The celestial sphere, the coordinates system, seasons,

phases of the moon and eclipses

Chapters 2 and S1

The celestial sphere and the coordinates system

Chapter S1

How to find our way in the sky?

Let’s start with the Earth Coordinate System

Latitude: N-S of the equator, Longitude: E-W along equator

North celestial poleNorth

North Celestial Pole

South Celestial Pole

Cele

stia

l

Equ

ato

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From Earth to Space

The Celestial Sphere • The Celestial Sphere: An

imaginary sphere of infinite radius centered on Earth.

• The extensions of the Earth North and South Pole define the North and South celestial poles.

• The projection of Earth equator defines the Celestial equator.

• Celestial Sphere can then be divided into a grid, just like the Earth is divided into a grid of latitude and longitude.

The Celestial Sphere: Motions

• Stars, planets and Sun are “attached” to this imaginary sphere.

• As the Earth rotates, the celestial sphere (with the stars attached to it) appears to rotate in the opposite direction.

• To explain the daily motions of the sky you can imagine the sphere rotating once in 23 hours 56 minutes (using a star as reference).

orth celestial poleNorth

North Celestial Pole

South Celestial Pole

Cel

esti

al E

quat

or

Celestial Sphere: Measuring Angles

Longitude (E – W along Equator) Right Ascension (RA)

Latitude (N – S of Equator) Declination (Dec)

The celestial coordinate system

RA, measured in hr, min, sec (0 to 24 hours)

1 hour = 60 min

1 min = 60 sec

(1 hour = 15 degrees of Earth rotation)

Dec, measured in degrees, arcmin,

arcsec (0 celestial equator, +90 north hemisphere, -90

south hemisphere)

1 degree = 60 arcminutes

1 arcminute = 60 arcseconds

The use of RA and Dec to locate objects in the celestial sphere

There are two coordinates that allow to locate an object in the sky: Azimuth and

Altitude. Their value depends in the location of the observer

Azimuth: Use as reference the north direction (close to Polaris) and the range of

values is from 0 to 360 degrees. 0 degrees is N, 90 degrees E, 180 is S and 270 is W.

Altitude: Use as reference the horizon. The range of values is from 0 degrees (horizon)

to 90 degrees (zenith)

Locating the star Vega and the Sun in the celestial sphere

Ecliptic: Apparent annual path of the Sun in the celestial sphere

The Sun crosses the celestial equator on March 21 (Spring equinox) and on September

21 (Fall equinox)

The Sun reaches a declination of +23.5 degrees on June 21 (Summer solstice)

The Sun reaches a declination of – 23.5 degrees on December 21 (Winter solstice)

Locating Polaris: RA: 0h 31m 49.084s Dec: +89d 15’ 50.79”

Using two stars in the Big Dipper (Ursa Major) constellation called the Pointers”

Locating Polaris (North star) in the celestial sphere

Angular Size Angular size of an object depends on two parameters

The physical size of the object

The distance to the object Angular size is measured in units of angle (degrees, arcmin and

arcsec)

Angular size = Physical Size

Distance

More specifically (See page 30, Mathematical Insight 2.1)

Angular Size = Physical size

360 degrees 2 x Pi x distance

Angular size = Physical size x 360 degrees/ (2 x Pi x distance)

Example: Physical size of the Moon

Angular size = 0.5 degrees

Distance = 380,000 km

Angular Units Estimating angular sizes

Practical Measurements

• The Moon and the Sun, coincidentally, have nearly the same angular size,

about 0.5 degrees.

• The Moon is about 380,000 km away but only 3,300 km diameter

• The Sun is 150,000,000 km away and about 1,400,000 km diameter

Celestial Sphere and the Observer

Horizon: flat plane where observer

stands

Zenith: the point directly above an

observer

Nadir: the point opposite to the zenith

An observer can see only half of the

celestial sphere from any location on

Earth

Apparent Motion of Stars

Earth rotates from W-E celestial sphere

seems to rotate E-W.

Depending on our location, we’ll see some

stars rising on the east and setting on the

west.

Depending on our location, some stars

never set. Those stars are called

circumpolar stars.

For someone standing at the equator, all stars rise and set.

For someone standing at the poles, all stars are circumpolar.

Observer located at the equator

Meridian: The circle that passes through the zenith and the

two celestial poles

Orientation of the sky relative to

the celestial sphere, for an

observer at the Earth’s equator

Rotating the diagram make it

easier to visualize the local sky

at the equator

Observer located at the north pole

Observer located at latitude 40 degrees N

The latitude is the angle from the zenith to

the Earth’s equator. “Up” point to the circle

on the celestial sphere with declination +40

degrees

Notice that the south pole is below the

horizon and invisible for an observer located

at 40 degrees N latitude

Rotating the diagram so the zenith is

up make it easier to visualize the

local sky.

The blue scale along the meridian

shows altitudes and directions in the

local sky.

Notice that the altitude of the north

celestial pole is 40 degrees which

correspond to the latitude of the

place

How can we estimate our latitude? Remember that the angle between the horizon and the object is called altitude The altitude of the north celestial pole, give us our latitude. Polaris is close to the north celestial pole. By estimating the altitude of Polaris we can estimate the latitude of the observer.

The path of the sun on the equinoxes and solstices at latitude 40 degrees north

(Latitude of Gainesville is about +29.65 degrees)

The path of the Sun on the equinoxes and solstices at latitude 0 degrees ( Observer at

equator)

Apparent Daily Motion of the Sun

The Sun:

Rises in the east

Sets in the west

Travels on an arc

across the sky

Solar day: 24 hours

Solar and Sidereal Days Solar day (relative to the Sun): It is the average time between two consecutive passes of the Sun through the meridian. It is on average 24 hours Sidereal day (Relative to stars): It is the time between two consecutive passes of a star through the meridian. It is on average 23 hours, 56 minutes, 4.1 seconds

Why is the Solar Day Longer?

The reason: Earth rotation on its axis + orbital motion around the Sun

The Earth has to travel an additional angle to have the Sun at the same position each day. 1 orbit = 1 full circle = 360 degrees Earth takes 1 year = 365 days to complete 1 orbit.

additional angle Earth has to rotate:

360 degrees/365 days = 0.986 degrees/day

How long does it take the Earth to cover ~ 1 degree? It takes 1 day to rotate 360 degrees on its axis 1 day = 24 hrs = 1440 minutes 1440 minutes/360 degrees = 4 min/degree

Solar day is 4 minutes longer

Apparent Annual Motion of the Sun

Because of Earth orbital motion, the Sun position relative to the stars is different every night.

Apparent Annual Motion of the Sun

The Sun apparent path relative to the stars is called the ECLIPTIC The Sun moves eastward relative to the stars on celestial sphere It moves ~ 1 degree per day. Why?

The 12 constellations through which the Sun moves are the constellations of the

ZODIAC What is a constellation? A constellation is a region of the sky limited by lines of RA and Dec. The ancients attached a figure to a constellation. The IAU defined 88 constellations that cover the celestial sphere

An example of a

constellation:

Orion the Hunter

The stars form the figure of

a Hunter but the stars are

located a different distances.

The stars in a constellation

are not physical related to

each other

The Zodiac constellations (All the Zodiac constellations lie along the ecliptic)

ZODIAC CONSTELLATIONS

• There are actually 13 (NOT 12) zodiac constellations

(Ophiuchus)

• Sky has changed since Babylonians came up with the

signs of the zodiac (Earth precession later)

• For example: August 4th is not Leo anymore, but

Cancer

• The Sun spends different times in different

constellations (they are not all the same size!)

• Scorpius only 7 days

• Virgo 47 days

The seasons Chapter 2

Section 2.2

Why do we have seasons?

TRUE OR FALSE?

We have seasons because the Earth is closer

to the Sun in summer and farther from the

Sun in winter.

Question

TRUE OR FALSE?

We have season because the Earth is closer to

the Sun in summer and farther from the Sun

in winter.

Question

Hint: When it is summer in America,

it is winter in Australia.

TRUE OR FALSE!

Earth is closer to the Sun in summer and farther

from the Sun in winter. Actually it is the opposite: Earth is closer to the Sun

during the north hemisphere winter and farter during the

north hemisphere summer (see another slide later)

• Seasons are opposite in the N and S hemispheres, so

distance cannot be the reason.

• The real reason for seasons involves Earth’s axis tilt.

What causes the seasons?

Seasons depend on how Earth’s axis affects the directness of sunlight.

Earth’s rotation axis is tilted by 23.5 degrees compared to the

direction perpendicular to the Earth’s orbital plane

23.5

The sun crosses the meridian higher during the summer. In the winter the sun crosses the meridian lower in the sky.

Seasons

Summary: The Real Reason for Seasons

• Earth’s axis points in the same direction (to Polaris) all year round, so its orientation relative to the Sun changes as Earth orbits the Sun.

• Summer occurs in an hemisphere when sunlight hits it more directly; winter occurs when the sunlight is less direct.

• AXIS TILT is the key to the seasons; without it, we would not have seasons on Earth.

Why doesn’t distance matter?

•Is there a change in

distance from the Sun

during the year?

• Yes, but the

variation of Earth–

Sun distance is

small—about 3%; this

small variation is

overwhelmed by the

effects of axis tilt.

How do we mark the progression of the

seasons?

•We define four special points:

summer (June) solstice

winter (December) solstice

spring (March) equinox

fall (September) equinox

We can recognize solstices and

equinoxes by Sun’s path across sky:

Summer (June) solstice:

highest path; rise and set at

most extreme north of due

east

Winter (December) solstice:

lowest path; rise and set at

most extreme south of due

east

Equinoxes: Sun rises

precisely due east and sets

precisely due west.

How does the orientation of Earth’s axis

change with time?

•The effect is called precession. •Although the axis seems fixed on human

time scales, it actually precesses over about

26,000 years.

Polaris won’t always be the North

Star.

Positions of equinoxes shift around

orbit; e.g., spring equinox, once in Aries,

is now in Pisces!

Long-Term Changes: Climatic Changes

In about 13,000 years the Earth North Pole will be closer to

the Sun in December. The Earth is at its shortest distance

from the Sun in January. How will this affect our seasons?

Moon phases and eclipses Chapter 2. section 2.3

Motion of the Moon

• The Moon rises in the east and sets in

the west moving across the sky in an

arc

• The Moon moves slowly eastward

against the stars (half a degree per

hour)

• The Moon returns to the same position

among the stars every 27.3 days (its

orbital period or sidereal period)

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Why do we see phases of the Moon?

• Lunar phases are a

consequence of the

Moon’s 27.3-day

orbit around Earth.

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Differences in angular diameter of the moon when it is at

apogee (farthest from Earth) and perigee (closest from Earth )

This is caused by the elliptical orbit of the moon.

Phases of the Moon

Why do we see phases?

• The Moon emits no light of its own shines by reflecting light

from the Sun

• The half of the Moon facing the Sun is always lit

• We see a combination of lit and dark areas

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Phases of the Moon • Half of Moon is illuminated

by Sun and half is dark.

• We see a changing

combination of the bright and

dark faces as the Moon orbits

the Earth

• Depending on the angle

between the Moon and the

Sun as seen from Earth, is the

combination of bright and

dark areas that we see.

• Examples: At new moon, the

moon rises at sunrise and sets

at sunset

At full moon, the moon rises

at sunset and set at sunrise

Phases of the Moon • Phases change in a regular sequence over a 29.5 day period (synodic

period). It is the time required for a complete cycle of lunar phases

Question

• If the Sun sets at 6pm,

when does a full Moon

rise?

The time at which the moon rises depends on its phase (phase of the moon depends on the relative positions of the Sun, Moon & Earth)

• At 6 pm. The side of the Moon we see is facing the Sun, so when the Sun is setting, the Moon is rising.

Another way of looking at it:

• The Sun and the Moon are ~ 180 degrees apart. The moon and Sun rising times are 12 hrs apart. Sun rose at 6 am Moon at 6pm.

Another question

• If the Sun sets at 6pm,

when does a 1st quarter

Moon rise?

• The Moon and Sun rising times are now 6

hrs apart (~90 degrees).

If the Sun rose at 6 am,

the Moon will rise 6

hours later (noon).

• How about New Moon and 3rd quarter Moon?

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Phases of the Moon: 29.5-day cycle

Waxing • Moon visible in afternoon/evening

• Gets “fuller” and rises later each day

Waning • Moon visible in late night/early morning

• Gets “less full” and sets later each day

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Question

A. first quarter

B. waxing gibbous

C. third quarter

D. half moon

It’s 9 a.m. You look up in the sky and see a

moon with half its face bright and half dark.

What phase is it?

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A. first quarter

B. waxing gibbous

C. third quarter

D. half moon

It’s 9 a.m. You look up in the sky and see a

moon with half its face bright and half dark.

What phase is it?

Question

• Why do we always see the same face of the moon?

• The Moon and Earth are tidally locked Moon keeps the same

side towards Earth at all times.

A consequence of this is that :

Moon rotation period = Moon orbital period

As a person walks around you, in order for you to always see her face She must be slowly spinning around (“rotating on her axis”)

Phases of the Moon

Lunar and Solar Eclipses

Chapter 2

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What causes eclipses? • The Earth and the Moon cast shadows.

• When either passes through the other’s shadow, we have an

eclipse.

• Umbra: the dark central region of the shadow

• Penumbra: The lighter, outlying region of the shadow

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Lunar and solar eclipses

• A lunar eclipse occurs when the Earth lies

directly between the Sun and the Moon, so

that the Earth’s shadow falls on the Moon

• A solar eclipse occurs when the Moon lies

directly between the Sun and the Earth so

that the Moon’s shadow falls on Earth

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Lunar and solar eclipses

New Moon, a condition for a

← solar eclipse

Full Moon, a condition for

lunar eclipse →

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Lunar Eclipse

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When can lunar eclipses occur?

• Lunar eclipses can occur

only at full moon.

• Lunar eclipses can be

Total: The moon passes

through Earth’s umbra

Partial: If the alignment is

not perfect, only part of

the full Moon passes

through the umbra

Penumbral: The Moon

passes through the Earth’s

penumbra

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Solar Eclipse

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When can solar eclipses occur?

• Solar eclipses can occur only at new moon.

• Solar eclipses can be partial, total, or annular.

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Types of solar eclipses • Total eclipse: The Moon’s umbra touches a small area of Earth’s

surface, no more than 270 km diameter. Because the Earth and the Moon

are moving, this area drift across the Earth’s surface and may cover a

total of 7,000 km. An observer located inside this strip will see a total

solar eclipse.

• Partial solar eclipse: If the observer is located in the penumbral part of

the shadow, only part of the Sun will be covered and the observer will

see a partial solar eclipse

• Annular solar eclipse: If the Moon is relatively far from Earth in its orbit

(Or the Earth closer to the Sun or a combination of both effects), the

Moon disk will not completely cover the disk of the Sun. It leaves a ring

around the Sun. In that case, the umbra of the Moon’s shadow will not

touch the surface of Earth. The observer will see a bright ring (the Sun)

around the Moon.

• The Earth and the Moon orbits are elliptical. Because of that, the

distances between the two bodies can varies.

• The Sun-Earth distance can change from 147 x10^6 to 152 x 10^6 km

• The Earth-Moon distance can change from 357,000 to 406,000 km

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Types of solar eclipses

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Why don’t we have an eclipse at every new

and full moon? – The Moon’s orbit is tilted 5° to ecliptic plane.

– So we have about two eclipse seasons each year, with a lunar

eclipse at new moon and solar eclipse at full moon.

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Summary: Two conditions must be met

to have an eclipse:

1. It must be full moon (for a lunar eclipse) or new moon (for a solar eclipse).

AND

2. The Moon must be at or near one of the two points in its orbit where it crosses the ecliptic plane (its nodes).

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Predicting Eclipses • Eclipses recur with the 18-year, 11 1/3-day saros cycle, but

type (e.g., partial, total) and location may vary.

• When will be the next total solar eclipse seen from the continental US?

• August 21, 2017 (about 4 years and 7 month from now)

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What have we learned?

• Why do we see phases of the Moon?

– Half the Moon is lit by the Sun; half is in shadow, and

its appearance to us is determined by the relative

positions of Sun, Moon and Earth.

• What causes eclipses?

– Lunar eclipse: Earth’s shadow on the Moon

– Solar eclipse: Moon’s shadow on Earth

– Tilt of Moon’s orbit means eclipses do not occur for

every new or full Moon. They occur during two

periods each year.