prof . geoff marcy
DESCRIPTION
Prof . Geoff Marcy. Jupiter and Europa. Saturn and Enceladus. Textbook : The Cosmic Perspective Bennett et al. (2010) Purchase Bookstore version to get kit for homework: MasteringAstronomy www.masteringastronomy.com www.masteringastronomy.com - PowerPoint PPT PresentationTRANSCRIPT
Prof. Geoff Marcy
Jupiter and EuropaSaturn and Enceladus
Textbook:The Cosmic Perspective
Bennett et al. (2010)
Purchase Bookstore version to get kit for homework:
MasteringAstronomywww.masteringastronomy.com www.masteringastronomy.com
See instructions at end of this lecture
Reading this week and next week: Chapters 1 and 2 “Our place in the Universe “ & “Discovering the Sky”
Homework: Due every Friday at 6pm Chapter 1 and Chapter 2 Assignments: due Friday Aug 31 at 6pm Tuesday Sept. 4 @ 6pm 5% off for each wrong try. 2% for a hint.
Course ID: THEPLANETSFALL2012
Description of Course• Tour of the Solar System, the Space Program and the physics,
chemistry, geology, and experiments and reasoning that explains it all.
• Observations and space missions.• Learn physical and chemical processes that formed and continue to shape the Solar System: Past, Present and Future.
Intended for Non-Science Majors (light on math)
Objectives of Course• Learn the process of careful thinking and reasoning• Work with others: group reasoning• Learn to estimate answers with a factor of 2
Basic Science:• Concepts of physical, chemical & biological sciences:• Force, Energy, Atoms, Nuclei, and DNA• How to calculate with very large and small numbers
12 Discussion Sections • 1 hour: All start this week. • Review, Clarification, Homework Help. Sign up on Telebears
101 Wed 9-10A, 265 McCone Hall: Ben Legg102 Wed 1-2P, 264 Evans Hall: Lea Hirsch103 Wed 2-3P, 264 Evans Hall: Tess McEnulty 104 Wed 3-4P, 241 Cory Hall: Tess McEnulty105 Th 2-3P, 264 Evans Hall: Lea Hirsch106 Tu 2-3P, 264 Evans Hall: Tess McEnulty107 Th 11-12P, 264 Evans Hall: Ryan Turner108 Tu 11-12P, 264 Evans Hall: Ryan Turner 109 Tu 12-1P, 264 Evans Hall: Drummond Fielding110 Th 12-1P, 264 Evans Hall: Lea Hirsch111 W 11-12P, 264 Evans Hall: Ben Legg112 Wed 12-1P, 264 Evans Hall: Drummond Fielding
Observing Project #1Two choices
B) Sketch where the Sun sets, relative to buildings. Wait 4-10 days. Sketch where the Sun sets again. Turn in both sketches, with time and date of observation. Write three sentences about any change in the position of sunset. Did it change? What direction? By how many degrees (approx.)? (The sun has an angular size of 0.5 degrees in diameter.)
Due in class, Thursday Sept. 61 page maximum; Handwritten is fine.
A) Chart the position and shape of the moon. Sketch where the moon is located relative to nearby buildings. Also sketch the shape of the moon. Mark which direction is south. Note the time and day on the sketch. Wait 2-5 days, and do it again. (Hint: the moon is up now from 7pm-midnight) Turn in both sketches, with time and date of observation. Write three to four sentences about any change you saw in the position or shape.
Course material on bSpace: http://bspace.berkeley.edu
• Syllabus
• Lecture slides
• Assignments: reading, homework, observing projects
• Course information
Last Time ::
The Solar SystemInner Solar System Outer Solar System
Our place in the Universe
Overview
13 billionLight Years
The Solar System:Sun and 8 Planets
Moons, Rings, Asteroids, Comets, and Dust
Milky Way Galaxy
You Are Here
200 Billion StarsPhoto taken from Earth
Our Sun moves relative to the other stars in the local Solar neighborhood.
Our Sun and the stars orbit around the center of the Milky Way Galaxy every 230 million years.
Our Milky Way Galaxy
Spiral Galaxies
Elliptical Galaxies
Irregular Galaxies
The Galactic Neighborhood
100,000 Light YearsThe ``Local Group”of Galaxies
The ``Local Group’’of Galaxies
And outward…10 Million Light Years
The Universe:All matter and
energy
> 100 Billion Galaxies
B
Astronomical Numbers Best to use Exponential Notation
Exponential notation is handy:
10N x 10M = 10(N+M)
103 = 1000 Thousand106 = 1,000,000 Million109 = 1,000,000,000 Billion1012 = 1,000,000,000,000 Trillion
Also: 10–3 = 1/1000 = 0.001
103 x 106 = 109 thousand million billion
Example:
B
How many stars in our visible Universe?
A. 1012 (1 million million)B. 1018 (1 billion billion)C. 1022
D. infinite
Interactive QuizB
A. 1012 (1 million million)B. 1018 (1 billion billion)C. 1022
D. infinite
Interactive Quiz
Number of Stars in a galaxy: ~100 billion = 1011
Number of galaxies in Universe: 100 billion = 1011
B
How many stars in our visible Universe?
There are 1011 stars in the galaxy. That used to be a huge number. But it's only a hundred billion. It's less than the national deficit! We used to call them astronomical numbers. Now we should call them economical numbers.
Richard Feynman
Federal B
In 2005, the National Debt was $7.6 Trillion
U.S. Population = 300 x 106
$7.6 x 1012 / 3 x 108 = $2.5 x 104
= $25,000$25,000 per person in 2005.
= $7.6 x 1012
Calculate Your Personal Debt:
Federal DebtTr
illio
ns o
f Dol
lars
Debt Total
02 03 04 05
B
Population of France: 65 millionLoss per person: $7x109 / 6.5x107 = $107
Transfer of 350 million Euros Population of Germany: 75 millionLoss per person: 4.66 Euros -- Cheap!!
B
B
Population of US: 300 millionCost per person: $7.87x1011 / 3x108 = $2623
B
B
All UC campus have 200,000 students.
How much will your annual fees increase? (A) $100 (B) $250(C) $1000(D) $2500
5×108 / 2×105=2.5×103=$2500
Distance, time and number :
Radius of our Galaxy:6,000,000,000,000,000,000 m =
Radius of a Hydrogen atom:0.00000000005 m =
Time for one vibration of an oxygen molecule, O2:0.00000000000001 s =
Age of the Universe:470,000,000,000,000,000 s =
Scientific notation: 6 x 1018 m
1 x 10–14 s
4.7 x 1017 s = 14 billion years
0.5 x 10–10 m
B
SI (Systeme International) Units
Base units: 1 meter (m) length ~ 3.3 ft1 kilogram (kg) mass ~ 2.2 lb
1 second (s) time
MKS System of units and measure
B
SI (Systeme International) Units
Base units: 1 meter (m) length 1 kilogram (kg) mass
1 second (s) timeMKS System of units and measure
Sometimes easier to derive other units from these:km, g, ms, µs, … km = 103 m kilo
g = 10-3 kg kilo
ms = 10-3 s milli
µs = 10-6 s micro
B
UNITS ARE IMPORTANT!!!
Mars Climate Orbiter: Launch: 11 Dec. 1998Orbit insertion:
23 Sep. 1999 Followed by: Loss of Communication WHY?
Failed to convert from English units (inches, feet, pounds) to Metric units (MKS) $Billion error
B
Light takes time to travel: 3 x 108 m/sec = 3 x 105 km/sec = 300,000 km/sec= 0.3 m/ns (1 ns = 10-9 s)
Light Year = 9 trillion km = 6 trillion milesLight HourLight Minutes are unit of Distance:
How far Light Travels in that interval of time1 light second = 3 x 105 km1 light ns = 30 cm ≈ 1 foot
B
How long does it take the sun’s light to reach the Earth?
Distance d = 1AU = 1.5x1011m
Speed of light v = 3x108 m/s
Time
€
t = dv
= 1.5 ×1011m3 ×108 m /s
= 0.5 ×103 s ≈ 8 min
B
Driving the Mars Exploration Rovers (MER)
• How long does it take to communicate with the rovers?
NASA/JPL/Cornell
B
How long does it take for radio waves (light) to reach
Mars?A. Less than 1 secondB. 1 minuteC. 10 minutesD. 1 hour
Interactive QuizB
How long does it take for radio waves (light) to reach Mars?
A. Less than 1 secondB. 1 minuteC. 10 minutesD. 1 hour
Interactive QuizB
Earth-Mars distance: between 55 and 400 million km.tmin = dmin/v = 5.5×107 km / (3×105 km/s ) =1.8×102s= 3 minutes
tmax = dmax/v = 4.0×108 km / (3×105 km/s ) =1.3×103s= 22 minutes
Powers of Ten“Cosmic Voyage”
The Movie
G
How to deal with very large & small numbers
•Develop a useful arithmeticExponential notation; convert between units
•Visualize using a sequence of images (movie)Use different sequences
•Visualize by way of a scale modelTry different models
G
A Scaled Model of the Solar System10 Billion x Smaller
Sun’s diameter: 14 x 1010 cm Reduce by 1010: 14 cm
Earth diameter: 13000 km 0.13 cm Jupiter’s diameter: 150,000 km 1.5 cmEarth’s distance from Sun: 1 “Astronomical Unit” = 1 “AU” = 1.5 x 108 km1 AU ?? cm
Ans: 1500 cm = 15 meters
14cm
1010 Scaled Down
“Sun”
A. 1.5 cmB. 15 cmC. 150 cmD. 1500 cm
How large is the Solar System?• Let’s view it to scale
– Say the Sun is the size of a large grapefruit, 14 cm (6 inches) - then:
G
Planet Dist (AU) Scaled Dist (m) Where?Mercury 0.4 6 6 rows backVenus 0.7 10 10 rowsEarth 1.0 15 15 rowsMars 1.5 22 22 rowsJupiter 5 75 3/4 football field awaySaturn 10 150 1.5 football field awayUranus 20 300 Sproul PlazaNeptune 30 450 Bancroft AvePluto 50 750 Durant AveOort Cloud 50,000 5 x 105 Oakland
.
100 m
Saturn oUranus
o
Neptune o
Jupiter o
You Are Here:Earth’s Orbit
G
.
How Far is the Nearest Star?Alpha Centauri d = 4 light years
= 4 x 1016 m
Scales to:4 x 106 m(~ 3000 mi)
G
Grapefruit-sizedSun in Berkeley
Nearest Grapefruit:
In Washington D.C.
A Universe in motion• Contrary to our perception, we are not “sitting still.”• We are moving with the Earth.
– and not just in one direction
The Earth rotates around it’s axis once every day!
G
The Earth orbits around the Sun once every year!
The Earth’s axis is tilted by 23.5º!
G
Looking back in time• Light, although fast, travels at a finite speed.• It takes:
– 8 minutes to reach us from the Sun– 8 years to reach us from Sirius (8 light-years away)– 1,500 years to reach us from the Orion Nebula
• The farther out we look into the Universe, the farther back in time we see!
B
What is the origin of the Universe?
Most of the atoms in our bodies were created in the core of a star!
(1) The two simplest atoms (H and He) were created during the Big Bang.
B
(2) More complex atoms were created in stars.
(3) When the star dies, chemical elements are expelled into space…. to form new stars and planets!
B
Balloon experiment
The Milky Way moves with the expansion of the Universe!
• Mostly all galaxies appear to be moving away from us.
• The farther away they are, the faster they are moving.– Just like raisins in a raisin
cake; they all move apart from each other as the dough (space itself) expands.
B
How old is the Universe?
• The Cosmic Calendar– if the entire age of
the Universe were one calendar year
– one month would be approximately 1 billion real years
B
• What does our solar system look like when viewed to scale?
• How far away are the stars?• How do human time scales compare to the age
of the Universe?
Key Issues So Far:
B
TODAY’S LECTURE
• Solar System Resides within our Milky Way Galaxy• Ranges of distances and time are huge.• Exponential notation and models are a real Help!• Distance Units:1 Astronomical Unit (AU) = Earth - Sun Distance = 93 million miles = 150 million km
B
The Universe in a Day
Look at the entire history of the Universe as though it took place in a single day. The present is at the stroke of midnight at the end of that day. Since it is about 13.5 billion years old, each hour will be ~0.5 billion years. A million years takes only a little over 7 seconds.
The Big Bang (a dense, hot explosion) and the formation of H and He all take place in the first nanosecond. The Universe becomes transparent in about 2 seconds. The first stars and galaxies appear after about 2am.
Our Galaxy forms at 4am. Generations of stars are born and die.
B
The Universe in a Day
The Solar System does not form until 3pm. The first life (bacterial) appears on the Earth by 4pm. Our atmosphere begins to have free oxygen at 7 or 8 pm, and this promotes the development of creatures which can move more aggressively and eat each other. Life does not begin to take on complex forms (multicellular) until 10:45pm. It moves onto land at 11:10. The dinosaurs appear at about 11:40, and become extinct at 11:52. Pre-human primates appear at around 14 seconds before midnight, and all of recorded history occurs in the last 70 milliseconds.
Looking to the future, we can expect the Universe of stars to go on for at least another millennium (using the same time compression factor). After that, there are other ages of the Universe (not dominated by stars), which grow colder and more bizarre, and take place on astronomical timescales…
B
What is the Earth’s velocity about the Sun?
Radius of Orbit (1 AU): 150 x 106 kmCircumference: 2 π x radiusDistance around the Sun that the Earth travels: 2 π x (1.5 x 108 km) = 9 x 1011 mEarth orbits the Sun once a year: 1 yr = 3 x 107 s Velocity = Distance/Time = 9 x 1011 m / 3 x 107 s = 3 x 104 m/s = 30 km/s
110,000 km/hr or 75,000 miles/hr!
B