The Greenhouse Effect. Lan Ma

Similar documents
Radiative Balance and the Faint Young Sun Paradox

Earth: the Goldilocks Planet

Lecture 2 Global and Zonal-mean Energy Balance

Greenhouse Effect. Julia Porter, Celia Hallan, Andrew Vrabel Miles, Gary DeFrance, and Amber Rose

PTYS 214 Spring Announcements. Midterm 3 next Thursday!

Mon Oct 20. Today: radiation and temperature (cont) sun-earth geometry energy balance >> conceptual model of climate change Tues:

PTYS 214 Spring Announcements. Midterm 3 next Thursday! Midterms 4 and 5 more spread out

Earth: A Dynamic Planet A. Solar and terrestrial radiation

IB Physics Lesson Year Two: Standards from IB Subject Guide beginning 2016

PTYS 214 Fall Announcements

Lecture 3: Global Energy Cycle

Lecture 4: Global Energy Balance

Lecture 4: Global Energy Balance. Global Energy Balance. Solar Flux and Flux Density. Blackbody Radiation Layer Model.

Lecture 5: Greenhouse Effect

Mon April 17 Announcements: bring calculator to class from now on (in-class activities, tests) HW#2 due Thursday

Lecture 5: Greenhouse Effect

P607 Climate and Energy (Dr. H. Coe)

Lecture 6. Solar vs. terrestrial radiation and the bare rock climate model.

Take away concepts. What is Energy? Solar Radiation Emission and Absorption. Energy: The ability to do work

Monday 9 September, :30-11:30 Class#03

1. Weather and climate.

ESS15 Lecture 7. The Greenhouse effect.

10/31/2017. Calculating the temperature of earth (The greenhouse effect) IR radiation. The electromagnetic spectrum

Temperature Scales

Energy and Radiation. GEOG/ENST 2331 Lecture 3 Ahrens: Chapter 2

8.5 GREENHOUSE EFFECT 8.6 GLOBAL WARMING HW/Study Packet

Wednesday, September 8, 2010 Infrared Trapping the Greenhouse Effect

Radiative Equilibrium Models. Solar radiation reflected by the earth back to space. Solar radiation absorbed by the earth

Let s make a simple climate model for Earth.

Lecture 2: Global Energy Cycle

The Structure and Motion of the Atmosphere OCEA 101

Lecture # 04 January 27, 2010, Wednesday Energy & Radiation

MASSACHUSETTS INSTITUTE OF TECHNOLOGY Department of Physics Problem Solving 10: The Greenhouse Effect. Section Table and Group

Investigating Planets Name: Block: E1:R6

SIT IN YOUR GROUP AREA TODAY!

Very Dynamic! Energy in the Earth s Atmosphere. How Does it Get Here? All Objects Radiate Energy!

AST 105 Intro Astronomy The Solar System

Earth! Objectives: Interior and plate tectonics Atmosphere and greenhouse effect

Electromagnetic Radiation. Radiation and the Planetary Energy Balance. Electromagnetic Spectrum of the Sun

Understanding the Greenhouse Effect

Atmospheric Radiation

2. Energy Balance. 1. All substances radiate unless their temperature is at absolute zero (0 K). Gases radiate at specific frequencies, while solids

Global Energy Balance. GEOG/ENST 2331: Lecture 4 Ahrens: Chapter 2

Learning goals. Good absorbers are good emitters Albedo, and energy absorbed, changes equilibrium temperature

Stefan-Boltzmann law for the Earth as a black body (or perfect radiator) gives:

2. Illustration of Atmospheric Greenhouse Effect with Simple Models

Radiation Conduction Convection

Lecture 4: Radiation Transfer

Course Outline. About Me. Today s Outline CLIMATE SCIENCE A SHORT COURSE AT THE ROYAL INSTITUTION. 1. Current climate. 2.

AT 350 EXAM #1 February 21, 2008

Energy, Temperature, & Heat. Energy, Temperature, & Heat. Temperature Scales 1/17/11

Blackbody Radiation. A substance that absorbs all incident wavelengths completely is called a blackbody.

Emission Temperature of Planets. Emission Temperature of Earth

- matter-energy interactions. - global radiation balance. Further Reading: Chapter 04 of the text book. Outline. - shortwave radiation balance

TOPIC # 7 The RADIATION LAWS

9/5/16. Section 3-4: Radiation, Energy, Climate. Common Forms of Energy Transfer in Climate. Electromagnetic radiation.

COURSE CLIMATE SCIENCE A SHORT COURSE AT THE ROYAL INSTITUTION

WRAP UP OF TOPIC #6. Fire up your CLICKERS for some questions to solidify the concepts from the last few classes:

ATMOS 5140 Lecture 7 Chapter 6

Earth s Energy Budget: How Is the Temperature of Earth Controlled?

Name(s) Period Date. Earth s Energy Budget: How Is the Temperature of Earth Controlled?

Course Outline CLIMATE SCIENCE A SHORT COURSE AT THE ROYAL INSTITUTION. 1. Current climate. 2. Changing climate. 3. Future climate change

Agronomy 406 World Climates January 11, 2018

Atmospheric "greenhouse effect" - How the presence of an atmosphere makes Earth's surface warmer

Unique nature of Earth s atmosphere: O 2 present photosynthesis

PLANETARY ATMOSPHERES

1. What is the phenomenon that best explains why greenhouse gases absorb infrared radiation? D. Diffraction (Total 1 mark)

THE GREENHOUSE EFFECT

Object Type Moons Rings Planet Terrestrial none none. Max Distance from Sun. Min Distance from Sun. Avg. Distance from Sun 57,910,000 km 0.

Kinds of Energy. Defining Energy is Hard! EXPLAIN: 1. Energy and Radiation. Conservation of Energy. Sco; Denning CSU ESMEI ATS 1

The Chemistry of Global Warming

Thursday, November 1st.

T eff = [F s (1 - A)/(4σ)] ¼ = K.

Lecture 2-07: The greenhouse, global heat engine.

Physical and mathematical models of the greenhouse effect

Radiation in the Earth's Atmosphere. Part 1: Absorption and Emission by Atmospheric Gases

Introduction to Climate Change

Astro 210 Lecture 16 Feb 23, 2018

ATOC 3500/CHEM 3151 Air Pollution Chemistry Lecture 1

Equation for Global Warming

Lecture 2: Light And Air

The gases: gases: H2O O and What What are The two two most most abundant gases The The two two most most abundant abundant Greenhouse

TSOKOS READING ACTIVITY Section 7-2: The Greenhouse Effect and Global Warming (8 points)

Planetary Atmospheres

( 1 d 2 ) (Inverse Square law);

The inputs and outputs of energy within the earth-atmosphere system that determines the net energy available for surface processes is the Energy

Energy Balance and Temperature. Ch. 3: Energy Balance. Ch. 3: Temperature. Controls of Temperature

Energy Balance and Temperature

Which picture shows the larger flux of blue circles?

Lecture 4: Heat, and Radiation

Electromagnetic Radiation.

We re about to play: PSUEDO-JEOPARDY!!!!! (Aka The Answer Is... ) It will refresh your memories about some of the key concepts we ve covered.

Global Climate Change

Climate 1: The Climate System

Our Atmosphere as seen from the bottom of it near Grand Pre, NS. Info modified from various sources by TWebb HHS

Climate Dynamics (PCC 587): Feedbacks & Clouds

ATM S 111: Global Warming Solar Radiation. Jennifer Fletcher Day 2: June

Global Energy Balance: Greenhouse Effect

Fundamentals of Earth s Atmosphere. AOSC 434/658R & CHEM 434/678A Tim Canty

Inaugural University of Michigan Science Olympiad Tournament

Transcription:

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 global warming?

Solar input Radiation from Earth = Source: NASA Visible Earth

Solar input depends on the distance between the Sun and the planets and the size of the planets Earth! 1 AU = 1.5x10 8 km r E = 6378km S 0 = 1367W/m 2

Is that all? It turns out that not all incoming solar radiation is absorbed at Earth s surface. Part of it is directly reflected from clouds, the surface itself, and air molecules. This reflectance of solar input is called albedo; the present value for Earth is about 0.3. http://www.geo.lsa.umich.edu/~crlb/courses/117- IntroductiontoGeology/Lec23/lec23.html

Solar input S 0 = 1367W/m 2 Albedo (0.3)*S 0 Radiation from Earth Source: NASA Visible Earth

The amount of radiation emitted is proportional to 4 the surface temperature of that body radiation emitted = σt E 4 σ Stephan-Boltzmann constant = 5.67x10-8 Wm -2 K -4

Solar input S 0 = 1367W/m 2 Albedo (0.3)S 0 Radiation from Earth (5.67x10-8 W/m 2 K 4 )T 4 E Input = Output S 0 πr E2 (1-α) = 4πr E2 σt 4 E T E = (S 0 (1-α)/4σ) 1/4 = 255K = -18 C!!! Yikes! That s freezing cold!!! Source: NASA Visible Earth

Let s apply the same calculation to Venus and Mars and see Venus Earth Mars 252K 255K 216K Theoretical temp 735K 288K 218K Actual temp

What parameters do we need to calculate the Earth s average surface temperature? Solar input (depends on distance from Sun and size of planet) Albedo (depends on landform and cloud cover) Blackbody assumption (perfect absorption and perfect emission) Greenhouse effect

Wait a second, there is another twist! About 25% of the incoming solar radiation is absorbed by various gases like H 2 O, CO 2, O 2, and O 3 before it hits the surface. So the calculation would be: Input = Output S 0 (1 - α - atmos absorption) = 4σT E 4 = 615 W/m 2 T E = (S 0 (1 - α - atmos absortion)/4σ) 1/4 = 228K = -45 C!!! Opps that s going the wrong direction!

Thankfully, greenhouse gases also save the day! We know the average surface temperature of Earth is about 15 C, by back calculation we see: 4σ(T E ) 4 = 4σ(288K) 4 = 1560 W/m 2 GH Effect = 1560 W/m 2 615 W/m 2 = 945 W/m 2 Let us compare: solar input 1367 W/m 2 greenhouse effect 945 W/m 2

Thankfully, greenhouse gases also save the day! The greenhouse effect is HUGE! From the no atmosphere model of -18 C to an observed average surface temp of 15 C, it is a +33 C effect! Furthermore, if this were linear then we would get 1 C increase for every 7 W/m 2. Thankfully this is not the case, but adding more greenhouse gases into the atmosphere still poses an appreciable amount of warming to Earth!

Let s come back to the planets Venus has a really thick atmosphere (90 times Earth s surface pressure.) More importantly, this atmosphere consists of 96% CO 2 735K 298K 218K Venus Earth Mars

Let s come back to the planets Mars has a very thin atmosphere such that the greenhouse effect is nearly negligible 735K 298K 218K Venus Earth Mars

Let s come back to the planets Earth has an atmosphere composed of 78% N 2, 21% O 2, and only ~1% of traces gases including greenhouse gases 735K 298K 218K Venus Earth Mars Earth is so far the only life-sustaining planet not just because of the right distance from the Sun but also due to a moderate greenhouse effect.

That was a lot of math Now what?!

Past atmosphere

Present atmosphere

Future atmosphere? Source: IPCC AR4

What are greenhouse gases? Source: Global Warming Art

What are greenhouse gases? Greenhouse gases can effectively absorb radiation emitted from the Earth s surface. Such absorption excites molecules to vibrate and rotate and sometimes change their dipole moment. Symmetric and linear molecules like O 2 and N 2 do not have a dipole moment (and cannot produce one).

Dipole Moment Amount of charge separated by distance There needs to be a change in dipole moment- a change of charge for a molecule to interact with the energy radiating from Earth s surface (electromagnetic radiation)

What are greenhouse gases? ν 1 symmetric O C O ν 2 bending 15 μm O C O ν 2 asymmetric 4.3 μm O C O

Sources of greenhouse gases: CO 2 CH 4 N 2 O CFCs / HCFCs O 3 Natural: ocean, volcano, decomposition Anthropogenic: fossil fuel burning, exhaust Natural: aerobic decomposition (wetland, cows) Anthropogenic: fossil fuel burning, agriculture Natural: soil and ocean Anthropogenic: fertilizers (nitrification of ammonium) Anthropogenic: refrigerant, aerosol propellant Natural: photolysis Anthropogenic: NOx + VOCs

Concern? Source: IPCC AR4

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback