Intro. Into Nuclear Energy And you. What are the fundamental forces of the Universe??? Gravitational Force (interaction of massive bodies) Electromagnetic.

Slides:

Advertisements

Similar presentations

Fundamental Forces of the Universe

Advertisements

NUCLEAR FUSION & NUCLEAR FISSION Noadswood Science, 2012.

Nuclear Energy Nuclear Reactions Nuclear Fission / Nuclear Fusion Harnessing the Power of the Nucleus.

Nuclear Reactions: AN INTRODUCTION TO FISSION & FUSION Farley Visitors Center.

Chapter 25 Nuclear Chemistry 25.3 Fission and Fusion

Miss Nelson SCIENCE ~ CHAPTER 12 ENERGY AND MATERIAL RESOURCES.

Chapter All matter is made up of atoms. Parts of an atom: 1. Nucleus – the center of an atom. Proton – Positively charged. ( + ) Neutron – have.

Atomic Energy 3U Physics. Mass-Energy Equivalence All matter is a form of stored energy.

Nuclear Fission and Fusion

Nuclear / Subatomic Physics Physics – Chapter 25 (Holt)

Nuclear Physics Selected Topics 5 –Fission and Fusion.

Section 3.  Inside the nucleus of the atom contains protons and neutrons.  Nuclear reactions involves tremendous amounts of energy.  Two types of nuclear.

Adam Smalley.  Describe how neutrons produced in a fission reaction may be used to initiate further fission reactions (chain reactions)  Distinguish.

Alternative Energy Sources

Radiation, nuclear fusion and nuclear fission

Nuclear Fission and Fusion

Nuclear Energy. The Periodic Table Dates from around 1880, invented by the Russian Gregor Mendeleev. Organizes the elements into groups (columns) and.

23.4 Nuclear energy NUCLEARNUCLEAR POWERPOWER Millstone Station.

23.4 Nuclear energy NUCLEARNUCLEAR POWERPOWER Millstone Station.

Section 7.3. The process in which the nucleus changes gains or releases particles and energy The stronger the bond the more energy associated with it.

Chapter 40 Nuclear Fission & Fusion

19.6 Nuclear energy Fission=splitting a heavy nucleus into 2 with smaller mass numbers. Causing an unstable nucleus. Fusion=combining 2 light nuclei to.

Section 10–4: Fission and Fusion

Fission and Fusion.

"More than any other time in history, mankind faces a crossroads. One path leads to despair and utter hopelessness. The other, to total extinction. Let.

Nuclear Fission & Fusion Objectives: Describe what happens in a nuclear chain reaction. Explain the use of water in the storage of spent fuel rods. Distinguish.

 Splitting of a nucleus into smaller fragments  Happens when they are bombarded with neutrons  Releases ENORMOUS amts of energy!  Only U-235 & Pu-239.

Nuclear Chemistry. Radioactive Decay Spontaneous breakdown of an atom’s nucleus Breakdown results in a lighter nucleus Emits electromagnetic radiation.

Nuclear Chemistry.

Nuclear Energy Nuclear fission is when a heavy nucleus splits into two smaller nuclei. The total mass of the products is less than the original mass. The.

Subatomic Physics Chapter Properties of the Nucleus The nucleus is the small, dense core of an atom. Atoms that have the same atomic number but.

Section 10–4: Fission and Fusion Physical Science Coach Kelsoe Pages 308–315.

Nuclear Power. How does nuclear power work? Fission produces heat Heat boils water making steam Steam turns a turbine Turbine produces electricity.

ATOMIC ENERGY 4 Binding Energy 4 Fission and Fusion 4 Nuclear Reactors 4 Electrical Generation.

Fundamental Forces of the Universe. There are four fundamental forces, or interactions in nature.  Strong nuclear  Electromagnetic  Weak nuclear 

Atoms Chapter 4.

Radioactive Nuclide Nuclide which is unstable. It emits radiation & changes into another kind of atom.

Nuclear Fission and Fusion Unit 8 – Part B. Nuclear Balance Delicate balance between attractive strong nuclear forces and repulsive electric forces. In.

Chapter 11 Nuclear Power  Energy released in combustion reactions comes from changes in the chemical bonds that hold the atom together.  Nuclear Energy.

FISSION vs. FUSION. Fission The splitting of a nucleus into smaller fragments when bombarded with neutrons. One large nucleus of a particular isotope.

Basic Chemistry Copyright © 2011 Pearson Education, Inc. 1 Chapter 16 Nuclear Radiation 16.6 Nuclear Fission and Fusion.

In your own words try to explain a radio active decay series

Nuclear Reactions: FISSION & FUSION ã Nuclear reactions deal with interactions between the nuclei of atoms ã Both fission and fusion processes deal with.

CHAPTER 5: ENERGY RESOURCES SECTION 3: NUCLEAR ENERGY.

Nuclear fission Nuclear fission: heavy nuclei split into two smaller parts in order to become more stable proton neutron Kr-90 nucleus U-235 nucleus energy.

Chapter 21 Nuclear Chemistry

Nuclear Fusion and Fission

MEASURING RADIATION Large doses of radiation are harmful to living tissue. Radiation can be measured with a Geiger counter – a device that measures radioactivity.

Fission, the splitting of nuclei, and fusion, the combining of nuclei, release tremendous amounts of energy. Section 3: Nuclear Reactions K What I Know.

 Large nuclei (> 92 protons) are unstable and usually results in radioactive decay.  Very rarely a large nucleus will split up spontaneously into two.

 In nuclear fission, large atoms are split apart to form smaller atoms, releasing energy.  Fission also produces new neutrons when an atom splits. 

Fission and Fusion Nuclear power And you. YOU Have heard of nuclear reactions – but what are they???????????? Nuclear bombs Nuclear reactors The Sun.

Chemistry - Unit 13.  Discovery of Radioactivity  In 1895 Wilhelm Roentgen found that invisible rays were emitted when electrons bombarded the surface.

Chapter 31. Caleb Pat FM Carrette. Introduction Formulas E-mc Strong nuclear force – The force that overcomes the mutual repulsion of the charged.

25.3 Fission and Fusion > 1 Copyright © Pearson Education, Inc., or its affiliates. All Rights Reserved. Chapter 25 Nuclear Chemistry 25.1 Nuclear Radiation.

NUCLEAR FISSION. Fission = splitting of nuclei Nuclei split when hit with a neutron Nucleus breaks into: * 2 large fragments & * 2-3 neutrons Fission.

Fission and Fusion of Atomic Nuclei

Nuclear Physics.

A. Nuclear Forces Do nuclei contain attractive or repulsive forces?

A. Nuclear Forces Do nuclei contain attractive or repulsive forces?

Chapter 5 Energy Resources

Fundamental Forces of the Universe

A. Nuclear Forces Do nuclei contain attractive or repulsive forces?

Nuclear Reactions 1-3,6-7,17-23 E = mc2.

Fundamental Forces of the Universe

Nuclear Fission.

Nuclear Reactions: FISSION & FUSION.

Intro. Into Nuclear Energy

Big 7 - Chapter 6 Nuclear Reactions.

Nuclear Energy Chapter 25 6/1/2019.

Presentation transcript:

Intro. Into Nuclear Energy And you

What are the fundamental forces of the Universe??? Gravitational Force (interaction of massive bodies) Electromagnetic Force (interaction of charged particles) Weak Nuclear Force (short distance – responsible for radioactive decay of subatomic particles) Strong Nuclear Force (binds nucleons together despite electrostatic repulsion of protons – very strong force – only acts at very small distances)

How it relates to nuclear Energy Let’s discuss really big atoms – like Uranium protons, 143 neutrons U The large number of neutrons help the nucleus to stay together (keeps P+s apart) Stays together due to strong nuclear force

Fission reactions Breaking apart of nuclei Ba U 1 0 n  U Δ U n U Kr U Release of large amounts of energy Process takes about s Starts a chain reaction!!!!!

E = mc 2

Historical highlight E = mc 2 small amounts of mass converted to E Started ~ 1940 in U.S. Manhattan project Did not take place in Manhattan Very fast pace A great deal of knowledge of atomic physics was learned in this time period

Not just used for bombs!!! Fission used in nuclear reactions as well

Where does the U-235 come from? Mined Uranium is a combination of Uranium isotopes. Most is U-238, some U-237, and less than 1% is U-235 Enrichment = separation of isotopes to isolate U-235

What happens when you have large amounts of U-235? When you have enough U-235, and therefore, enough slow moving neutrons to have a self sustaining nuclear reaction going in a reaction = critical mass. Is that all you need? No, you need something else to slow down the neutrons

How you say?? The use of a moderator (graphite or heavy water) to slow down the neutrons that bombard the U-235 (too fast = bounce off)

So why don’t the nuclear reactors just blow up like a bomb? The use of control rods (Cd or B) help to slow down the reaction if it gets going too fast – they absorb neutrons (so they are not hitting the U-235) The control rods are adjustable – so they can be changed in their orientation – to control the rate of the nuclear reaction What if the reaction goes too fast? Meltdown (like 3 mile island or Chernobyl)

How does the reactor work? Shield molten Na steam to turbine (generates electricity) Core reactor heat exchanger Fuel rods water

What do we do with the waste? Left over 238 U undergoes radioactive decay β decay 4.5 x 10 9 year ½ life What is to be done with it???????

Fusion reactions Put together small nuclei to make a larger nuclei P + + P +  2 2 He (fusion on the Sun) Enormous E released (high T O, P plasma gas) Very hard to start fusion reaction Net E gain is so large – that it melts everything!

Example (Deuterium) 2 1 H 4 2 He n smash together 3 1 H (Tritium) Non radioactive products 100 mill o C fusion plasma Contain in a magnetic chamber ~ 2035 (hopefully)