Fission

Fission • Splitting a nucleus into smaller fragments • Happens with atoms larger than Iron (Fe) • Usually far more massive • Can release A LOT of energy • Think: atomic bomb • Nuclear reactors use fission as source of energy http://www.atomicarchive.com/Fission/Fission1.shtml

http://www.spiritofbaraka.com/images/koyaanisqatsi/fullsize/koyanisa320.jpghttp://www.spiritofbaraka.com/images/koyaanisqatsi/fullsize/koyanisa320.jpg

Why does fission happen? • Addition of a neutron to the nucleus • Neutrons can also be emitted when an unstable nucleus breaks down • Why a neutron? (Why won’t an alpha particle work?) • What effect will this neutron have on the forces in the nucleus? http://reactor.engr.wisc.edu/fission.htm

Fission’s good side • Used in nuclear power plants • Has to be controlled

Fusion • Two nuclei combine • Happens with elements smaller than (Iron) Fe • Usually much smaller • The Sun: hydrogen nuclei combine to form helium • Release large amounts of energy, but requires very high temperatures • Ex: hydrogen bomb http://www.noaanews.noaa.gov/stories2005/images/ http://reactor.engr.wisc.edu/fission.htm

The dream of Fusion • Yet to be harnessed • Would provide even MORE energy than fission • No system of control unlike fission

Fusion - the Sun http://www.atpm.com/7.12/sewickley/images/sun.jpg http://zebu.uoregon.edu/~soper/Light/fusion.html

Fusion – the hydrogen bomb

The relationship between energy and matter • What is the law of conservation of matter? • Fission & fusion seem to break this law • Mass of products is less than the mass of the starting material • Matter (or mass) not destroyed but converted into another form… • Energy • E = m c2

What is radiation? • Certain elements or isotopes are unstable, and will decay over time.

3 types of Radiation Alpha (a) Radiation Beta (b) Radiation Gamma (g) radiation

1. AlphaRadiation (a) • Nuclear decay which releases alpha particles • Alpha particle: two protons and two neutrons • Results: • What happens to the atomic number? • What happens to the mass number? • Notice: atom becomes a different element http://education.jlab.org/glossary/alphaparticle.html

2. Beta Radiation (b) • Nuclear decay in which beta particles – high energy electrons – are released • A neutron is a collapsed proton and electron. • Neutron  proton + electron • Results: • What happens to the atomic number? • What happens to the mass number? • Notice: atom becomes a different element http://www.physics.isu.edu/radinf/beta.htm

3. Gamma Radiation (g) • High energy “light” (electromagnetic radiation) • No mass or charge • Often emitted along with beta or alpha radiation • Results: • How does gamma radiation effect the… • atomic number? • mass number? http://www.epa.gov/radiation/understand/ionize_nonionize.htm

Alpha particles. Alpha particles are the least penetrating form of radiation. They do not penetrate the outer layer of skin, however, may be a risk to an open wound. • Beta particles. Beta particles can burn the skin and damage eyes. • Gamma rays. Gamma rays are the most penetrating kind of radiation, can travel long distances and penetrate through the body. (excerpt from Mayo clinic website) (EPA website) http://www.epa.gov/radiation/docs/ionize/402-f-98-009.htm

Writing nuclear equations Symbol Meaning: • X = element type • A = mass # or protons + neutrons • Z = atomic # or # of protons

Conservation of Mass • According to the Law of Conservation of Mass: • Matter cannot be created nor destroyed. • The total starting mass must equal the total resulting mass. http://web.fccj.org/~ethall/1025/scale3.gif

Alpha Decay • Atom releases an alpha particle. • Atomic # decreases becoming new element. + • Notice: • total starting mass equals total resulting mass: 238 = 234 + 4 • total starting charge equals total resulting charge: 92 = 90 + 2

Using alpha decay, properly complete the following nuclear equations. + + +

Did you notice… • when an atom undergoes alpha decay, its atomic number decreased by ______? • when an atom undergoes alpha decay, its mass number decreased by _______?

Beta Decay • Atom releases a beta particlewith zero mass & negative charge • Atomic number increases (becomes new element!) + • Notice: • total mass stays the same: 14 = 14 + 0 • total charge stays the same: 6 = 7 - 1

Using beta decay, properly complete the following nuclear equations. + +

Did you notice… • when an atom undergoes beta decay, its atomic number is increased by ______? • when an atom undergoes beta decay, its mass number _________________?

Often multiple steps must occur for a radioactive element to reach a stable form. http://www.uic.com.au/ral.htm

Properties of Reactions

Half-Life HALF-LIFE is the time it takes for 1/2 a sample is disappear. For 1st order reactions, the concept of HALF-LIFE is especially useful.

Half-Life • Reaction is 1st order decomposition of H2O2.

Half-Life • Reaction after 654 min, 1 half-life. • 1/2 of the reactant remains.

Half-Life • Reaction after 1306 min, or 2 half-lives. • 1/4 of the reactant remains.

Half-Life • Reaction after 3 half-lives, or 1962 min. • 1/8 of the reactant remains.

Half-Life • Reaction after 4 half-lives, or 2616 min. • 1/16 of the reactant remains.

Half-Life Sugar is fermented in a 1st order process (using an enzyme as a catalyst). sugar + enzyme --> products Rate of disappear of sugar = k[sugar] k = 3.3 x 10-4 sec-1 What is the half-life of this reaction?

Half-Life Rate = k[sugar] and k = 3.3 x 10-4 sec-1. What is the half-life of this reaction? Solution [A] / [A]0 = fraction remaining = 1/2 when t = t1/2 Therefore, ln (1/2) = - k • t1/2 - 0.693 = - k • t1/2 t1/2 = 0.693 / k So, for sugar, t1/2 = 0.693 / k = 2100 sec = 35 min

Half-Life Rate = k[sugar] and k = 3.3 x 10-4 sec-1. Half-life is 35 min. Start with 5.00 g sugar. How much is left after 2 hr and 20 min (140 min)? Solution 2 hr and 20 min = 4 half-lives Half-life Time Elapsed Mass Left 1st 35 min 2.50 g 2nd 70 1.25 g 3rd 105 0.625 g 4th 140 0.313 g

Half-Life Radioactive decay is a first order process. Tritium ---> electron + helium 3H 0-1e 3He t1/2 = 12.3 years If you have 1.50 mg of tritium, how much is left after 49.2 years?

Half-Life Start with 1.50 mg of tritium, how much is left after 49.2 years? t1/2 = 12.3 years Solution ln [A] / [A]0 = -kt [A] = ? [A]0 = 1.50 mg t = 49.2 y Need k, so we calc k from: k = 0.693 / t1/2 Obtain k = 0.0564 y-1 Now ln [A] / [A]0 = -kt = - (0.0564 y-1) • (49.2 y) = - 2.77 Take antilog: [A] / [A]0 = e-2.77 = 0.0627 0.0627 = fraction remaining

Half-Life Start with 1.50 mg of tritium, how much is left after 49.2 years? t1/2 = 12.3 years Solution [A] / [A]0 = 0.0627 0.0627 is the fraction remaining! Because [A]0 = 1.50 mg, [A] = 0.094 mg But notice that 49.2 y = 4.00 half-lives 1.50 mg ---> 0.750 mg after 1 half-life ---> 0.375 mg after 2 ---> 0.188 mg after 3 ---> 0.094 mg after 4

Half-Lives of Radioactive Elements Rate of decay of radioactive isotopes given in terms of 1/2-life. 238U --> 234Th + He 4.5 x 109 y 14C --> 14N + beta 5730 y 131I --> 131Xe + beta 8.05 d Element 106 - seaborgium263Sg 0.9 s

Fission

Fission

Presentation Transcript

Nuclear Fission

Fission

Abrasion -Fission

Nuclear Fission

Nuclear Fission

Nuclear Fission

Nuclear Fission

Fission

Fission

NUCLEAR FISSION

Nuclear Fission

Fission

Nuclear Fission

Nuclear Fission

Nuclear Fission

Nuclear Fission

Fission Products

Nuclear Fission

Nuclear Fission

Fission

Nuclear Fission

Fission