Presentation is loading. Please wait.

Presentation is loading. Please wait.

8. Gravity 1.Toward a Law of Gravity 2. Universal Gravitation 3. Orbital Motion 4. Gravitational Energy 5. The Gravitational Field.

Published byVincent Brown Modified over 8 years ago

Similar presentations

Presentation on theme: "8. Gravity 1.Toward a Law of Gravity 2. Universal Gravitation 3. Orbital Motion 4. Gravitational Energy 5. The Gravitational Field."— Presentation transcript:

1 8. Gravity 1.Toward a Law of Gravity 2. Universal Gravitation 3. Orbital Motion 4. Gravitational Energy 5. The Gravitational Field

2 This TV dish points at a satellite in a fixed position in the sky. How does the satellite manage to stay at that position? period = 24 h

3 8.1. Toward a Law of Gravity 1543: Copernicus – Helio-centric theory. 1593: Tycho Brahe – Planetary obs. 1605: Kepler’s Laws 1592-1610: Galileo – Jupiter’s moons, sunspots, phases of Venus. 1687: Newton – Universal gravitation. Phases of Venus: Size would be constant in a geocentric system.

4 8.2. Universal Gravitation Newton’s law of universal gravitation : m 1 & m 2 are 2 point masses. r 12 = position vector from 1 to 2. F 12 = force of 1 on 2. G = Constant of universal gravitation = 6.67  10  11 N m 2 / kg 2. Law also applies to spherical masses. m1m1 m2m2 r 12 F 12

5 Example 8.1. Acceleration of Gravity Use the law of gravitation to find the acceleration of gravity (a) at Earth’s surface. (b) at the 380-km altitude of the International Space Station. (c) on the surface of Mars.  (a) (b) (c) see App.E

6 TACTICS 8.1. Understanding “Inverse Square” Given Moon’s orbital period T & distance R from Earth, Newton calculated its orbital speed v and hence acceleration a = v 2 / R. He found a ~ g / 3600.  Moon-Earth distance is about 60 times Earth’s radius.

7 Cavendish Experiment: Weighing the Earth M E can be calculated if g, G, & R E are known. Cavendish: G determined using two 5 cm & two 30 cm diameter lead spheres. Gravity is weakest & long ranged always attractive  dominates at large range. EM is strong & long ranged, can be attractive & repulsive  cancelled out in neutral objects. Weak & strong forces: very short-range.

8 8.3. Orbital Motion Orbital motion: Motion of object due to gravity from another larger body. E.g. Sun orbits the center of our galaxy with a period of ~200 million yrs. Newton’s “thought experiment” Condition for circular orbit Speed for circular orbit Orbital period Kepler’s 3 rd law g = 0 orbit projectiles

9 Example 8.2. The Space Station The ISS is in a circular orbit at an altitude of 380 km. What are its orbital speed & period? Orbital speed: Orbital period: Near-Earth orbit T ~ 90 min. Moon orbit T ~ 27 d. Geosynchronous orbit T = 24 h.

10 Example 8.3. Geosynchronous Orbit What altitude is required for geosynchronous orbits? Altitude = r  R E Earth circumference = Earth not perfect sphere  orbital correction required every few weeks.

11 Elliptical Orbits Orbits of most known comets, are highly elliptical. Perihelion: closest point to sun. Aphelion: furthest point from sun. Projectile trajectory is parabolic only if curvature of Earth is neglected. ellipse

12 Open Orbits Closed (circle) Closed (ellipse) Open (hyperbola) Borderline (parabola)

13 8.4. Gravitational Energy How much energy is required to boost a satellite to geosynchronous orbit?  U 12 depends only on radial positions.  U = 0 on this path … so  U 12 is the same as if we start here.

14 Example 8.4. Steps to the Moon Materials to construct an 11,000-kg lunar observatory are boosted from Earth to geosyn orbit. There they are assembled & launched to the Moon, 385,000 km from Earth. Compare the work done against Earth’s gravity on the 2 legs of the trip. 1 st leg: 2 nd leg:

15 Zero of Potential Energy  Gravitational potential energy E > 0, open orbit Open Closed E < 0, closed orbit Bounded motionTurning point

16 Example 8.5. Blast Off ! A rocket launched vertically at 3.1 km/s. How high does it go ? Initial state: Final state: Energy conservation: Altitude = r  R E

17 Escape Velocity Body with E  0 can escape to   Escape velocity Moon trips have v < v esc. Open Closed

18 Energy in Circular Orbits Circular orbits:   To catch the satellite, the shuttle needs to lose energy. It does so by turning to fire its engine opposite its direction of motion. It drops lower, turns again, and fires its engine to achieve a circular orbit, now faster and lower than before. Higher K or v  Lower E & orbit (r). 0 E U K K

19 GOT IT? 8.3. Spacecrafts A & B are in circular orbits about Earth, with B at higher altitude. Which of the statements are true? (a) B has greater energy. (b) B is moving faster. (c) B takes longer to complete an orbit. (d) B has greater potential energy. (e) a larger proportion of B’s energy is potential energy.     

20 8.5. The Gravitational Field Two descriptions of gravity: 1.body attracts another body (action-at-a-distance) 2.Body creates gravitational field. Field acts on another body. Near Earth: Large scale: Action-at-a-distance  instantaneous messages Field theory  finite propagation of information Only field theory agrees with relativity. near earth in space Great advantage of the field approach: No need to know how the field is produced.

21 Application: Tide Sun + Moon  2 high & 2 low tides each day. Tidal forces cause internal heating of Jupiter’s moons. They also contribute to formation of planetary rings.

Download ppt "8. Gravity 1.Toward a Law of Gravity 2. Universal Gravitation 3. Orbital Motion 4. Gravitational Energy 5. The Gravitational Field."

Similar presentations

UNIT 6 (end of mechanics) Universal Gravitation & SHM

UNIT 6 (end of mechanics) Universal Gravitation & SHM
Review Chap. 12 Gravitation

Review Chap. 12 Gravitation
Roger A. Freedman • William J. Kaufmann III

Roger A. Freedman • William J. Kaufmann III
Chapter 12 Gravity DEHS 2011-12 Physics 1.

Chapter 12 Gravity DEHS Physics 1.
UNIFORM CIRCULAR MOTION

UNIFORM CIRCULAR MOTION
Chapter 8 Gravity.

Chapter 8 Gravity.
Chapter 5 Projectile Motion and Satellites. Projectile Motion Describe the motion of an object in TWO dimensions Describe the motion of an object in TWO.

Chapter 5 Projectile Motion and Satellites. Projectile Motion Describe the motion of an object in TWO dimensions Describe the motion of an object in TWO.
Chapter 7 Rotational Motion and The Law of Gravity.

Chapter 7 Rotational Motion and The Law of Gravity.
Gravitation and the Waltz of the Planets

Gravitation and the Waltz of the Planets
Physics 151: Lecture 28 Today’s Agenda

Physics 151: Lecture 28 Today’s Agenda
17 January 2006Astronomy 20101 Chapter 2 Orbits and Gravity What causes one object to orbit another? What is the shape of a planetary orbit? What general.

17 January 2006Astronomy Chapter 2 Orbits and Gravity What causes one object to orbit another? What is the shape of a planetary orbit? What general.
Chapter 4 Making Sense of the Universe: Understanding Motion, Energy, and Gravity.

Chapter 4 Making Sense of the Universe: Understanding Motion, Energy, and Gravity.
Physics 111: Mechanics Lecture 13 Dale Gary NJIT Physics Department.

Physics 111: Mechanics Lecture 13 Dale Gary NJIT Physics Department.
Chapter 13 Gravitation.

Chapter 13 Gravitation.
6. Centripetal force F = ma 1. Example: A stone of mass m sits at the bottom of a bucket. A string is attached to the bucket and the whole thing is made.

6. Centripetal force F = ma 1. Example: A stone of mass m sits at the bottom of a bucket. A string is attached to the bucket and the whole thing is made.
Chapter 12 Gravitation. Theories of Gravity Newton’s Einstein’s.

Chapter 12 Gravitation. Theories of Gravity Newton’s Einstein’s.
Chapter 4 Making Sense of the Universe: Understanding Motion, Energy, and Gravity.

Chapter 4 Making Sense of the Universe: Understanding Motion, Energy, and Gravity.
Do our planets move?.

Do our planets move?.
Gravitation and the Waltz of the Planets Chapter Four.

Gravitation and the Waltz of the Planets Chapter Four.
Astro: Chapter 3-5. The birth of modern astronomy and of modern science dates from the 144 years between Copernicus’ book (1543) and Newton’s book (1687).

Astro: Chapter 3-5. The birth of modern astronomy and of modern science dates from the 144 years between Copernicus’ book (1543) and Newton’s book (1687).

Similar presentations

Ads by Google