Presentation is loading. Please wait.

Presentation is loading. Please wait.

Applications of the elements

Similar presentations


Presentation on theme: "Applications of the elements"— Presentation transcript:

1 Applications of the elements

2 Radioactivity Elements with unstable nuclei are said to be radioactive
Eventually they break down and eject energetic particles and emit high-frequency electromagnetic radiation Involves the decay of the atomic nucleus, often called radioactive decay

3 Radioactivity It is found in volcanoes, geysers and hot springs

4 Alpha, Beta and Gamma Rays
All elements with an atomic number greater than 82 (after Lead) are radioactive These elements emit 3 different types of radiation, named α ß γ (alpha, beta and gamma) α : carries positive charge ß : carries negative charge γ : carries no charge Can be separated by placing a magnetic field

5 Alpha, Beta and Gamma Rays
The alpha particle is the combination of 2 protons, and 2 neutrons (nucleus of He) Large size, easy to stop Double positive charge (+2) Do not penetrate through light materials Great kinetic energies Cause significant damage

6 Alpha, Beta and Gamma Rays
A beta particle is an electron ejected from a nucleus The difference from this and other electrons is that it originates inside the nucleus, from a neutron Faster than an alpha particle Carries only one negative charge (-1) Not easy to stop They can penetrate light materials Harming to kill living cells

7 Alpha, Beta and Gamma Rays
Gamma rays are the high- frequency electromagnetic radiation emitted by radioactive elements It is pure energy Greater than in visible light, ultraviolet light or even X rays No mass or electric charge Can penetrate through almost all materials (except Lead) Cause damage

8 Sources of radioactivity
Common rocks and minerals in the environment People who live in brick, concrete and stone building are exposed to greater amounts Radon-222 (gas arising from Uranium deposits) Non natural sources – medical procedures Coal and nuclear power industries (wastes)

9 Radiation dosage Commonly measured in rads (radiation absorbed)
Equals to 0.01 J of radiant energy absorbed per kilogram tissue The unit to measure for radiation dosage based on the potential damage is the rem Dosage: # rads x factor of effects Letal doses →begin at 500 rems

10 Radioactive tracers Radioactive isotopes are called tracers
Medical imaging

11 The atomic nucleus and the strong nuclear force
Strong nuclear force: attraction between neutrons and protons. Strong in short distances Repulsive electrical interactions (strong even in long distances) A small nucleus has more stability

12 The atomic nucleus and the strong nuclear force
A nucleus with more than 82 protons are radioactive. There are many repulsive effects due to all the protons interacting together The neutrons are like the “nuclear cement” (hold the nucleus together). Attract p+ and nº The more p+, the more nº needed to balance the repulsive electrical forces

13 The atomic nucleus and the strong nuclear force
In large nucleus more nº are needed Neutrons are not stable when alone A lonely neutron is radioactive and spontaneously transforms to a p+ and e- Nº seems to need p+ to avoid this from happening When the nucleus`size reaches a certain point, the #nº> #p+→ nº transform into p+ More p+= stability decreases, repulsive electric force increases, starts radiation

14 Half life and transmutation
Half life: the rate of decay for a radioactive isotope. The time it takes for half of an original quantity of an element to decay Example: radium-226 (half life of 1620 years), uranium- 238 (half life of 4.5 billion years) Half lives are not affected my external conditions, constant The shorter the half life, the faster it desintegrates, and the more radioactivity per amount is detected

15 Half life and transmutation
To determine the half life is used a radiation detector When a radioactive nucleus emits alpha or a beta particle, there is a change in the atomic number, which means that a different element is formed This change is called transmutation (Could be natural or artificial)

16 Natural transmutation
Uranium- 238 (92 protons, 146 neutrons) Alpha particle is ejected (2 protons and 2 neutrons) No longer identified as Uranium- 238 but as Thorium-234 Energy is released (kinetic energy of the alpha particle, kinetic energy of the Thorium atom and gamma radiation

17 Natural transmutation
When an element ejects a beta particle from its nucleus, the mass of the atom is practically unaffected, there`s no change in the mass number, its atomic number increases in 1. Gamma radiation results in no change in either the mass or atomic number

18 Artificial transmutation
Ernest Rutherford was the 1st to succeed in transmuting a chemical reaction He bombarded nitrogen gas with alpha particle from a piece of radioactive element. The impact of an alpha particle on the nitrogen nucleus transmutes Nitrogen into Oxygen Other experiments are used to make synthetic elements

19 Nuclear Fission Hahn and Strassmann (1938)
Uranium has not enough nuclear forces Stretches into an elongated shape Electric forces push it into an even more elongated shape Electric forces > strong nuclear forces The nucleus splits U-235 released energy (kinetic energy, ejects a neutron and gamma radiation)

20 Nuclear Fission Chain reaction
Self sustaining reaction in which the products of one reaction even stimulate further reaction events

21 Nuclear fission reactors
An important amount of energy in the world is made up by the use of nuclear fission reactors Boil water to produce steam for a turbine The fuel is Uranium

22 Nuclear fission reactors
BENEFITS Plentiful electricity Conservation of fossil fuels DISADVANTAGES Radioactive waste products

23 Mass –Energy equivalence E=mc²
Albert Einstein discovered the mass is actually “congealed” energy E= the energy in rest M= mass C= speed of light c²= constant of energy and mass This relation is the key in understanding why and how energy is released in nuclear reactions

24 Mass –Energy equivalence E=mc²
More energy →greater mass in the particle Nucleons outside > inside More energy is required to separate nucleons

25 Nuclear fusion Is the opposite to nuclear fission, it is a combination of nuclei Energy is released as smaller nuclei fuse. Less mass is obtained For a fusion reaction to occur, the nuclei must collide at a very high speed in order to overcome the mutual electric repulsion Examples: Sun and other stars

26 Thermonuclear fusion Hydrogen →Hellium and radiation
Less mass, more energy Depends on high temperatures

27 Atomic bomb Hiroshima y Nagasaki Case
Nuclear attacks near the end of World War II against the Empire of Japan by the United States on August 6 and 9, 1945. “Little Boy” →Hiroshima (U-235) “Fat Man” → Nagasaki (Plutonium-239) Many people died due to the radiation poisoning

28 Hydrogen bombs Eniwetok case Marshall islands (Pacific Ocean) 1952
Nothing survived In the zero point of the explotion (center of the bomb) the temperature was 15 million degrees celsius


Download ppt "Applications of the elements"

Similar presentations


Ads by Google