NUCLEAR VS. CHEMICAL CHEMICAL reactions involve rearranging of atoms: e.g., H 2 +O 2  H 2 O No new atoms are created. Chemistry involves electrons only.

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Presentation transcript:

NUCLEAR VS. CHEMICAL CHEMICAL reactions involve rearranging of atoms: e.g., H 2 +O 2  H 2 O No new atoms are created. Chemistry involves electrons only.

CHEMICAL VS. NUCLEAR NUCLEAR reactions involve taking atoms apart and making new atoms. Nuclear reactions involve protons and neutrons (the stuff in the nucleus!)

NUCLEAR DECAY NOTE: decay doesn’t mean the mass is “gone,” just that the atoms have become different atoms. What law discusses this???

UNSTABLE atoms DECAY--they emit energy (radiation) to become more stable. RF  wave infrared visible uv x-ray  -ray cosmic LOW ENERGY HIGH ENERGY Non-ionizing Ionizing radiation MOST isotopes are RADIOACTIVE (unstable)-- nearly 85% of all known isotopes decay…only about 15% are STABLE.

Ionizing Radiation Can deposit energy in neighboring atoms resulting in the removal of electrons

IONIZING RADIATION Since your cells and tissues are NEUTRAL, ionizing radiation is NOT GOOD.

Type of RadiationGreek Symbol Chemical Symbol ChargeShielding/ Protection Additional Information Alpha Beta Gamma Neutron

Alpha Particle  Consists of two protons and two neutrons.  Just like a He nucleus (no electrons)  It has a charge of +2: it is IONIZING.  They have a low penetrating power - can be stopped by your skin. He Greek Symbol Chemical Symbol α

Alpha Particle  Alpha particles are relatively slow and heavy.  Rapidly lose energy when passing through matter.  Does not penetrate very far, but can cause damage over its short path through tissue.  Can be very harmful if ingested or inhaled.

Alpha radiation is only a hazard when inside your body (internal hazard) Can’t penetrate skin Internal hazard Stopped by paper Found in soil, radon and other radioactive materials

Beta Particle  Fast moving electrons emitted from the nucleus during radioactive decay. ?? IONIZING or NOT ??  More penetrating than an Alpha Particle  Can penetrate skin, but more hazardous when inhaled.  Can be slowed or stopped by a layer of clothing or a few mm of aluminum. ELECTRON -- 0 e Chemical Symbol Greek Symbol

Beta radiation is a skin, eye and internal hazard Skin, eye and internal hazard Stopped by clothing/aluminumFound in natural food, air and water

Gamma Radiation Gamma rays are waves of energy, not particles. They have no mass and no charge, but are ionizing. Often produced with alpha or beta particles. Gamma rays can easily pass through the body or be absorbed by tissue, thus a hazard for the entire body. Gamma rays have a high penetrating power - it takes a thick sheet of lead or concrete to slow them down. Gamma rays are like X-rays, only more energetic. 

Stopped by several inches of lead or several feet of concrete. Naturally present in soil and cosmic radiation Many medical uses Gamma radiation is penetrating radiation and an EXTERNAL HAZARD

Neutron  Neutrons are the most penetrating.  Have mass, but no charge (IONIZING??)  On Earth they mostly come from the splitting, or fissioning, of atoms inside a nuclear reactor.  Water and concrete are the most commonly used shields against neutron radiation from the core of the nuclear reactor n

What are health risks from ionizing radiation? The degree of damage caused by radiation depends –dose –dose rate –type of radiation –the part of the body exposed –age and health Large doses of ionizing radiation can cause various forms of cancers. At very high levels, radiation can cause sickness and death. The body has defense mechanisms against low levels of radiation. Radiation therapy is used to kill cancerous cells. Much larger doses are used to kill harmful bacteria in food (without leaving radioactive “residue,”) and to sterilize bandages and other medical equipment.

Radiation Dose Naturally occurring background radiation is the main source of exposure for most people. Background radiation comes from three sources: –cosmic rays –naturally occurring radioactive elements such as radon-222 –solar radiation. –The amount of background radiation depends on factors like location, house construction materials, medical treatments, and occupation. –The average exposure for a U.S. resident is 0.36 rem per year.

Radioactive Decay Not all isotopes are “finished” after they decay. Some products are also radioactive, and the matter will not be stable until many decay steps have occurred.

Type of RadiationGreek Symbol Chemical Symbol ChargeShielding/ Protection Additional Information Alpha 2 protons 2 neutrons  4 He sheet of paper Low penetrating power; is a helium nucleus; slow and heavy Beta 1 electron  0 e Layer of clothing, alum., plastic Fast moving electron; result is to change a neutron into a proton; penetrates skin, eyes; is an internal hazard Gamma Not a particle; a wave  none Lead, concrete High penetrating power; hazard for entire body; often accompanies  or  Neutron none 1 n 0 none Water, concrete Nuclear power comes from Uranium neutron decay.