PTYS 214 Spring Announcements. Midterm 3 next Thursday! Midterms 4 and 5 more spread out
|
|
- Pierce Owens
- 5 years ago
- Views:
Transcription
1 PTYS 214 Spring 2018 Announcements Midterm 3 next Thursday! Midterms 4 and 5 more spread out 1
2 Previously Geothermal Energy Radioactive Decay Accretional Energy Heat of Differentiation Why Water? Phase Diagrams 2
3 Major advantages of water 1. Ingredients (H and O) are abundant in the universe 2. A wide (and high) range of temperatures over which it remains liquid (major advantage) 3. Water ice floats, whereas the other substances sink when frozen 4. Water is a polar molecule (hydrogen bond!) Water can dissolve some substances (salts) but cannot dissolve membranes 3
4 Phase Diagrams Temperature and Pressure specify the phase of any substance Conditions (1) solid phase Conditions (2) liquid phase Conditions (3) gas phase We can make a liquid boil by either: a) increasing temperature (at constant pressure) or b) decreasing pressure (at constant temperature) 4
5 Habitable Zone A circumstellar habitable zone (HZ) is defined as a region around any star where a planetary body can maintain liquid water on its surface Under the present Earth s atmospheric pressure (1 atm ~ 105 Pa) water is stable if the temperature is 273K < T < 373K On a planetary surface temperature (T) is key assuming the planet has some atmosphere! 5
6 How far from a star should an Earth-like planet be to maintain liquid water on its surface? Solar energy from hydrogen fusion Electromagnetic Radiation (waves) Temperature? 6
7 How do we determine a Planet s surface temperature? We must examine the Planet s Planetary Energy Budget: absorbed energy = emitted energy 7
8 Incoming Energy How much solar energy gets to the Earth? Total amount of energy per unit time (i.e., power) reaching the Earth is given by the amount of radiative flux hitting (e.g., W/m2) an area corresponding to the disk of the Earth: πre2 W/m2 m2 W Pin =S0 ( 2 πr E ) re Ein πre2 8
9 How much solar energy is absorbed by the Earth s surface? Some energy is reflected away 9
10 Albedo Fraction of incident sunlight that is reflected Range: 0 1 (no reflection) (100% reflection) Typical Surface Albedos: Sand Forest Green grass 0.25 Ocean Fresh Snow Average Earth s albedo: A =
11 Absorbed Power The amount of absorbed power is given by the amount of incident power minus the amount of reflected power: Pabs = Pin Prefl or Pabs = Pin APin = Pin(1-A) 11
12 How do we determine the Energy emitted by the Earth? 12
13 How do we determine the Energy emitted by the Earth? We can use Stefan-Boltzmann law to calculate the flux radiating from the Earth F=σT 4 F = flux of energy (W/m2) T = temperature (K) = 5.67 x 10-8 W/m2K4 (constant) 13
14 Total energy emitted by the Earth Start from Stefan-Boltzmann s law: F = T4 [W/m2] This is a flux, power per unit area, not total power We must multiply the flux by an area (area of the Earth s surface) Pemm = σt4 aearth 14
15 Energy Balance Over time, the power absorbed by the Earth should be equal to the power emitted (Pout) by the Earth Otherwise, the Earth s temperature would steadily rise (or fall) Pemm Pabs 15
16 Energy Balance 2 Pabs =(1 A )S 0 πr E Pemm =σt 4 ( 4 πr 2E ) Pemm Pabs re 16
17 Energy Balance: Pabs = Pemm 2 4 ( 1-A ) S 0 πr E =σt ( (1-A )S 0 =4σT 4 2 4πr E ) Pemm Pabs 17
18 Energy Balance: Pabs = Pout ( 1-A ) S 0 T = 4σ 4 Pout Pin 18
19 Earth Surface Temperature (1 A )S 0 4 T em = 4σ ==> Emission Temperature So = 1370 W/m2 A = 0.3 = 5.67 x 10-8 W/m2/K4 4 T em = 2 (1-0.3) 1370W/m W/m / K 19
20 Earth s Average Surface Temperature T em = K 4 9 T em = K We expect an average surface temperature (emission temperature) of: T em =255K ~ -18 C or 0 F 20
21 Is the Earth s surface at 255K? 21
22 Earth Surface Temperature The average observed temperature at the Earth s surface is: Tobs = 288K (or +15oC, +59oF) Difference between observed and expected temperatures: T = Tobs Tem = 288K 255K T = + 33K = 33 C = 59.4 F What did we do wrong? 22
23 We must consider the interaction of atmospheric gases with the incoming and outgoing radiation Greenhouse Effect 23
24 How does a greenhouse work? Reduces heat loss primarily by inhibiting the upward air motion (convection) Solar energy is used more effectively: Same solar input higher temperatures 24
25 Atmospheric Greenhouse Effect Thermal radiation (infrared) from the surface is absorbed and re-emitted by some gases in the atmosphere Some of the re-emitted radiation radiates back to the planet 25
26 Composition of the Atmosphere Air is composed of a mixture of gases: Gas Concentration (%) N2 O2 Ar H2O CO2 greenhouse gases CH4 N2O O % 21 Non-greenhouse gases 0.9 variable (=370 ppm) (stratosphere -- surface) 26
27 Molecules with an uneven distribution of electrons are especially good absorbers and emitters These molecules are said to be dipoles (+) Water Electron-poor region: Partial positive charge H O (-) Electron-rich region: Partial negative charge H (+) oxygen is more electronegative than hydrogen 27
28 Greenhouse Gases O C O carbon dioxide O H water H H H C H -O O+ ozone O H methane 28
29 Non-greenhouse Gases N N nitrogen O O oxygen 29
30 Non-greenhouse Gases N N nitrogen O O oxygen Electron cloud is distributed equally over the atoms in the molecule (Technically speaking, greenhouse gases have (or can be made to have) a dipole moment whereas N2 and O2 don t/can't) 30
31 Greenhouse gases and radiation Molecules of greenhouse gases absorb energy from infrared radiation The energy increases the movement of the molecules, including vibration and rotation The molecules gain kinetic energy that may then be transmitted to other molecules such as oxygen and nitrogen and cause a general heating of the atmosphere 31
32 CO2 Vibration modes Which are IR active? 32
33 CO2 Vibration modes 15 μm 4.2 μm Which are IR active? 33
34 H2O Vibration Absorption wavelengths: 2.7 m 6.2 m 2.6 m 34
35 Solar Spectrum at Earth s Surface Greenhouse gases absorb IR radiation at specific wavelengths CO2 35
36 Homework See web page for suggested reading Homework #10 available shortly on the web site 36
PTYS 214 Fall Announcements
PTYS 214 Fall 2017 Announcements Midterm 3 next Thursday! Midterms 4 and 5 more spread out Extra credit: attend Lynn Carter's evening lecture 10/4, 7:00 pm takes notes and get them signed / stamped! 1
More informationPTYS 214 Spring Announcements. Midterm 3 next Thursday!
PTYS 214 Spring 2018 Announcements Midterm 3 next Thursday! 1 Previously Habitable Zone Energy Balance Emission Temperature Greenhouse Effect Vibration/rotation bands 2 Recap: Greenhouse gases In order
More informationEarth: the Goldilocks Planet
Earth: the Goldilocks Planet Not too hot (460 C) Fig. 3-1 Not too cold (-55 C) Wave properties: Wavelength, velocity, and? Fig. 3-2 Reviewing units: Wavelength = distance (meters or nanometers, etc.) Velocity
More informationEnergy, Temperature, & Heat. Energy, Temperature, & Heat. Temperature Scales 1/17/11
Energy, Temperature, & Heat Energy is the ability to do work (push, pull, lift) on some form of matter. Chapter 2 Potential energy is the potential for work (mass x gravity x height) Kinetic energy is
More informationEnergy and Radiation. GEOG/ENST 2331 Lecture 3 Ahrens: Chapter 2
Energy and Radiation GEOG/ENST 2331 Lecture 3 Ahrens: Chapter 2 Last lecture: the Atmosphere! Mainly nitrogen (78%) and oxygen (21%)! T, P and ρ! The Ideal Gas Law! Temperature profiles Lecture outline!
More information1. Weather and climate.
Lecture 31. Introduction to climate and climate change. Part 1. Objectives: 1. Weather and climate. 2. Earth s radiation budget. 3. Clouds and radiation field. Readings: Turco: p. 320-349; Brimblecombe:
More informationESS15 Lecture 7. The Greenhouse effect.
ESS15 Lecture 7 The Greenhouse effect. Housekeeping. First midterm is in one week. Open book, open notes. Covers material through end of Friday s lecture Including today s lecture (greenhouse effect) And
More informationLecture 4: Global Energy Balance
Lecture : Global Energy Balance S/ * (1-A) T A T S T A Blackbody Radiation Layer Model Greenhouse Effect Global Energy Balance terrestrial radiation cooling Solar radiation warming Global Temperature atmosphere
More informationLecture 4: Global Energy Balance. Global Energy Balance. Solar Flux and Flux Density. Blackbody Radiation Layer Model.
Lecture : Global Energy Balance Global Energy Balance S/ * (1-A) terrestrial radiation cooling Solar radiation warming T S Global Temperature Blackbody Radiation ocean land Layer Model energy, water, and
More information2. Energy Balance. 1. All substances radiate unless their temperature is at absolute zero (0 K). Gases radiate at specific frequencies, while solids
I. Radiation 2. Energy Balance 1. All substances radiate unless their temperature is at absolute zero (0 K). Gases radiate at specific frequencies, while solids radiate at many Click frequencies, to edit
More informationLecture 3: Global Energy Cycle
Lecture 3: Global Energy Cycle Planetary energy balance Greenhouse Effect Vertical energy balance Latitudinal energy balance Seasonal and diurnal cycles Solar Flux and Flux Density Solar Luminosity (L)
More informationWednesday, September 8, 2010 Infrared Trapping the Greenhouse Effect
Wednesday, September 8, 2010 Infrared Trapping the Greenhouse Effect Goals to look at the properties of materials that make them interact with thermal (i.e., infrared, or IR) radiation (absorbing and reemitting
More informationMonday 9 September, :30-11:30 Class#03
Monday 9 September, 2013 10:30-11:30 Class#03 Topics for the hour Solar zenith angle & relationship to albedo Blackbody spectra Stefan-Boltzman Relationship Layer model of atmosphere OLR, Outgoing longwave
More informationThursday, November 1st.
Thursday, November 1st. Announcements. Homework 7 - due Tuesday, Nov. 6 Homework 8 - paper 2 topics, questions and sources due Tuesday, Nov. 13 Midterm Paper 2 - due Tuesday, Nov. 20 I will hand out a
More informationTemperature Scales
TEMPERATURE is a measure of the internal heat energy of a substance. The molecules that make up all matter are in constant motion. By internal heat energy, we really mean this random molecular motion.
More informationRadiative Balance and the Faint Young Sun Paradox
Radiative Balance and the Faint Young Sun Paradox Solar Irradiance Inverse Square Law Faint Young Sun Early Atmosphere Earth, Water, and Life 1. Water - essential medium for life. 2. Water - essential
More informationComposition, Structure and Energy. ATS 351 Lecture 2 September 14, 2009
Composition, Structure and Energy ATS 351 Lecture 2 September 14, 2009 Composition of the Atmosphere Atmospheric Properties Temperature Pressure Wind Moisture (i.e. water vapor) Density Temperature A measure
More informationAtmospheric "greenhouse effect" - How the presence of an atmosphere makes Earth's surface warmer
Atmospheric "greenhouse effect" - How the presence of an atmosphere makes Earth's surface warmer Some relevant parameters and facts (see previous slide sets) (So/) 32 W m -2 is the average incoming solar
More informationMASSACHUSETTS INSTITUTE OF TECHNOLOGY Department of Physics Problem Solving 10: The Greenhouse Effect. Section Table and Group
MASSACHUSETTS INSTITUTE OF TECHNOLOGY Department of Physics 8.02 Problem Solving 10: The Greenhouse Effect Section Table and Group Names Hand in one copy per group at the end of the Friday Problem Solving
More informationMon April 17 Announcements: bring calculator to class from now on (in-class activities, tests) HW#2 due Thursday
Mon April 17 Announcements: bring calculator to class from now on (in-class activities, tests) HW#2 due Thursday Today: Fundamentals of Planetary Energy Balance Incoming = Outgoing (at equilibrium) Incoming
More informationElectromagnetic Radiation. Radiation and the Planetary Energy Balance. Electromagnetic Spectrum of the Sun
Radiation and the Planetary Energy Balance Electromagnetic Radiation Solar radiation warms the planet Conversion of solar energy at the surface Absorption and emission by the atmosphere The greenhouse
More informationTake away concepts. What is Energy? Solar Radiation Emission and Absorption. Energy: The ability to do work
Solar Radiation Emission and Absorption Take away concepts 1. 2. 3. 4. 5. 6. Conservation of energy. Black body radiation principle Emission wavelength and temperature (Wien s Law). Radiation vs. distance
More information8.5 GREENHOUSE EFFECT 8.6 GLOBAL WARMING HW/Study Packet
8.5 GREENHOUSE EFFECT 8.6 GLOBAL WARMING HW/Study Packet Required: READ Tsokos, pp 434-450 Hamper pp 294-307 SL/HL Supplemental: none REMEMBER TO. Work through all of the example problems in the texts
More informationLecture 2-07: The greenhouse, global heat engine.
Lecture 2-07: The greenhouse, global heat engine http://en.wikipedia.org/ the sun s ultraviolet (left) and infrared radiation imagers.gsfc.nasa.gov/ems/uv.html www.odysseymagazine.com/images SOLAR FLARES
More informationChapter 02 Energy and Matter in the Atmosphere
Chapter 02 Energy and Matter in the Atmosphere Multiple Choice Questions 1. The most common gas in the atmosphere is. A. oxygen (O2). B. carbon dioxide (CO2). C. nitrogen (N2). D. methane (CH4). Section:
More informationThe Greenhouse Effect. Lan Ma
The Greenhouse Effect Lan Ma What to cover today: How do we calculate the Earth s surface temperature? What makes a gas a greenhouse gas and how does the increasing greenhouse gases in the atmosphere cause
More informationLecture 2: Global Energy Cycle
Lecture 2: Global Energy Cycle Planetary energy balance Greenhouse Effect Vertical energy balance Solar Flux and Flux Density Solar Luminosity (L) the constant flux of energy put out by the sun L = 3.9
More informationATM S 111: Global Warming Solar Radiation. Jennifer Fletcher Day 2: June
ATM S 111: Global Warming Solar Radiation Jennifer Fletcher Day 2: June 22 2010 Yesterday We Asked What factors influence climate at a given place? Sunshine (and latitude) Topography/mountains Proximity
More informationMAPH & & & & & & 02 LECTURE
Climate & Earth System Science Introduction to Meteorology & Climate MAPH 10050 Peter Lynch Peter Lynch Meteorology & Climate Centre School of Mathematical Sciences University College Dublin Meteorology
More information9/5/16. Section 3-4: Radiation, Energy, Climate. Common Forms of Energy Transfer in Climate. Electromagnetic radiation.
Section 3-4: Radiation, Energy, Climate Learning outcomes types of energy important to the climate system Earth energy balance (top of atm., surface) greenhouse effect natural and anthropogenic forcings
More informationRadiative Equilibrium Models. Solar radiation reflected by the earth back to space. Solar radiation absorbed by the earth
I. The arth as a Whole (Atmosphere and Surface Treated as One Layer) Longwave infrared (LWIR) radiation earth to space by the earth back to space Incoming solar radiation Top of the Solar radiation absorbed
More information- matter-energy interactions. - global radiation balance. Further Reading: Chapter 04 of the text book. Outline. - shortwave radiation balance
(1 of 12) Further Reading: Chapter 04 of the text book Outline - matter-energy interactions - shortwave radiation balance - longwave radiation balance - global radiation balance (2 of 12) Previously, we
More informationLecture 2 Global and Zonal-mean Energy Balance
Lecture 2 Global and Zonal-mean Energy Balance A zero-dimensional view of the planet s energy balance RADIATIVE BALANCE Roughly 70% of the radiation received from the Sun at the top of Earth s atmosphere
More informationEnergy: Warming the earth and Atmosphere. air temperature. Overview of the Earth s Atmosphere 9/10/2012. Composition. Chapter 3.
Overview of the Earth s Atmosphere Composition 99% of the atmosphere is within 30km of the Earth s surface. N 2 78% and O 2 21% The percentages represent a constant amount of gas but cycles of destruction
More informationTHE EXOSPHERIC HEAT BUDGET
E&ES 359, 2008, p.1 THE EXOSPHERIC HEAT BUDGET What determines the temperature on earth? In this course we are interested in quantitative aspects of the fundamental processes that drive the earth machine.
More informationPlanetary Temperatures
Planetary Temperatures How does Sunlight heat a planet with no atmosphere? This is similar to our dust grain heating problem First pass: Consider a planet of radius a at a distance R from a star of luminosity
More informationGlobal Climate Change
Global Climate Change Definition of Climate According to Webster dictionary Climate: the average condition of the weather at a place over a period of years exhibited by temperature, wind velocity, and
More informationPTYS 214 Spring Announcements. Next midterm 3/1!
PTYS 214 Spring 2018 Announcements Next midterm 3/1! 1 Previously Solar flux decreases as radiation spreads out away from the Sun Planets are exposed to some small amount of the total solar radiation A
More information2. What does a mercury barometer measure? Describe this device and explain how it physically works.
Written Homework #1 Key NATS 101, Sec. 13 Fall 2010 40 Points total 10 points per graded question 10 points for attempting all questions. 1. What is the difference between mass and weight? Mass is an intrinsic
More informationThe Atmosphere. Topic 3: Global Cycles and Physical Systems. Topic 3: Global Cycles and Physical Systems. Topic 3: Global Cycles and Physical Systems
The Atmosphere 1 How big is the atmosphere? Why is it cold in Geneva? Why do mountaineers need oxygen on Everest? 2 A relatively thin layer of gas over the Earths surface Earth s radius ~ 6400km Atmospheric
More informationThe Structure and Motion of the Atmosphere OCEA 101
The Structure and Motion of the Atmosphere OCEA 101 Why should you care? - the atmosphere is the primary driving force for the ocean circulation. - the atmosphere controls geographical variations in ocean
More informationLet s make a simple climate model for Earth.
Let s make a simple climate model for Earth. What is the energy balance of the Earth? How is it controlled? ó How is it affected by humans? Energy balance (radiant energy) Greenhouse Effect (absorption
More informationMon Oct 20. Today: radiation and temperature (cont) sun-earth geometry energy balance >> conceptual model of climate change Tues:
Mon Oct 20 Announcements: bring calculator to class from now on > in-class activities > midterm and final Today: radiation and temperature (cont) sun-earth geometry energy balance >> conceptual model of
More informationLearning goals. Good absorbers are good emitters Albedo, and energy absorbed, changes equilibrium temperature
Greenhouse effect Learning goals Good absorbers are good emitters Albedo, and energy absorbed, changes equilibrium temperature Wavelength (color) and temperature related: Wein s displacement law Sun/Hot:
More informationIntroduction to Electromagnetic Radiation and Radiative Transfer
Introduction to Electromagnetic Radiation and Radiative Transfer Temperature Dice Results Visible light, infrared (IR), ultraviolet (UV), X-rays, γ-rays, microwaves, and radio are all forms of electromagnetic
More informationDirected Reading. Section: Solar Energy and the Atmosphere RADIATION. identical point on the next wave. waves
Skills Worksheet Directed Reading Section: Solar Energy and the Atmosphere 1. How is Earth s atmosphere heated? 2. Name the two primary sources of heat in the atmosphere. RADIATION In the space provided,
More informationChapter 2. Heating Earth's Surface & Atmosphere
Chapter 2 Heating Earth's Surface & Atmosphere Topics Earth-Sun Relationships Energy, Heat and Temperature Mechanisms of Heat Transfer What happens to Incoming Solar Radiation? Radiation Emitted by the
More informationP607 Climate and Energy (Dr. H. Coe)
P607 Climate and Energy (Dr. H. Coe) Syllabus: The composition of the atmosphere and the atmospheric energy balance; Radiative balance in the atmosphere; Energy flow in the biosphere, atmosphere and ocean;
More informationLecture 2: Global Energy Cycle
Lecture 2: Global Energy Cycle Planetary energy balance Greenhouse Effect Selective absorption Vertical energy balance Solar Flux and Flux Density Solar Luminosity (L) the constant flux of energy put out
More informationSolar Flux and Flux Density. Lecture 2: Global Energy Cycle. Solar Energy Incident On the Earth. Solar Flux Density Reaching Earth
Lecture 2: Global Energy Cycle Solar Flux and Flux Density Planetary energy balance Greenhouse Effect Selective absorption Vertical energy balance Solar Luminosity (L) the constant flux of energy put out
More informationPrentice Hall EARTH SCIENCE. Tarbuck Lutgens
Prentice Hall EARTH SCIENCE Tarbuck Lutgens Chapter 17 The Atmosphere: Structure and Temperature 17.1 Atmosphere Characteristics Composition of the Atmosphere Weather is constantly changing, and it refers
More informationSpectrum of Radiation. Importance of Radiation Transfer. Radiation Intensity and Wavelength. Lecture 3: Atmospheric Radiative Transfer and Climate
Lecture 3: Atmospheric Radiative Transfer and Climate Radiation Intensity and Wavelength frequency Planck s constant Solar and infrared radiation selective absorption and emission Selective absorption
More informationInvestigating Planets Name: Block: E1:R6
FYI: Planetary Temperatures and Atmospheres Read FYI: A Planet s Temperature, The Importance of an Atmosphere, and The Greenhouse Effect As you read answer the following questions about the readings: Word/Term
More informationLecture 3: Atmospheric Radiative Transfer and Climate
Lecture 3: Atmospheric Radiative Transfer and Climate Solar and infrared radiation selective absorption and emission Selective absorption and emission Cloud and radiation Radiative-convective equilibrium
More informationBalancing planetary energy budgets
Balancing planetary energy budgets Energy transfer, by radiation and other processes, takes place in a planet s and at its surface, and drives its climate system. How do these processes differ between
More informationGreenhouse Effect. Julia Porter, Celia Hallan, Andrew Vrabel Miles, Gary DeFrance, and Amber Rose
Greenhouse Effect Julia Porter, Celia Hallan, Andrew Vrabel Miles, Gary DeFrance, and Amber Rose What is the Greenhouse Effect? The greenhouse effect is a natural occurrence caused by Earth's atmosphere
More informationAgronomy 406 World Climates January 11, 2018
Agronomy 406 World Climates January 11, 2018 Greenhouse effect quiz. Atmospheric structure and Earth's energy budget. Review for today: Online textbook: 2.1.1 The heat balance at the top of the atmosphere.
More informationUnderstanding the Greenhouse Effect
EESC V2100 The Climate System spring 200 Understanding the Greenhouse Effect Yochanan Kushnir Lamont Doherty Earth Observatory of Columbia University Palisades, NY 1096, USA kushnir@ldeo.columbia.edu Equilibrium
More informationRadiation Conduction Convection
Lecture Ch. 3a Types of transfers Radiative transfer and quantum mechanics Kirchoff s law (for gases) Blackbody radiation (simplification for planet/star) Planck s radiation law (fundamental behavior)
More informationLecture 5: Greenhouse Effect
/30/2018 Lecture 5: Greenhouse Effect Global Energy Balance S/ * (1-A) terrestrial radiation cooling Solar radiation warming T S Global Temperature atmosphere Wien s Law Shortwave and Longwave Radiation
More informationLecture 9: Climate Sensitivity and Feedback Mechanisms
Lecture 9: Climate Sensitivity and Feedback Mechanisms Basic radiative feedbacks (Plank, Water Vapor, Lapse-Rate Feedbacks) Ice albedo & Vegetation-Climate feedback Cloud feedback Biogeochemical feedbacks
More informationAtmospheric "greenhouse effect" - How the presence of an atmosphere makes Earth's surface warmer
Atmospheric "greenhouse effect" - How the presence of an atmosphere makes Earth's surface warmer Some relevant parameters and facts (see previous slide sets) (So/) 32 W m -2 is the average incoming solar
More informationObserving Habitable Environments Light & Radiation
Homework 1 Due Thurs 1/14 Observing Habitable Environments Light & Radiation Given what we know about the origin of life on Earth, how would you recognize life on another world? Would this require a physical
More informationME 476 Solar Energy UNIT TWO THERMAL RADIATION
ME 476 Solar Energy UNIT TWO THERMAL RADIATION Unit Outline 2 Electromagnetic radiation Thermal radiation Blackbody radiation Radiation emitted from a real surface Irradiance Kirchhoff s Law Diffuse and
More information2. Illustration of Atmospheric Greenhouse Effect with Simple Models
2. Illustration of Atmospheric Greenhouse Effect with Simple Models In the first lecture, I introduced the concept of global energy balance and talked about the greenhouse effect. Today we will address
More informationIB Physics Lesson Year Two: Standards from IB Subject Guide beginning 2016
IB Physics Lesson Year Two: Standards from IB Subject Guide beginning 2016 Planet Designer: Kelvin Climber IB Physics Standards taken from Topic 8: Energy Production 8.2 Thermal energy transfer Nature
More informationEnergy Balance and Temperature. Ch. 3: Energy Balance. Ch. 3: Temperature. Controls of Temperature
Energy Balance and Temperature 1 Ch. 3: Energy Balance Propagation of Radiation Transmission, Absorption, Reflection, Scattering Incoming Sunlight Outgoing Terrestrial Radiation and Energy Balance Net
More informationEnergy Balance and Temperature
Energy Balance and Temperature 1 Ch. 3: Energy Balance Propagation of Radiation Transmission, Absorption, Reflection, Scattering Incoming Sunlight Outgoing Terrestrial Radiation and Energy Balance Net
More informationThe greenhouse effect
16 Waves of amplitude of 1 m roll onto a beach at a rate of one every 12 s. If the wavelength of the waves is 120 m, calculate (a) the velocity of the waves (b) how much power there is per metre along
More informationLecture 5: Greenhouse Effect
Lecture 5: Greenhouse Effect S/4 * (1-A) T A 4 T S 4 T A 4 Wien s Law Shortwave and Longwave Radiation Selected Absorption Greenhouse Effect Global Energy Balance terrestrial radiation cooling Solar radiation
More informationPLATO - 5. Planetary atmospheres
PLATO - 5 Planetary atmospheres 1 Mercury Smallest planet! 0.38 Earth radii! 0.055 Earth masses! 0.39 AU orbit (eccentric)! 350K surface temperature (ranges from 100K-700K)! Slow 59 day rotation (2/3 orbital
More informationHabitable Planets. Much of it stolen from. Yutaka ABE University of Tokyo
Habitable Planets Much of it stolen from Yutaka ABE University of Tokyo 1. Habitability and Water Why water? Importance of Liquid Gas: highly mobile, but low material density. Solid: high density but very
More information[16] Planetary Meteorology (10/24/17)
1 [16] Planetary Meteorology (10/24/17) Upcoming Items 1. Homework #7 due now. 2. Homework #8 due in one week. 3. Midterm #2 on Nov 7 4. Read pages 239-240 (magnetic fields) and Ch. 10.6 by next class
More informationwater Plays dominant role in radiation All three phases emit and absorb in longwave radiation
4.,4. water Plays dominant role in radiation All three phases emit and absorb in longwave radiation Some shortwave (solar) radiation is absorbed by all phases of water Principal role in the shortwave radiation
More informationThe Atmosphere and Atmospheric Energy Chapter 3 and 4
The Atmosphere and Atmospheric Energy Chapter 3 and 4 Size of the Earth s Atmosphere Atmosphere produced over 4.6 billion years of development Protects us from radiation Completely surrounds the earth
More informationEarth Systems Science Chapter 3
Earth Systems Science Chapter 3 ELECTROMAGNETIC RADIATION: WAVES I. Global Energy Balance and the Greenhouse Effect: The Physics of the Radiation Balance of the Earth 1. Electromagnetic Radiation: waves,
More informationThe Sun and Planets Lecture Notes 6.
The Sun and Planets Lecture Notes 6. Lecture 6 Venus 1 Spring Semester 2017 Prof Dr Ravit Helled Cover photo: Venus in true color (Courtesy of NASA) Venus Properties Venus is the second brightest natural
More informationChapter 3. Multiple Choice Questions
Chapter 3 Multiple Choice Questions 1. In the case of electromagnetic energy, an object that is hot: a. radiates much more energy than a cool object b. radiates much less energy than a cool object c. radiates
More informationLecture 4: Radiation Transfer
Lecture 4: Radiation Transfer Spectrum of radiation Stefan-Boltzmann law Selective absorption and emission Reflection and scattering Remote sensing Importance of Radiation Transfer Virtually all the exchange
More informationToday. Events. Terrestrial Planet Atmospheres (continued) Homework DUE. Review next time? Exam next week
Today Terrestrial Planet Atmospheres (continued) Events Homework DUE Review next time? Exam next week Planetary Temperature A planet's surface temperature is determined by the balance between energy from
More informationSection 2: The Atmosphere
Section 2: The Atmosphere Preview Classroom Catalyst Objectives The Atmosphere Composition of the Atmosphere Air Pressure Layers of the Atmosphere The Troposphere Section 2: The Atmosphere Preview, continued
More informationTorben Königk Rossby Centre/ SMHI
Fundamentals of Climate Modelling Torben Königk Rossby Centre/ SMHI Outline Introduction Why do we need models? Basic processes Radiation Atmospheric/Oceanic circulation Model basics Resolution Parameterizations
More informationExtrasolar planets Detection and habitability
Extrasolar planets Detection and habitability October 23rd 2014 Detecting exoplanets Primary methods : Direct imaging Transit Radial velocity Direct imaging Planets are much fainter than their host star
More information2/22/ Atmospheric Characteristics
17.1 Atmospheric Characteristics Atmosphere: the gaseous layer that surrounds the Earth I. In the past, gases came from volcanic eruptions A. Water vapor was a major component of outgassing B. Other gases
More informationG109 Midterm Exam (Version A) October 10, 2006 Instructor: Dr C.M. Brown 1. Time allowed 50 mins. Total possible points: 40 number of pages: 5
G109 Midterm Exam (Version A) October 10, 2006 Instructor: Dr C.M. Brown 1 Time allowed 50 mins. Total possible points: 40 number of pages: 5 Part A: Short Answer & Problems (12), Fill in the Blanks (6).
More informationLecture 4: Heat, and Radiation
Lecture 4: Heat, and Radiation Heat Heat is a transfer of energy from one object to another. Heat makes things warmer. Heat is measured in units called calories. A calorie is the heat (energy) required
More informationChapter 3 Energy Balance and Temperature. Astro 9601
Chapter 3 Energy Balance and Temperature Astro 9601 1 Topics to be covered Energy Balance and Temperature (3.1) - All Conduction (3..1), Radiation (3.. and 3...1) Convection (3..3), Hydrostatic Equilibrium
More informationEarth! Objectives: Interior and plate tectonics Atmosphere and greenhouse effect
Earth! Objectives: Interior and plate tectonics Atmosphere and greenhouse effect Earth Fun Facts 1. Only body with liquid water on the surface. 2. Most massive terrestrial body in solar system 3. Only
More informationRadiation and the atmosphere
Radiation and the atmosphere Of great importance is the difference between how the atmosphere transmits, absorbs, and scatters solar and terrestrial radiation streams. The most important statement that
More information1. The frequency of an electromagnetic wave is proportional to its wavelength. a. directly *b. inversely
CHAPTER 3 SOLAR AND TERRESTRIAL RADIATION MULTIPLE CHOICE QUESTIONS 1. The frequency of an electromagnetic wave is proportional to its wavelength. a. directly *b. inversely 2. is the distance between successive
More informationThe Atmosphere: Structure and Temperature
Chapter The Atmosphere: Structure and Temperature Geologists have uncovered evidence of when Earth was first able to support oxygenrich atmosphere similar to what we experience today and more so, take
More informationAtmospheric Radiation
Atmospheric Radiation NASA photo gallery Introduction The major source of earth is the sun. The sun transfer energy through the earth by radiated electromagnetic wave. In vacuum, electromagnetic waves
More informationOutline. Stock Flow and temperature. Earth as a black body. Equation models for earth s temperature. Balancing earth s energy flows.
Outline Stock Flow and temperature Earth as a black body Equation models for earth s temperature { { Albedo effect Greenhouse effect Balancing earth s energy flows Exam questions How does earth maintain
More informationTeaching Energy Balance using Round Numbers: A Quantitative Approach to the Greenhouse Effect and Global Warming
Teaching Energy Balance using Round Numbers: A Quantitative Approach to the Greenhouse Effect and Global Warming Brian Blais Science and Technology Department Bryant College bblais@bryant.edu August 29,
More informationTroposphere and mesosphere Stratosphere and thermosphere radio
Warm-up Page: 518, 1. What two layers of the atmosphere is temperature decreasing? Troposphere and mesosphere Page: 518, 2. What two layers of the atmsophere is temperature increasing? Stratosphere and
More informationVery Dynamic! Energy in the Earth s Atmosphere. How Does it Get Here? All Objects Radiate Energy!
Energy in the Earth s Atmosphere Unit Essential Question: What are the different features of the atmosphere that characterize our weather. How does the atmosphere influence life and how does life influence
More informationEarth s Atmosphere. Energy Transfer in the Atmosphere. 3. All the energy from the Sun reaches Earth s surface.
CHAPTER 11 LESSON 2 Earth s Atmosphere Energy Transfer in the Atmosphere Key Concepts How does energy transfer from the Sun to Earth and to the atmosphere? How are air circulation patterns within the atmosphere
More informationUnique nature of Earth s atmosphere: O 2 present photosynthesis
Atmospheric composition Major components N 2 78% O 2 21% Ar ~1% Medium components CO 2 370 ppmv (rising about 1.5 ppmv/year) CH 4 1700 ppbv H 2 O variable Trace components H 2 600 ppbv N 2 O 310 ppbv CO
More informationChapter 3 Energy Balance and Temperature. Topics to be covered
Chapter 3 Energy Balance and Temperature Astro 9601 1 Topics to be covered Energy Balance and Temperature (3.1) - All Conduction (3..1), Radiation (3.. and31) 3...1) Convection (3..3), Hydrostatic Equilibrium
More informationTananyag fejlesztés idegen nyelven
Tananyag fejlesztés idegen nyelven Prevention of the atmosphere KÖRNYEZETGAZDÁLKODÁSI AGRÁRMÉRNÖKI MSC (MSc IN AGRO-ENVIRONMENTAL STUDIES) Fundamentals in air radition properties Lecture 8 Lessons 22-24
More information