P3 1.7 Planetary orbits

P3 1.7 Planetary orbits • Learning objectives • Be able to explain that; • The force of gravity provides the centripetal force • that keeps planets and satellites moving in their orbits. • To stay at a particular distance, a planet must move • at a particular speed around the sun. • 3. The larger the orbit the slower the speed and the longer it takes. If the Earth’s orbit were more elliptical, how would we be affected?

P3 1.7 Planetary orbits Speed = distR time T Radius Time for each orbit (AU) (years) Mercury 0.39 0.24 Important: The orbits on this slide are not shown to scale! What does this data show?

P3 1.7 Planetary orbits sun To stay at a particular distance, a planet must move at a particular speed around the sun. Velocity of planet Earth R = 1 AU T = 1 Yr Force of gravity on planet

P3 1.7 Planetary orbits sun To stay at a particular distance, a planet must move at a particular speed around the sun. Velocity of planet Earth R = 1 AU T = 1 Yr Force of gravity on planet If its speed is too slow, it will spiral into the sun If its speed is too high, it will move away from the sun

P3 1.7 Planetary orbits sun To stay at a particular distance, a planet must move at a particular speed around the sun. Velocity of planet Earth R = 1 AU T = 1 Yr Force of gravity on planet speed = dist (2πR) time (T) speed = 2 π1 1 AU/yr If its speed is too slow, it will spiral into the sun If its speed is too high, it will move away from the sun

P3 1.7 Planetary orbits sun The larger the orbit the slower the speed and the longer it takes Velocity of planet Saturn R = 9.53 AU T = 29.5 yr Force of gravity on planet

P3 1.7 Planetary orbits sun The larger the orbit the slower the speed and the longer it takes Velocity of planet Saturn R = 9.53 AU T = 29.5 yr Force of gravity on planet The speed is less because gravity is weaker when further away.

P3 1.7 Planetary orbits sun The larger the orbit the slower the speed and the longer it takes Orbit time is longer because the planet has further to go and it is moving slower. Velocity of planet Saturn R = 9.53 AU T = 29.5 yr Force of gravity on planet

P3 1.7 Planetary orbits sun The larger the orbit the slower the speed and the longer it takes Orbit time is longer because the planet has further to go and it is moving slower. Velocity of planet Saturn R = 9.53 AU T = 29.5 yr Force of gravity on planet speed = dist time

P3 1.7 Planetary orbits sun The larger the orbit the slower the speed and the longer it takes Orbit time is longer because the planet has further to go and it is moving slower. Velocity of planet Saturn R = 9.53 AU T = 29.5 yr Force of gravity on planet speed = dist time speed = 2 π 9.59 29.5 speed = 0.65 π AU/yr

P3 1.7 Planetary orbits Elliptical orbits: The squashed circle orbit has two ‘foci’ F1 & F2 Distances OF1 + OF2 = constant The sun is at one focus of the ellipse

P3 1.7 Planetary orbits Q

P3 1.7 Planetary orbits • Learning objectives • Be able to explain that; • The force of gravity provides the centripetal force • that keeps planets and satellites moving in their orbits. • To stay at a particular distance, a planet must move • at a particular speed around the sun. • 3. The larger the orbit the slower the speed and the longer it takes.

P3 1.7 Planetary orbits

P3 1.7 Planetary orbits

Presentation Transcript

Orbits

On the Origin of Orbits in Extrasolar Planetary Systems

Planetary Orbits

Orbits

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Stable planetary orbits in multiple planetary systems

Planetary Orbits: Kepler’s Laws

ORBITS

1 - Planetary Moon Science Orbits

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Orbits

Newton’s Universal Law of Gravitation and planetary orbits

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Orbits

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Planetary Orbits

Newton’s Laws of Motion and Planetary Orbits

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Goal to understand how Planetary Orbits work.