the flow of underground water or to determine if an underground water system is leaking. Radioactive isotopes are even used in smoke alarms.

Generate electrical power Nuclear fission is used to generate electricity as an alternative energy source. Dating Even the age of fossils or rocks can be determined by using radioactive isotopes.

Combining of two nuclei. Fission Fusion Splitting a nucleus Combining of two nuclei.

Nuclear power can come from the fission of uranium, plutonium or thorium or the fusion of hydrogen into helium. Today it is almost all uranium. The fission of an atom of uranium produces 10 million times the energy produced by the combustion of an atom of carbon from coal.

Issues for Fission Power Plants Need for a spent fuel disposal facility and a decommissioning plan Use of large amounts of water for cooling purposes (if wet cooling towers are used) –thermal pollution Biological impacts on the ocean due to thermal discharge (if seawater cooling is used) Public safety concerns Clip Bill Nye Clip

21 FUSION A fusion reaction occurs when nuclei of light elements, specifically hydrogen and its isotopes (deuterium, or "heavy water," and tritium), are forced together at extremely high temperatures and densities until they fuse into nuclei of heavier elements and release enormous amounts of energy. If fusion is to yield net energy, the fuel must be heated in the form of plasma (a highly ionized gas) to a very high temperature and the plasma must then be held together for a sufficiently long time such that the number of fusion reactions occurring releases more energy than was required to heat the fuel.

Bill Nye Explains Half Life Half Life is the amount of time it takes for half of the nuclei in a sample to decay Bill Nye Explains Half Life Mass (kg)

Carbon occurs naturally in three isotopes. mass number 13C Carbon occurs naturally in three isotopes. All of these atoms have the same number of protons but different numbers of neutrons. The number of neutrons and protons determines the mass, so the masses are different. 14C is radioactive.

14C Radioactive 14C acts chemically just like 12C, so it becomes incorporated into plants an animals. When the animal/plant dies the 14C begins to decay into 14N at a know rate, so we can determine how long ago the organism died. This is called Carbon Dating. It’s only good for about 50,000 years.

The half life of 14C is 5,730 years. If a sample originally contained 100 g, how much would be left after 11,460 years? 50g 25g

Older Dating Methods The isotopes 235U and 238U can be used to date objects billions of years old. 235U has a half life of 704 million years. 238U has a half life of 4.5 billion years. Mainly used for rocks.

Geiger Counter Used to measure radiation. The more intense the radiation the more “clicks”.