Chapter 9 Gravity (and some Satellite Motion)! Universal Law of Gravitation Universal Gravitational Constant (“G”) Inverse Square Law Weight and Weightlessness

Chapter 9 Gravity (and some Satellite Motion)!

Universal Law of Gravitation

Universal Gravitational Constant (“G”)

Inverse Square Law

Weight and Weightlessness

Satellites – Circles and Ellipses/Energy Considerations

Gravity and Ocean Tides

Gravitational Fields and Black Holes!

Universal Law of Gravitation

mass1 mass2

distance2

Force ~

mass1

mass2

dG m1 m2

d2

Force =

This force is always attractive and exists between every pair of masses in the universe!

If d is large we can approximate any object by a point particle at its center of mass. For a sphere we can do this at any distance (outside the sphere).

THE Universal constant “G”

Where does “G” come from?????

G = 6.67 10-11 N m2/kg2

G m1 m2

d2

Force =

This law has been verified from ~10-6 m to the largest distances probed with telescopes.

Extremely weak Force!

m1

m2

One Experimental Method(von Jolly) 6 TON lead sphere!

mercuryBalance – Measure F to restorethe balance!

Force (N)

distance from the surface of the Earth (in Earth Diameters)

1N

1 2 3 4 5

1/4N

Force on an apple as it moves away from the earth

0

d Rearth ~ 6400 KmMearth ~ 6 1024 Kg

G m1 Mearth

(Rearth + d)2

Force = - If you know G thiscan be used to measure the mass ofthe Earth!

Other influences also decrease as 1/R2 ! (sound, light from a star, etc.)

http://hubblesite.org/gallery/

When at rest on the launching pad, the force of gravity on the space shuttle is quite huge—the weight of the shuttle. When in orbit, some 200 km above Earth’s surface, the force of gravity on the shuttle is

1. nearly as much.2. about half as much.3. nearly zero (micro-gravity).4. zero.

(Neglect changes in the weight of the fuel carried by the shuttle.)

Answer: 1Discounting the changes in the fuel, the gravitational force on the shuttle in orbit is 94% as much as when on Earth’s surface—nearly the same!


Weight = m”g”

More general definition of weight:

The weight of an object is the force the object exerts against a supporting surface (floor) or a weighing scale.

G Mearth m

Rearth2

Net Force = = m a = m “g”

a = g a = -g

What do the scales read in each case?

scale

Satellites (cont’d)

Circular Orbits

Elliptical Orbits

- 8Km/s tangential speed!- Near surface, about 90minutes to orbit,- If further away “g” is less, orbital speed is slower, they move a longer distance --> so it takes longer!

GPS satellites – about 12 hour orbits Geosynchronous – about 24 hour orbits. Moon – 27.3 days for orbit!

-Move faster than 8km/s(overshoots a circle)

-Kepler’s Laws!

Real-time tracking @ http://www.n2yo.com/

Ocean Tides

Tides are caused by the rotation of the Earth combined with differences (about 6.7%)in the gravitational pull between the moon and the earth on the opposite sides of the earth!

Earth

Moon

Rotation axis

Pull on ocean fromMoon is larger here (not to scale!)

Pull on ocean fromMoon is smaller here • 2 high tides and 2 low tides per day!

• Spring tides/Neap tides

The ocean remain bulges are fixed while we rotate in and out of them!

Nasa

http://home.hiwaay.net/~krcool/Astro/moon/moontides/

Satellites

An Earth satellite is a projectile that falls around the Earth rather than into it!

Earth’s Surface

8000m (8Km ~5miles)

5m

Because the Earth is spherical, the earth’s surface drops ~5m for every 8000m tangent to the surface.

If you could throw a ball so that it only dropped 5m after traveling 8Km then the ball would follow the curvature of the Earth (we are not worried about mountains here)!

•Remember d = ½ gt2 ? It takes the ball about a second to drop 5m!So you have to throw it at 8 Km/s so that it orbits the Earth!

• The tangential velocity keeps satellites from colliding (the moon into the earth, the earth into the sun, etc.)

Gravitational Fields

- We can imagine that any mass (even us!) sets up a gravitational field of force around is that attracts any “test” mass that is placed nearby.

We think of the mass as altering the space around it!

What is the gravitational field like INSIDE the Earth?

What is a “black” hole and should I be worried about particle accelerators creating them?

The Universal Law of Gravity

1. In what sense does the moon “fall”?

2. State Newton’s law of universal gravitation in words and in an equation!

3. What is the gravitational force between two 1Kg masses 1m apart?

4. What is the gravitational force between the Earth and a 1Kg mass?

5. What do we call the gravitational force between the Earth and your body?

The Inverse Square Law

6. If you travel four times further from the sun the amount of light to reach you is _________ as much.

For Review


1. Give an example of when your weight is more than mg and another when your weight is less than mg. How about zero?

Tides

2. Why do both the sun and moon exert a greater gravitational force on one side than the other?

3. Gravitational force depends on the inverse _______ of distance. Tidal force, the difference in gravitational force per unit mass, depends on the inverse _________ of distance.

4. What’s the difference between spring tides and neap tides?

5. Do tides occur inside the Earth? Are they also greatest during a new or full moon?

6. Does the moon rotate (spin) on its axis? Does it spin and revolve about the Earth?

1. When the moon’s long axis is not aligned with the Earth there is a rotational force, or ________ about the Moon’s center.

Black Holes etc!

2. If the Earth shrank with no change in mass what would happen to the gravitational force on you if you stayed in the same place as before the earth started shrinking?

3. How can we detect black holes is they are invisible?

4. What percent of the universe is currently thought to be composed of an unknown form of matter (dark matter) and an unidentified form of energy (dark energy).

Exercises

1. Comment on whether the following label should be cause for concern: CAUTION: the mass of this product pulls on every other mass in the universe!

2. What would be the path of the Moon if somehow all gravitational forces on it vanished to zero?

3. A friend says that astronauts are weightless in orbit because they are beyond the pull of Earth’s gravity. Correct your friend!

4. Does the more massive Earth attract the less massive Moon with a force that is greater/smaller/the same as the force that the Moon attracts the Earth?

5. An astronaut lands on a planet that has twice the mass of Earth and twice the radius. How does the astronaut’s weight differ from their “Earth” weight?

6. The intensity of light from a central source varies inversely as the square of the distance. If you lived on a planet only half as far from the Sun as the Earth how would the light intensity compare with that at the Earth? How about 10 times further away?

Study Guide Exam #2 Momentum, Energy, Rotational Motion and Gravity(Chapters 6-9)

The exam will be based on the homework Review Questions, Exercises, and Quick Calculations from these chapters! The format is the same as the previous exam – multiple choice, true-false, fill in the blank, write-out the answer type questions, and quick calculations. Equations that will be provided:

v =d/t, a = v/t, v = at, d = ½ at2, a = F/MP = mv, Impulse = Ft = mv, W = Fd, P = W/t, PE = mgh, KE = ½ mv2, W = KE, v = r , Torque = lever arm F, F = mv2/R, Angular momentum = I (= mvr sometimes), F = Gm1m2/d

2

You should:- Be able to define, use the correct units, and do quick calculations (using the equations provided) of momentum, kinetic energy, gravitational potential energy, work, power, angular momentum, torque, centripetal force, and angular momentum!

In momentum, you should

o Understand what impulse is and the relationship of impulse to changes in momentum.

o Be able to state the Law of Conservation of (Linear) Momentum.

o Know the difference between an elastic and inelastic collision.

In energy you should

o Understand the difference between momentum and energy (kinetic and potential (which is a vector and which is a scalar?)

o Understand what doing work means and that power is the rate at which work is done.

o Understand the work energy Theorem (e.g., how far does the car slide before it comes to a stop?)

o Be able to state the Law of Conservation of Energy!

o Be able to give examples of different types of energy sources (is hydrogen a source of energy or a way of storing energy?)

o Know the basic principle of the operation of a machine.

In Rotational motion you should

o Understand the difference between tangential and angular velocity.

o Understand what rotational Inertia means and how it affects the rotational motion of objects.

o What torque is and how the concept can be applied.

o Understand center of mass and stability.

o Know that an object moving in a circle experiences a force toward the center (centripetal).

o Be able to State the Law of conservation of angular momentum

Chapter 13 Liquids!

Pressure -definition

Pressure in a Liquid

Bouyancy

Archimedes’ Principle

What makes an Object Sink or Float?

Flotation

Pascal’s Principle

Surface Tension and Capillarity

http://en.wikipedia.org/wiki/Liquid

Liquids– Phases of matter (solid,liquid, gas)

- The motion of molecules and how far they stray from one another defines the phase of a collection of molecules

Unbound

Loosely Bound – matter flows

Strongly Bound – fixed positions

-The temperature of a collection is determined by the average kinetic energy of the collection and can determine the phase.

(1) The volume of a completely submerged object is (equal to/less than/greater than) the volume of the fluid it displaces.

(2) The buoyant force on a completely submerged object in a fluid is (equal to/less than/greater than) the weight of the fluid it displaces.

True/False

(3) The mass of a completely submerged object is equal to the mass of the fluid it displaces. ___

Question (4) The relative densities of ice, water and alcohol are 1.0, 0.9, and 0.8 respectively. Do ice cubes float higher or lower in a mixed alcoholic drink? What comment can you make about a cocktail in which ice cubes lie submerged at the bottom of the glass! ?

Bonus Quiz!

Pressure = Force/Area

-You are under a lot of pressure when there is a large force exerted on you over a small area!

P = F/A (the unit is called the Pascal, N/m2)

An Elephant versus a pin?

- When we talk about fluids and forces we use the concept of pressure.

2 blocks of the same mass. Which exerts more pressure on the table?


Liquid Pressure = Weight density Depth

- more dense fluids exert more pressure- the further the object is submersed the higher the pressure


- If you are submerged in a liquid the pressure on you depends on 3 things:

(a) Your depth below the surface of the liquid (d).(b) The density () of the liquid(c) The acceleration due to gravity (g)! (different on the moon)

P = g d

d

Fluid, density =

The origin of the force is from the weight of fluid above the object

In general there may be more than one fluid contributing to the force (example: pressure on a fish in the gulf includes the air from the atmosphere above the ocean).

Area = A

Weight of fluid above A = mgVolume of fluid above A = Ad

Pressure in a Liquid (cont’d)

Pressure = Force/Area = mg/A

The mass is the density times volume:m = V = A d

Pressure = (Ad)g/A = gd

Quick Calculation – Water pressure

Calculate the pressure exerted on your head by the surrounding water when you are 1m below the surface of a swimming pool.

Hints: water = 1g/cm3 or 1000Kg per m3


•Liquid pressure does not depend on the volume of the liquid you are submerged in

-At a given depth below the surface the pressure is the same in the Atlantic ocean as in a swimming pool (aside from density differences!).

• “Water seeks its own level” (steady-state)

-Since water depends on depth, not volume, water will adjust its depth in any vessel to maintain the same pressure at any given depth. If it did not, the pressure difference would cause a flow in the fluid to equalize the pressures. (water can flow “uphill” to equalize pressures)

Open at the bottom andImmersed in fluid!


• Experimentally, liquid pressure on a submerged object is exerted in all directions equally at a given depth! (pressure can act “sideways”, up and down).

• When a liquid presses against a surface there is a net force perpendicularto that surface. We can look at the pressure dependence of depth by poking holes in a cup!

Buoyancy

- An upward force on immersed or submerged objects equal to the weight of the fluid the object displaced.

d

Block displaces a volume of fluid equal to its volume (V)

There is more pressure at the bottom than the top of the block!

Pressure on the sides cancel. The net result is a force upward on the block.

d

Bouyancy (cont’d)

Difference in pressure across the block (the top to the bottom) = g d

Force up = g d times Area= g times Volume of Object (V)= V g

= Mass of Fluid displaced by the volume of the object times g

= “Weight of fluid displaced by the objects immersed volume”

Fluid, density =

(Does it matter at what depth I place the object?)

d

We can show where this upward force comes from:

Buoyancy (cont’d)

This is Archimedes’ Principle:

An immersed object is buoyed up by a force equal to the weight of the fluid it displaces.

Check: If an object is placed in water and displaces 1Kg of water, what is the buoyant force on the object?

Check: Do objects placed in water weigh less than in air? How much?

Check: An object is thrown into a well and sinks deeper and deeper. Does the buoyant force change?

Quick Calculation – Buoyancy

Estimate the buoyant force on yourself when completely submerged in a swimming pool. How about only ½ immersed?

Hints: water = 1g/cm3 or 1000Kg per m3

(Volume person ~ 0.1m3)

What makes objects sink or float?

We can find out with Newton’s 2nd Law!

At any given time,

Buoyant Force – Weight = ma

fluidV g - Mg = ma

positive

•If submerged and Weight > Buoyant Force then it will sink!•If submerged and Weight < Buoyant Force then it will rise(and may end up partially immersed).

The mass of the object is M = object V

fluidV g - object Vg = ma

ORfluid- object = (m/Vg) a

fluid- object = (m/Vg) a (submerged object)


The same rule from Newton’s 2nd Law are that a submerged object

- sinks when the density of the object is greater than the fluid- rises when the density of the object is less than the density

of the fluid- floats (a=0) when the densities are the same!

Principle of Flotation: A floating object displaces a weight of fluid equal to its own weight:

Buoyant Force = Weight of Object

Floating object only!


Wait. If I put an ice cube in water it floats but part of it is immersed. Can I figure out how much?

Yes. The volume submerged is the volume required such that the buoyant force is the same as the weight of fluid displaced.

fluidVimmersed g - Mg = Ma = 0

Total mass = object Vtotal

Vimmersed

Vtotal

=

object

fluid

Buoyancy Exercises

1. A block of aluminum with a volume of 10cm3 is placed in a beaker of water filled to the brim. The same is done in another beaker with a 10cm3 block of lead. Does lead displace more, less or the same amount of water?

2. A block of aluminum with a mass of 1kg is placed in a beaker of water filled to the brim. The same is done in another beaker with a 1kg block of lead. Does lead displace more, less or the same amount of water? (hint: which has the larger volume for a given mass?)

3. A block of aluminum with a weight of 10N is placed in a beaker of water filled

to the brim. The same is done in another beaker with a 10N block of lead. Does lead displace more, less or the same amount of water? (hint: which has the larger volume for a given mass?)

4. If liquid pressure were the same at all depths would there be a buoyant force on an object submerged in the liquid?

Pascal’s Principle

A change in pressure at any point in an enclosed fluid at rest is transmitted undiminished to all points in the fluid.

An example is the simple machine, the hydraulic press!

(Machine: a device for multiplying forces or changing the direction of forces.Energy is conserved.)

Machines!

f D = F d

http://en.wikipedia.org/wiki/Hydraulic_press

Surface Tension

-Water molecules like other water molecules (cohesion)!

Why is this a “surface” effect rather than a volume effect?

Because at the surface the molecules are pulled preferentially “down” into the other water molecules. Molecules below the surface are pulled everywhere equally!

Capillarity

-Water molecules like molecules other than water molecules also (adhesion)!Adhesive force = Weight of Fluid lifted

www.digitalfieldguide.com/.../2006/09/page/2/

1. Give 2 examples of a fluid.

2. Distinguish between Force and Pressure

3. If you swim beneath the surface in salt water will the pressure be (the same/greater/less) than fresh water at the same depth?

4. How does water pressure 1m below the surface of a small pond compare with 1m below the surface of a huge lake?

5. If you punch a hole in a container filled with water, in what direction does the water initially flow out?

6. Why does a buoyant force act upward on an object submerged in

water?

7. Why is there no horizontal buoyant force on a submerged object?

8. How does the volume of a completely submerged object compare with the volume of water displaced?

For Review - Liquids

1. Why does the buoyant force act upward on an object?

2. What is the mass of 1L of water? Weight?

3. If a 1L container of anything is immersed halfway into the water, what is the volume of water displaced?

4. Is the buoyant force on an object equal to the weight of the object or the weight of the fluid it displaces?

5. How is the density of a fish controlled? A submarine? 6. What is the principle of flotation?

7. A non-sinking 100 ton ship displaces what weight of water? What is the buoyant force on the 100 ton ship?

For Review - Liquids

Some Exercises! - Liquids

1. Which do you suppose exerts more pressure on the ground – an elephant or a lady standing on spiked heels?

2. If water faucets upstairs and downstairs are turned on which do you suppose will flow faster or do they flow at the same rate?

3. Look at the teapots in exercise 12 of the chapter. The teapot on the left holds less/more/the same amount as the teapot on the right.

4. If liquid pressure were the same at all depths would there be a buoyant force on an object submersed in the liquid?

5. Why will a volleyball held beneath the surface have more buoyant force than if it is floating?

6. A piece of iron placed on a block of wood makes it float lower in the water. If the iron were instead suspended beneath the wood would the wood float higher lower or the same?

More exercises..!

7. Will a rock gain or lose buoyant force as it sinks deeper in water?

8. When an ice cube in a glass of water melts does the water level in the glass rise, fall or remain the same? (What does this say about the North polar ice cap melting in terms of sea level change?) Does the answer change if the ice cube has air bubbles in it? How about sand (*this one is hard!)?

Chapter 14 Gases and Plasmas!

The Atmosphere

Atmospheric Pressure Barometer

Boyle’s Law

Buoyancy of Air

Bernoulli’s Principle

Plasmas

Our Atmosphere

Why is it spherical and why doesn’t it just drift off into space?

Gravity versus Kinetic Energy!

The sun provides the kinetic energy and the Earth provides the gravitational attraction.

Most of the “air” stays very close to the Earth’s surface: - 99% of our atmosphere is less than 30Km from the surface and the radius of the Earth is ~6400Km!

Some gas molecules escape but they have to have a very large kinetic energy.

Some molecules get trapped too.

www.whatiscience.com/.../Atmosphere.jpg

EARTH

R =6,400Km

Atmosphere (not too scale)It is thinner than this!

EARTH

The Atmosphere

Composition:

~78% Nitrogen ~21% Oxygen ~0.93% Argon~0.035% Carbon dioxide

The Atmosphere: The Ocean we swim in!

How much mass is there in 1m3 of air?

air ~ 1.25 Kg/m3

Roughly, what mass of air is in the lecture room? About 1000 Kg (2,200 lbs)!

1m

1m

1m

This density actually depends on how far you are above Earth’s surface.

air ~ 0.4 Kg/m3

At 10 Km above the surface

At the surface of the Earth

(National geographic)

Just like liquids pressure from air is the result of the mass of the air above you!

Unlike liquids, gases are compressible (can be readily compressed) and they become less dense the higher you go! So for gases we DO NOT have

Atmospheric Pressure

A block just sitting there

Column of air above the block

P = g d Since the density is not constant(over an appreciable distance)!

Atmospheric Pressure

Column of air above Area A

Pressure = Force/Area = Weight of Air/Area

Area = A

A column of air about 30Km high (99% of atmosphere)with an area of 1cm2 has a mass of ~1Kg

Pressure at surface ~10N per square cm

= 100,000 N/m2 (~100 KPa)

(the average is actually 101.3 KPa)

How do we survive such a tremendous force??It is pressure differences that create a net force!

Barometers

Can we make a water barometer to measure the local pressure from the atmosphere?

Sure, but it will need to be about 10.3 m tall!

Vacuum ( tube is closed at the top)

Air pressure

Air pressure pushes water up the column

Weight of column of water =Force of the Atmosphere!

Vacuum ( tube is closed at the top)

Atmospheric pressure

Air pressure pushes water up the column: Patmosphere Area

Weight of column of water =Force of the Atmosphere!

Mg = Patmosphere Area(water V) g = Patmosphere A(water A h)g = Patmosphere A

(waterh)g = Patmosphere

(Newton’s 2nd Law again)

(It does not depend on the area of the tube!)

Patmosphere

watergh =

So the height to which the water rises in a closed vessel tells us the atmospheric pressure:

~100,000 N/m2

1000 Kg/m3 10m/s2h

We can estimate this:

= 10m

More practically we can use a more dense liquid to find Patmosphere.

If we use mercury (13.6 times as dense) then h ~0.76m and this is easier to have around!

Barometers (cont’d)

mercury

http://home.c2i.net/astandne/help_htm/images/element/mercury.jpg

Where does this come from? Pressure is proportional to density:

Twice the number of molecules means twice the number of collisions= twice the force on the walls

Boyle’s Law What happens as an object “floats” or ascends or descendsthrough the atmosphere?

Pressure Volume= CONSTANT

Does the helium balloonexpand as it rises?

We can increase the density by decreasing the volume!

Density increase due to volume decreasing = Pressure increase

P V= P vAnd they exactly compensate so the product is constant!

Applied external force to compressThe cube

Bouyancy of Air (just like liquids – they are both fluids!)

- An upward force on immersed or submerged objects equal to the weight of the fluid the object displaced.

d

Block displaces a volume of fluid equal to its volume (V)

There is more pressure at the bottom than the top of the block! This is where the buoyant force comes from!

Pressure on the sides cancel. The net result is a force upward on the block.

Air

Buoyancy of Air!

This is Archimedes’ Principle for Air:

An immersed object is buoyed up by a force equal to the weight of the fluid (air here!) it displaces.

Check: If an object is placed in air and displaces 1Kg of air at the surface of the Earth, what is the buoyant force on the object? What is the volume of the object?

Check: Do objects placed in air weigh less than in a vacuum? Does this depend on altitude?

Check: An object is thrown into a well (of water) and sinks deeper and deeper and the buoyant force does not change. What happens to an object dropping through the atmosphere?

fluid- object = (m/Vg) a


The same rule from Newton’s 2nd Law are that a submerged object

- sinks when the density of the object is greater than the fluid- rises when the density of the object is less than the density

of the fluid- floats (a=0) when the densities are the same!

Buoyancy of Air!

Recall that we found for liquids:

For air this equation applies at a particular altitude!

Bernoulli’s Principle

When the speed of a fluid increases, internal pressure in the fluid decreases.

For Fluids in motion not at rest!

FLOW LINES

FLOW LINES

The internal pressure is higher here

The internal pressure is lower here

A big air bubble

A manifestation of conservation of energy!

Increased kinetic energy for any given part of the fluid means less pressure is exerted from molecules within that part.

Each part of a fluid exerts pressure (a force) on another part!

1. What is the energy source for the motion of gases in the atmosphere? What prevents the atmosphere from flying off into outer space?

2. How high would you have to go in the atmosphere would you have to go for ½ of the mass to be below you?

3. What is the cause of atmospheric pressure?

4. What is the mass of a cubic meter of air at room temperature?

5. What is the mass and weight of a column of air 1cm squared in area extending from sea level to the upper atmosphere?

6. What is the pressure at the bottom of the column of air referred to in the previous question?

For Review -Gases

The Atmosphere and Atmospheric Pressure

6. How does the pressure at the bottom of a 76cm column of mercury in a barometer compare with air pressure at the bottom of the atmosphere?

7. How high would you have to go in the atmosphere would you have to go for ½ of the mass to be below you?

8. When you drink liquid with a straw why is it more accurate to say the liquid is pushed up the straw rather than sucked up the straw? What does the pushing?

9. Why will a vacuum pump not operate for a well that is more than 10.3m deep?

10. Why is it that an aneroid barometer is able to measure altitude as well as atmospheric pressure?

For Review -Gases

Barometer

11. By how much does the density of air increase when it is compressed to ½ its volume?

12. What happens to the air pressure inside a balloon when it is squeezed to ½ its volume at constant temperature?

13. What is an ideal gas?

14. A balloon that weighs 1N is suspended in air drifting neither up nor down. (a) How much buoyant force acts on it? (b) What happens if the buoyant force decreases? Increases?

15. Does air exert a buoyant force on all objects in air or only on objects such as balloons that are very light for their size?

16. What happens if you release a helium balloon into the atmosphere?

For Review -Gases

Boyle’s Law and Buoyancy of Air

Some Exercises! -Gases

1. Why is the pressure in an automobile’s tires slightly greater after the car has been driven several kilometers (or miles).

2. When an air bubble rise in water what happens to its mass, volume, and density?

3. When boarding an airplane you bring a bag of chips and, while you are in flight, notice that the bag of chips puffs up. Explain why this happens.

4. We can understand how pressure depends on depth by staking bricks. The pressure below the bottom brick is the weight of the full stack and ½ way up the stack only ½ the bricks above contribute to the pressure. Why should we consider compressible bricks to explain atmospheric pressure?

5. The “pump” in a vacuum cleaner is merely a high speed fan. Would a vacuum cleaner pick up dust from a rug on the moon? Explain.

Some Exercises! -Gases

6. Your friend says that the buoyant force of the atmosphere on an elephant is significantly greater than the buoyant force of the atmosphere on a small balloon. What do you say?

7. Two Identical balloons of the same volume are pumped up with air to more than atmospheric pressure and suspended on the ends of a stick that is horizontally balanced. One of the balloons is punctures. Is the balance of the stick upset? If so, which way does it tip?

8. The force of the atmosphere on a 10m2 window is about a million N. Why doesn’t the window break? Why might the window shatter when a strong wind blows past the window?

9. What provides the lift to keep a Frisbee in flight?

Chapter 22 Electrostatics

Electrical Forces

Electric Charges

Conservation of Charge

Coulomb’s Law

Conductors and Insulators/Superconductors

Charging – Friction/Induction

Charge Polarization

Electric Field and Potential

Electric Energy Storage

mcdermott.chem.columbia.edu/biophys/intro_ima...

-Electrostatics

The study of stationary (not moving) Electric Charges.

-Electrodynamics

The study of moving charges.

Where does electric charge come from and why must matter be (almost) electrically neutral?

- There are two types of charge and we call them negative and positive- Opposite charges attract, like charges repel! Why, we don’t know.

The origin of charge in our daily wanderings is from two elementary particles: the electron and up and down quarks (which combine to form the +1 proton and neutral neutron)

q1

q2

Electric Charges: the origin of electricity and magnetism

+

- Schematic of a Hydrogen atom

Nucleus (~ 10-15 m) with one proton (and zero, 1 or more neutrons)

Electron( < 10-18 m)

Every atom is

(1) Composed of a positively charged nucleus of protons (q =+1) and neutrons (q =0)(2) Negatively charged Electrons (-1) “orbit” the nucleus at fixed distances.(3) Mproton ~ 1800 Melectron

(4) Atoms usually have equal numbers of negative and positive charges

(Ordinary) matter is composed of lots (1023) of atoms and is almost perfectly neutral!

r ~ 10-10 m

Conservation of Charge

Charge can be neither created nor destroyed only transferred from one object to another.

Atoms can lose an electron but some other atom must acquire that charge!

+

A positively charged hydrogen ion = a proton! (and maybe a neutron or 2)

Where is my electron! ?

-A charge imbalance occurs when electrons are transferred from 1 object to another.

-Electrons furthest away from the nucleus are loosely boundand can be “set free” if they are given some energy.

-Real materials (like hair, plastic, metals) hold onto their Electrons with different strengths.

Conservation of Charge (cont’d)

-Preference for holding onto their electrons:

Silk > Glass > Rubber > Plastic > Hair

-Ease with which they give up their electrons:

Hair > Plastic > Rubber > Glass > Silk

A Comb transfers electrons from your hair to the comb!

www.abcgallery.com/R/renoir/renoir127a.jpg

Comb becomes negatively charged

Hair becomes positively charged!

There is an actual difference of integer numbers of electrons, like 123,766,218,196 electrons.

Coulomb’s Law

charge1 charge2

distance2

Force ~

charge1

charge2

dk q1 q2

d2

Force =

Another inverse square law! This one can be attractive or repulsive.This time, however, the proportionality constant k is

k = 9,000,000,000 Nm2/C !!!

k = 9 109 N m2/C2

k q1 q2

d2

Force =

Coulomb’s Law (cont’d)

What is a “Coulomb” of charge? 1 electron has a charge of 1.6 10-19 C.

So 1 C = 6.25 billion billion (6.25 1018) electrons worth of charge!

-For direct current this is about the amount of charge passing through a 100W bulb in 1s (~100 joules of energy).

Electrical force between two stationary charges:

Even for highly charged objects the charge imbalance is only 1 part in a trillion.

q1

q2

d

Conductors and Insulators

Conductor: electrons in outer atomic shells are “free to wander.” Relation to thermal conductivity.

- metals

Insulator: electrons in outer atomic shells are not “free to wander” and

All materials can be classified by the ease with which they conduct electric charge

Good conductor

Insulator

Ease with which electrons areMoved about

Wood, plastic, rubber, glass

Semi-conductors (germanium, silicon)

Copper, Iron

Semi-Conductors: materials that can be made to behave like a conductor or like an insulator.

Most of our current technology relies on semiconductors sandwiched together which are used to control the flow of charge! (transistors)

Some semiconductors can also conduct when light is shone on them.

In general their resistance to the flow of electrons can be altered by heat, light, magnetic fields, etc.

Super-Conductors: materials that conduct perfectly (usually at a very low temperature!)

members.tripod.com/~ComputerLab/micropro.jpg

Charging- the transfer of electrons by physical contact or induction

Initially uncharged Gains a net chargeby touching a charged object.

- - - - --

-

-

(Hollow metal sphere)

Initially uncharged

- - - - - - +

+

-

-

+

+

--

-

+

-

Touch the sphere!Net positive charge remains+

Direct contact

Induction

Charge Polarization

The re-arrangement of charges in a material in response to an externalNet charge.

In conductors, the electrons can moveIn insulators, the atoms or molecules themselves become polarized!

- + -Negative chargeOutside the molecule

Rearrangement of charge within The molecule (net charge =0)

Some molecules have an intrinsic uneven distribution of charge (like water!) and we say these are “polar” molecules.

Electric Field: The force per unit charge at some location in space.

E = Fe/(+q)

The direction is defined by the direction of the forcea positive “test” unit charge would feel at that point!

+q

E

-

+q

Therefore, for a given source of charge, an electric Field is defined everywhere in space.

A source of Net charge (-)

k q1 q2

d2Fe =


http://buphy.bu.edu/~duffy/PY106/2e.GIF

son.nasa.gov/tass/images/electric_fields2.jpg


Energy is stored in the electric field and energy can be transported by the electric field! (over very long distances).

Electric Shielding: Because electric forces can be attractive or repulsive we canshield objects from any external electric field!

For any conductor all of its net charge (If any) resides on the surface.

The charge is distributed so that the electric field inside the conductor is zeroEverywhere!

www.physics.gla.ac.uk/.../E3/pfarad1.gif

No electric fields allowed in here!

Metal wire cage(Faraday cage)-a conductingSurface.

Electric Potential:

The electric potential energy per unit charge.

Just like 2 masses can have a gravitational potential energy associated with their relative positions, 2 charges can have an Electrical Potential energy associated with their relative positions!

h PE =mgh

+

-

PE ~ q1q2/hh

Surface of Earth

Gravitational Potential Electric Potential

If we release the mass it will gain KE.If we release the + charge (and “hold” the – charge) the + charge will gain KE!

Electric Potential:


The electric potential energy is the energy associated with the position of a Charge in an electric field.

If I bring two similar sign charges together I must do work (because the force is repulsive).

By doing so I increase the Electric potential energy associated with the charges.

+

+

+

+ +

qIf the charge q is doubled then the Electric potential energy is doubled.

But the amount of potential energy per electron will remain the same -> this is the electric potential.

It is defined by the electric field

d

Electric Potential :


The Unit = the VOLT = 1 Joule per Coulomb

A 1 Volt battery generates 1 Joule of energy for every Coulomb of charge passing through the battery.

The difference in electrical potential between 2 points (in space)is called the voltage between those points.

d

Potential 1

Potential 2

Voltage = Potential 2 – Potential 1

If the force on any charge is different at 1 than at 2 then there is a voltage difference between these two points

Electric Energy Storage- Capacitors

Simple parallel plate capacitor:

-Charge is distributed to each plate, the amount determined by the battery voltage and the capacitance of the device.

- Roll up it up and we have a cylindrical capacitor used in almost every electronic device for energy storage

- release of large amounts of charge in a short time (large energy transfer- dangerous!)

Cameras, PCs, TVs, etc.

Amount of charges stored = C * Voltage, C = "capacitance of the device“

Units of capacitance are coulombs per volt

Review Questions:

1. Why does the gravitational force between Earth and the Moon predominate over electrical forces?

2. How does the charge of one electron compare to that of another electron. Are two electrons different? How does the electron charge compare with the charge of a proton?

3. How do the numbers of protons in the nucleus compare with the number of electrons that orbit the nucleus?

4. What is an ion? Give an example of a positive and negative ion.

5. What is meant by saying charge is conserved?

6. What is meant by saying charge is quantized?

7. What particle has exactly one quantum unit of charge? How about charge 1/3?

8. How does 1 Coulomb of charge compare with the charge of a single electron?

9. How is Coulomb's Law similar to Newton's Law of Gravitation? Different?

10. Why are metals god conductors of heat and electrons?

11. What are materials such as glass and rubber good insulators?

12. How is a semiconductor different than a conductor or insulator?

13. What happens to electrons during any charging process?

14. Example of charging by friction?

15. Example of charging by contact?

16. Example of charging by induction?

17. What do we use lightning rods?

18. How does electric polarization differ from an electrically charged object?

Review Questions (cont’d):

19. What is an electric dipole?

20. How is the magnitude and direction of the electric field defined?

21. Why is there no electric field at the center of a charged solid spherical conductor (e.g., a steel ball)?

22. When charges mutually repel and distribute themselves on the surface of a conductor what effect occurs inside the conductor?

23. How much energy is given to 1C of charge that flows through a 1.5V battery?

24. A balloon may be charged to several thousand volts! Does this mean it transfers several thousand joules?

25. Where is the energy stored in a capacitor?

Review Questions (cont’d):

Exercises!

1. Why do clothes often cling together after being in the clothes dryer?

2. When combing your hair you transfer electrons from your hair onto the comb.

Is your hair positively or negatively charged? How about the comb?

Can you create a large electric potential between the hair and comb?

3. The tires for trucks transporting gasoline and other flammable fluids are electrically conducting. Why?

4. Strictly speaking, when an object acquires a positive charge by electron transfer, what happens to its mass?

5. When you double the distance between a pair of charged particles what happens to the force between them? Does the change in force depend on the sign of the charges? Their magnitude?

6. When you double the charge on both particles in a pair what effect does this have on the force between them?

Exercises (cont’d)!

7. Compare the electrostatic force on an electron by a proton in a hydrogen atom with the force of gravitional acctraction between them.

8. Measurements indicate that there is an electric field surrounding the Earth. The magnitude, E = 100N/C, and it points toward the center of the Earth. Given this, can you say whether the Earth has a net negative, zero, or positive charge?

9. How can a charged atom attract a neutral atom.

10. Two Pieces of plastic, a full ring and half ring are net positively charged; the 1/2 ring has 1/2 the total charge of the full ring.

At the center of the ring the electric field is largest for which one?

11. Why may it be dangerous to touch the terminals of a high voltage capacitor on a device after the device is turned off (unplugged and not connected to any batteries or other power source)?

Documents

Chapter 9 Gravity (and some Satellite Motion)! Universal Law of Gravitation Universal Gravitational Constant (“G”) Inverse Square Law Weight and Weightlessness