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Topic 6 – “Airs” and The Chemical Revolution Today: Some properties of air; overcoming the “ horror vacui ” Dr. George Lapennas Dept. of Biology. Studies of “air” and “air s ” lead to revolution in the understanding of the nature of elements and matter: - The weight and spring of air
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Topic 6 – “Airs” and The Chemical Revolution Today: Some properties of air; overcoming the “horror vacui” Dr. George Lapennas Dept. of Biology
Studies of “air” and “airs” lead to revolution in the understanding of the nature of elements and matter: • - The weight and spring of air • Different kinds of “air” (=“airs”) • Redefinition of “elements” • Atoms and their properties
Aristotle’s 4 earthly elements – natural motions were up or down to their natural places, where they came to rest
Aristotle’s 4 earthly elements: • element “fire” is absolutely light • element “air” is relatively light • element “water” is relatively heavy • element “earth” is absolutely heavy
The “horror vacui” • For Aristotle (and for most others until mid 1600’s, including Descartes): • Space is defined by the matter that occupies it • “Empty space” is a logical impossibility (“void”; “vacuum”); matter is everywhere • Nature “abhors a vacuum” (the “horror vacui”) and will do what is necessary to prevent formation of a vacuum • (Contrast: Democritus’ concept of “atoms” moving in the “void”)
Examples of the power of the horror vacui 1. Draw water up a tube (soda straw; water pump; syringe)
Examples of the power of the horror vacui 1. Draw water up a tube (soda straw; water pump; syringe) 2. Water does not drain from a vessel unless air can enter to replace it
Examples of the power of the horror vacui 1. Draw water up a tube (soda straw; water pump; syringe) 2. Water does not drain from a vessel unless air can enter to replace it 3. Water “siphon” through a tube
Examples of the power of the horror vacui 1. Draw water up a tube (soda straw; water pump; syringe) 2. Water does not drain from a vessel unless air can enter to replace it 3. Water “siphon” through a tube 4. Glass bottle breaks when water in it freezes (water presumed to shrink upon freezing; nature crushes the bottle to prevent formation of a vacuum)
Apparent limitations to the power of the horror vacui 1. Water pumps cannot lift water more than 34 feet 2. Water siphon cannot carry water over a hill more than 34 feet high 3. Behavior of water in a tall, inverted, closed tube
Gasparo Berti (1600-1643) • water filled tube • level of water inside tube stayed at 34 ft • space left above water in tube • Suggests vacuum existing in the space above the water.
Water height is the same whatever the length of the tube Wouldn’t nature more strongly abhor a larger void?
Torricelli used mercury instead of water: same pattern, except …
… height of mercury columns were only 2½ feet, or 1/13.6 the height of water column
… height of mercury columns were only 2½ feet, or 1/13.6 the height of water column Note: Mercury is 13.6 times as heavy as the same volume of water, so the weights of the mercury and water columns were the same. Does mercury abhor a vacuum less strongly than water does, and it is merely a coincidence that its abhorrence is less by the same factor that its weight per unit volume is greater? … or is there an underlying explanation?
Torricelli’s alternate hypothesis to the horror vacui: Perhaps something pushes the water or mercury up the tubes, and could push up the same weight of both liquids?
Torricelli’s hypothesis: Perhaps the weight of the air (atmosphere) is doing the pushing. (Galileo had already weighed air ~ 1/800 as heavy as same volume of water.) Pascal’s prediction: If so, then there should be less push as one moves up through the atmosphere, because there would be less air above the observer. Blaise Pascal
In 1648, Pascal sent his brother-in-law Florence Périer up 3000-foot Mt. Puy-de-Dome with bowls, tubes and mercury
The mercury rose to 2 ½ feet … minus 3 inches! These results proved that Torricelli’s hypothesis was true.
The mercury rose to 2 ½ feet … minus 3 inches! These results proved that Torricelli’s hypothesis was true. NOT!
The mercury rose to 2 ½ feet … minus 3 inches! These results proved that Torricelli’s hypothesis was true. NOT! These results supported Torricelli’s hypothesis.
Today we use the “barometer” to measure changes in atmospheric pressure to help predict weather changes.
Another test of weight of air hypothesis: Predict that if a barometer is placed in a chamber and the air pumped out, then the mercury column will not be as high.
Boyle’s/Hooke’s improved pump of 1660 von Guericke’s original air pump
When Boyle and Hooke pumped air out of a chamber containing a barometer, the mercury dropped lower and lower – down to a small fraction of an inch. This result lent further support to the hypothesis that water and mercury columns were pushed up to their heights by the weight of air, rather than climbing up in attempts to eliminate the vacuum.
Boyle’s experiments on the “spring” of air Air resists compression like a spring does.
Boyle’s experiments on the “spring” of air Air resists compression like a spring does. Explanation?
Boyle’s experiments on the “spring” of air Air resists compression like a spring does. Explanation? Boyle: Air consists of tiny particles that are like springs, pressing against each other, and resisting compression.
Boyle’s experiments on the “spring” of air Air resists compression like a spring does. Explanation? Boyle: Particles of air are like springs, pressing against each other, and resisting compression Newton: Air particles repel each other without contact, with a force that decreases with distance.
Boyle’s experiments on the “spring” of air Air resists compression like a spring does. Explanation? Boyle: Particles of air are like springs, pressing against each other, and resisting compression Newton: Air particles repel each other without contact, with a force that decreases with distance. Both of these hypotheses ultimately proved incorrect. (Air pressure results from the force of air molecules colliding with surfaces and bouncing off them – exerting force on the surfaces that are equal and opposite to the forces the surfaces are exerting on them.)
Further studies of air lead to … … the realization that there are many different kinds of air (“airs”), not just one.
Further studies of air lead to … … the realization that there are many different kinds of air (“airs”), not just one. … and to the identification of elements as we know them today.
Further studies of air lead to … … the realization that there are many different kinds of air (“airs”), not just one. … and to the identification of elements as we know them today. … and to the theory that matter consists of atoms, to the understanding of the structure and properties of atoms, and why they react the way they do.