1. Chapter 14 Gasses & Plasmas Weight of air is small but not negligible. For example, weight of air in this room is comparable to your weight (volume of room about 1000x your volume).

2. Figure 13.5 All vases are filled to equal depths, so the water pressure is the same at the bottom, regardless of its shape or volume

3. Once believed that you had to move water at a slow drop in gradient to move it. Now know water can flow uphill in a closed system if there is pressure behind it. Pipes in the ground can follow the natural slope of the land Garden hose full of water with one end dropped will spill water, but it will flow up hill

4. Pressure does not depend on the amount of liquid Volume is not the key- depth is Pressure is depth dependent, not volume dependent.

5. The force exerted by a fluid on a smooth surface is always at right angles to the surface Liquid pressure is exerted equally in all directions The pressure isn’t only downward When liquid presses against a surface, there is a net force that is perpendicular to the surface. While pressure does not have a specific direction, force does.

6. 24-Feb-16 Physics 1 (Garcia) SJSU Pressure in Liquids Pressure in a liquid depends on depth. As with bricks, weight of what’s above determines pressure. High Medium Low High Medium Low

7. 24-Feb-16 Physics 1 (Garcia) SJSU Pressure Pressure is defined as Pressure = Metric unit of pressure is Pascal. 1 Pascal = 1 Newtons per square meter Atmospheric pressure is about 100,000 Pascals ( Force ) ( Area )

8. 24-Feb-16 Physics 1 (Garcia) SJSU Demo: Bed of Nails One may safely lay or sit on a bed of nails, as long as there are enough nails so that the pressure, measured as force per nail, is small. Weight of 150 pounds is distributed over 300 nails. Force per nail is ½ lb. Need 5 lb per nail to pierce skin.

9. 24-Feb-16 Physics 1 (Garcia) SJSU Sample Problem “Gold” brick is roughly: 12 kilograms [Mass] 120 Newtons [Weight] (0.2 m)x(0.1 m) = (0.02 m 2 ) [Area] Pressure on surface is (120)/(0.02) = 6000 Pascals Note: Atmospheric pressure is about 100,000 Pascals so much more than pressure due to the “gold” brick.

10. 24-Feb-16 Physics 1 (Garcia) SJSU Check Yourself In which case is the pressure greatest? A B A B

11. 24-Feb-16 Physics 1 (Garcia) SJSU Check Yourself In which case is the pressure greatest? A B A B

12. 24-Feb-16 Physics 1 (Garcia) SJSU Crush the Rail Tanker Car The interior of the tank car was washed out & cleaned with steam. Then all the outlet valves were shut and the tank car was sealed. All the workers went home for the evening and when they returned, this is what they found. Apparently as the tank car cooled, it collapsed. The shell on these tank cars is 7/16 th inch thick steel.

13. 24-Feb-16 Physics 1 (Garcia) SJSU Buoyancy Since pressure depends on depth, a submerged object has more force due to pressure below it than above it. Net effect is to have a net upward force, which we call buoyancy. Buoyancy Weight If weight exceeds buoyancy force then object sinks, otherwise it floats. Pressure

14. If the weight of the submerged object is greater than the buoyant force= sink If the weight is less than buoyant= float When the weight is = to buoyant force = remain at same level (won’t sink or rise)

15. 24-Feb-16 Physics 1 (Garcia) SJSU Density & Floating By Archimede’s principle, a solid object will float if the density of the object is less than the density of the liquid. Billiard ball (4.0 g/cm 3 ) floating in a cup of mercury (13.6 g/cm 3 )

16. 24-Feb-16 Physics 1 (Garcia) SJSU Demo: Diet or Regular? What can you say about the density of diet cola as compared with regular cola?

17. Liquids like solids are difficult to compress. Both liquids and gases can flow, so both are called fluids. The pressure you feel is due to the weight of water (or air) above you The pressure a liquid exerts depends on depth. Also depends on density. Liquid pressure = weight density X depth + pressure of atm. Except for small changes produced by temp., the density of a liquids is practically the same at all depths.

19. 24-Feb-16 Physics 1 (Garcia) SJSU Buoyancy & Depth For a fully submerged object the buoyancy force does not depend on depth, even though pressure depends on depth. 1 2 3 4 5 6 Buoyancy

20. Only in the special case of floating does the buoyant force acting on an object equal the object’s weight. principle of flotation: A floating object displaces a weight of fluid equal to its own weight.

21. Figure 13.15 To control how high they float in the water Crocs swallow stones Fish use air bladders

22. Figure 13.17

23. Figure 13.19

24. 24-Feb-16 Physics 1 (Garcia) SJSU Check Yourself Did the designers of this “water bridge” have to account for the weight of ships or just the water?

25. Figure 13.20

26. 24-Feb-16 Physics 1 (Garcia) SJSU Check Yourself ? Place block of wood in the water. Scale reading goes up, down, or stays the same? 50 N 10 N Block 10 N Water 40 N Water A floating object displaces a weight of fluid equal to its own weight.

27. 24-Feb-16 Physics 1 (Garcia) SJSU Archimedes’ Principle Weight of liquid displaced by floating or submerged object equals the buoyant force on the object.

28. 24-Feb-16 Physics 1 (Garcia) SJSU Density & Floating, Revisited When an object is not solid then it floats if the average density, (total mass)/(total volume), is less than the density of the liquid. Solid iron ball Volume: 100 cc Mass: 790 g Density: 7.9 g/cc Iron ball, 90% hollow Volume: 1000 cc Mass: 790 g Density: 0.79 g/cc

29. 24-Feb-16 Physics 1 (Garcia) SJSU Floating & Liquid Density The greater the density of a liquid, the greater the buoyant force on objects floating or immersed in the liquid. Floating in Great Salt Lake, Utah is easy because the lake water is dense due to high concentration of salt.

33. Pascal’s Principle When force applied to a confined fluid, an increase in pressure is transmitted equally to all parts of the fluid A liquid completely filling a bottle exerts pressure in all directions

34. Pascal’s Principle

36. Figure 13.22 The additional pressure is exerted against every square centimeter of the larger piston. Since there is 50 times the area, 50 times as much force is exerted on the larger piston. Thus, the larger piston will support a 500-kg load—fifty times the load on the smaller piston! the piston on the right has 50 times the area of the piston on the left (let’s say that the left piston has a cross- sectional area of 100 square centimeters and that the right piston has a cross- sectional area of 5000 square centimeters).

37. Hydraulic devise Multiplies a force by applying the force to a small surface area. The increase in pressure is then transmitted to another part of a confined fluid, which pushes on a larger surface area

38. Unnumbered Figure 13.9

39. Figure 13.23

40. Figure 13.24

41. Surface Tension When the bent wire is lowered into the water and then raised, the spring will stretch because of surface tension. adhesion- attracted to unlike Cohesion- attracted to like contractive tendency of the surface of liquids

42. Figure 13.27

43. These molecular attractions thus tend to pull the molecule from the surface into the liquid, and this tendency minimizes the surface area. Surface tension is caused by molecular attractions. Beneath the surface, each molecule is attracted in every direction by neighboring molecules, resulting in no tendency to be pulled in any specific direction. A molecule on the surface of a liquid, however, is pulled only by neighbors on each side and downward from below; there is no pull upward. The water surface sags like a piece of plastic wrap, which allows certain insects, such as water striders, to run across the surface of a pond.

44. Surface tension causes a thin film of water to be drawn up over the inner and outer surfaces of the tube (Figure 13.31a).It causes this film to contract The film on the outer surface contracts enough to make a rounded edge. The film on the inner surface contracts more and raises water with it until the adhesive force is balanced by the weight of the water lifted

45. Buoyancy The pressure at the bottom of a submerged object is greater than the pressure at the top. The result is a net force in the upward direction. What is this upward force called?

46. 24-Feb-16 Physics 1 (Garcia) SJSU Buoyancy in Air Objects can float in air, just as they float in water, if the objects’ average density is less than the density of air. Hot Air Balloon Helium-filled Blimp

47. 24-Feb-16 Physics 1 (Garcia) SJSU Zeppelins On May 6, 1937, the German zeppelin Hindenburg caught fire and was destroyed in less than one minute. Only 35 of the 97 people on board were killed. Most deaths did not arise from the fire, but were suffered by those who leapt from the burning ship. (The lighter-than- air fire burned overhead.) Those passengers who rode ship on its gentle descent to the ground escaped unharmed. Hindenburg was 10 times longer than today’s blimps

48. Atmosphere The thickness is determined by kinetic energy From sun) -tends to spread the molecules apart; tend to fly away: if disappeared- molecules moved too slowly our “atmosphere” would be a liquid or solid layer gravity, which tends to hold molecules near the Earth. shut off= dissipate and disappear. height of the atmosphere gets thinner and thins out to emptiness in interplanetary space. 24-Feb-16 Physics 1 (Garcia) SJSU

49. 24-Feb-16 Physics 1 (Garcia) SJSU Atmosphere Density of air in the atmosphere decreases with increasing altitude. Most of atmosphere in the first 10 km (about 6 miles) of altitude. We live at the bottom of an ocean of fluid— the fluid is air & “ocean” is the atmosphere.

50. Unnumbered Figure 13.2

51. 24-Feb-16 Physics 1 (Garcia) SJSU Demo: Stop the Funnel Water will not enter an air-tight container. H A Weight A A A Block exit hole

52. 24-Feb-16 Physics 1 (Garcia) SJSU Atmospheric Pressure Atmospheric column of air Base: 1 square meter Height: 10 kilometers (10,000 m) Volume: 10,000 cubic meters Mass: 10,000 kilograms Weight: 100,000 Newtons (= 22,000 lb = 11 tons) Pressure: 100,000 Pascals (= 15 lb per sq. inch)

53. 24-Feb-16 Physics 1 (Garcia) SJSU Demo: Magdeburg Hemispheres Pair of hemispheres fit together with air-tight seal Most of the air is pumped out from the interior. Air pressure holds the two pieces tightly together. A A A A L A L - Atmospheric pressure - Low pressure

54. Barometer Any device that measures atmospheric pressure. A simple mercury barometer: The vertical height of the mercury column remains constant even when the tube is tilted, unless the top of the tube is less than 76 centimeters above the level in the dish—in which case the mercury completely fills the tube. Whatever the width of the tube, a 76- centimeter column of mercury weighs the same as the air that would fill a super-tall 30-kilometer tube of the same width. A water barometer would be —13.6 times as long, or 10.3 meters high— too tall to be practical. You may recognize this number as the density of mercury relative to that of water

55. Strictly speaking, these two do not suck the soda up the straws. They instead reduce pressure in the straws and allow the weight of the atmosphere to press the liquid up into the straws. Could they drink a soda this way on the Moon? 24-Feb-16 Physics 1 (Garcia) SJSU

56. 24-Feb-16 Physics 1 (Garcia) SJSU Demo: Drinking Straw L AA With lungs, you reduce pressure in your mouth and in the straw. The higher pressure on the outside pushes the liquid up the straw. Force due to the pressure difference must match or exceed the weight. Weight NO “SUCKING” FORCE

57. 24-Feb-16 Physics 1 (Garcia) SJSU Prairie Dog Vacuum Prairie dogs captured by giant vacuum truck with a padded bin. L A Force

58. There is a 10.3-meter limit on the height that water can be lifted with vacuum pumps.  At sea level, however strong your lungs may be, or whatever device you use to make a vacuum in the straw, the water cannot be pushed up by the atmosphere higher than 10.3 m. “hard vacuum- orbiting in space- satellites can reach 10 −13 Pa. A vacuum pump simply provides a region of lower pressure into which fast-moving gas molecules randomly move.

59. Boyle’s Law Density of a gas increases as it is compressed (volume decreased) As the density of a gas increases, the pressure in the gas also increases. P 1 V 1 = P 2 V 2 Compress the gas by pushing in the syringe. Dial gauge shows increase in pressure. Syringe Gauge Tank

60. Boyle’s Law A flat tire registers zero pressure on the gauge, but a pressure of about one atmosphere exists there. Gauges read “gauge” pressure— pressure greater than atmospheric pressure. Double volume & ½ pressure Dec speed of partaicles Dec. temp Decrease volume Density and pressure are increased P 1 V 1 = P 2 V 2 applies to ideal gases.

61. Boyle’s Law Boyle’s law applies to ideal gases. An ideal gas is one in which the disturbing effects of the forces between molecules and the finite size of the individual molecules can be neglected. Air and other gases under normal pressures approach ideal-gas conditions. the product of pressure and volume for a given mass of gas is a constant as long as the temperature doesn’t change pressure and volume are inversely proportional;

62. Archimedes’ principle holds for air just as it does for water: An object surrounded by air is buoyed up by a force equal to the weight of the air displaced. any object less dense than air will rise in air (Left) At ground level, the balloon is partially inflated. (Right) The same balloon is fully inflated at high altitudes where surrounding pressure is less

63. Rising motion of balloons are caused by unbalanced forces. The air beneath exerts more force than the air above. When it reaches an altitude where the forces are equal, it stops rising.

64. Unlike water, the atmosphere has no definable surface. There is no “top.” Furthermore, unlike water, the atmosphere becomes less dense with altitude 24-Feb-16 Physics 1 (Garcia) SJSU Plasma An electrified gas containing ions and free electrons. Most of the matter in the universe is in the plasma phase.

65. 24-Feb-16 Physics 1 (Garcia) SJSU Demo: Neutral Buoyancy Balloon Tie a helium balloon to a long string and allow it to float upward until it can lift no more string. Cut the string where it touches the floor. Weight of balloon and string exactly balance the buoyant force.

66. How high will a balloon rise? At ground level the balloon is partially inflated, but at high altitues it is full when the surrounding pressure is less. (1) A balloon will rise only so long as it displaces a weight of air greater than its own weight. Air becomes less dense with altitude, so, when the weight of displaced air equals the total weight of the balloon, upward acceleration of the balloon ceases. (2) When the buoyant force on the balloon equals its weight, the balloon will cease to rise. (3) When the average density of the balloon (including its load) equals the density of the surrounding air, the balloon will cease rising

67. Bernoulli’s Principle- fluid dynamics Where the speed of a fluid increases the pressure in the fluid decreases. This phenomenon is due to energy conservation; when fluid’s kinetic energy increases (velocity increases) its internal potential energy (pressure) decreases. A L Still Air Wind

68. Bernoulli’s principle

69. 24-Feb-16 Blow the Roof If wind blows hard enough the low pressure above can create a large enough force to lift the roof off. New Orlean’s Superdome after hurricane Katrina L A Even a small pressure difference over a large roof area can produce a large upward “lifting” force

70. 24-Feb-16 Physics 1 (Garcia) SJSU Check Yourself Wind blowing over the ocean causes waves to build due to Bernoulli’s principle. Where is the pressure lowered?

71. 24-Feb-16 Physics 1 (Garcia) SJSU Demo: Blow the Funnel Blow hard through a funnel with a ping pong ball in the funnel’s bowl. Ping Pong Ball BLOW

72. 24-Feb-16 Physics 1 (Garcia) SJSU Demo: Keep It Up Objects in a moving steam of fluid are pulled to the center of the stream because pressure is lower inside the stream than outside. L A L A A A L L A A

73. Airfoil - shape of wing Lift- upward force which results when the pressure on upper surface is less Drag- opposing force to forward motion Thrust - force which pushes the plane forward provided by plane’s propeller/jet

76. 24-Feb-16 Physics 1 (Garcia) SJSU Airplane Wing Pressure difference created by Bernoulli effect creates upward lift. L A Wing LIFT FORCE

78. Curving may be increased by threads or fuzz, which help to drag a thin layer of air with the ball and to produce further crowding of streamlines on one side. a) The streamlines are the same on either side of a nonspinning baseball. (b) A spinning ball produces a crowding of streamlines. The resulting “lift” (red arrow) causes the ball to curve, as shown by the blue arrow.

79. Bernoulli’s principle plays an important role for animals living in underground burrows. Entrances to their burrows are usually mound shaped, producing variations in wind speed across different entrances. This provides necessary pressure differences of air to enable circulation in the burrow How does this relate to fireplaces? On a windy day, waves in a lake are higher than normal. Why?

80. Plasma An electrified gas containing ions and free electrons. Most of the matter in the universe is in the plasma phase. The Sun and other stars are largely plasma Also fluorescent & neon lights, plasma TV, auroras a plasma (different from a gas) readily conducts electric current, it absorbs certain kinds of radiation that pass unhindered through a gas, it can be shaped, molded, and moved by electric and magnetic fields.

81. Plasma Power MHD power, the magnetohydrodynamic interaction between a plasma and a magnetic field. Low-pollution MHD power is in operation at a few places in the world already. operate at high temperatures without moving partsmoving parts Fusion power may not only make electrical energy abundant, but it may also provide the energy and means to recycle and even synthesize elements In submarines, low speed MHD generators using liquid metals would be nearly silent, eliminating a source of tell- tale mechanism noise. In spacecraft and unattended locations, low-speed metallic MHD generators have been proposed as highly reliable generators, linked to solar, nuclear or isotopic heat sources.

82. Pascal’s Principle Explains hydraulic systems Pressure is exerted equally throughout a closed container Hydraulic systems multiply force(over a greater distance)

83. Bernoulli’s Principle Pressure exerted on a moving steam of fluid is less than the pressure of the surrounding fluid Explains Flight

84. Archimedes’ Principle (Sinks) Buoyant force on an object is equal to the weight of the fluid displaced If an object floats- the volume of displaced water = volume of the portion of the object that is submerged.

85. Pressure P = force/area The force of all the collisions Force-Measured in Newtons, N Area- m2 Pascal- SI unit of pressure = pascal, Pa, 1 N/m2

86. Fluid pressure in the Environment The atm. Pushes downward due to gravity causing atm pressure = 100 000 Pa

87. As you move up & down in the atm & in water, the pressure changes Pressure is greatest the farther down you go Altitude is the most important factor in surface air pressure.