Nuclear Chemistry, Chapter 18
Introduction
Rutherford’s Gold Foil expt. showed that all of the mass of the atom is in the nucleus. or use the pHet Rutherford Scattering simulation: scattering scattering Nucleus = protons + neutrons Together they are called NUCLEONS. NUCLIDES are atoms identified by both mass and number. ex: 1 1
What force holds nuclei together? Called the Strong Force. Identified by Hideki Yukawa MUCH stronger than charge interactions but only strong over a VERY SHORT DISTANCE. Strong force must be stronger than the force pulling the nucleons apart (repulsion due to charge), so in large nuclei, where due to distance the pull is less, the nuclei tend to fall apart.
Are there smaller nuclear particles than neutrons and protons? Dalton—atoms are the smallest particles in nature Other scientists—there are protons and neutrons. 1960—protons and neutrons are made of QUARKS.
Quark FLAVORS 1.Up 2.Down 3.Top 4.Bottom 5.Strange 6.Charm ONLY Up and Down make up Protons and Neutrons.
Beta decay A neutron released from an unstable nucleus can be converted into A Proton and an Electron + energy. The Electron is also called a Beta Particle.
picreview/bp/ch23/modes.php#radiation ed.org/EducationResources/HighSchool/Radio graphy/radioactivedecay.htm
Genetic damages: from mutations that alter genes Genetic defects can become apparent in the next generation Somatic damages: to tissue, such as burns, miscarriages & cancers Bad Health Effects of Radiation
Electricity Production by Fuel U.S. Department of Energy, Annual Energy Review 1999
Use of Fission Power 1945 first large scale use atomic bombs were used by the US to knock Japan out of WWII –s–since then attention has been given to the peaceful uses of atomic energy
Nuclear Power Plants In a conventional nuclear power plant –a controlled nuclear fission chain reaction –heats water –produce high-pressure steam –that turns turbines –generates electricity.
Nuclear Fission approximately 20,000 times as much heat and energy is released from uranium fuels as from an equivalent amount of coal
when a sufficient amount of fissionable material is brought together, a chain reaction occurs splitting atoms and releasing a tremendous amount of heat
Controlled Fission Chain Reaction neutrons split the nuclei of atoms such as Uranium or Plutonium release energy (heat)
3c ar-fission
Nuclear Fusion Fusion is combining together the atoms are fused together rather than split apart possibilities for nuclear fusion are much greater than those for nuclear fission
Fuel for fusion fusion reactors would be fueled by deuterium, an isotope of hydrogen available in almost unlimited supply in sea water
Fusion Problems: process is so difficult to control that it is questionable whether commercial adaptation will ever be economically feasible Can be done in a lab –held in check by magnetic fields. BUT—creates HUGE amounts of heat.
Fusion Problems fusion requires extreme pressure and temperatures (as high as 100 million degrees) such heat was achieved by the Hydrogen bomb by first setting off a fission explosion
Destructive power: [1] Small towns have been leveled by floods and landslides. [2] The same size town could be leveled by 1,000 tons of chemical explosives. [3] Hiroshima (quarter of a million people) was destroyed by releasing the energy in 40 kg of Uranium We know the least about the strong nuclear force.
Nuclear Energy Concerns Concerns about the safety, cost, and liability have slowed the growth of the nuclear power industry Accidents at Chernobyl and Three Mile Island, and more recently, Fukashima, showed that a partial or complete meltdown is possible
Chernobyl April 26, 1986, reactor explosion (Ukraine) flung radioactive debris into atmosphereatmosphere Health ministry reported 3,576 deaths Green Peace estimates 32,000 deaths; About 400,000 people were forced to leave their homes ~160,000 sq km (62,00 sq mi) contaminated > Half million people exposed to dangerous levels of radioactivity Cost of incident > $358 billion
Three Mile Island March 29, 1979, a reactor near Harrisburg, PA lost coolant water because of mechanical and human errors and suffered a partial meltdown 50,000 people evacuated & another 50,000 fled area Unknown amounts of radioactive materials released Partial cleanup & damages cost $1.2 billion Released radiation increased cancer rates.
Three Mile Island evacuation of preschool children and pregnant women within five miles of the plant
1. Low-level radiation (Gives of low amount of radiation) Sources: nuclear power plants, hospitals & universities 1940 – 1970 most was dumped into the ocean Today deposited into landfills 2. High-level radiation (Gives of large amount of radiation) Fuel rods from nuclear power plants Half-time of Plutonium 239 is years No agreement about a safe method of storage Radioactive Waste
Radioactive Waste 1. Bury it deep underground. Problems: i.e. earthquake, groundwater… 2. Shoot it into space or into the sun. Problems: costs, accident would affect large area. 3. Bury it under the Antarctic ice sheet. Problems: long-term stability of ice is not known, global warming 4. Most likely plan for the US Bury it into Yucca Mountain in desert of Nevada Cost of over $ 50 billion 160 miles from Las Vegas Transportation across the country via train & truck
What is Going to Happen to Spent Fuel? Photos from : The Yucca Mountain Project: /
Conclusion…… “The odds of an American dying from a nuclear power accident are 300 million to one.”