Climate Forcing.

Slides:

Advertisements

Similar presentations

FEEDBACK PARAMETERS Let T s = global mean surface air temperature R= net flux of heat into the climate system ΔR f = change in R due to some change in.

Advertisements

Feedback effects When the Earth warms up, a large number of changes take place in the atmosphere, the oceans, and the land surface. Some of these changes.

Water Vapor and Cloud Feedbacks Dennis L. Hartmann in collaboration with Mark Zelinka Department of Atmospheric Sciences University of Washington PCC Summer.

Earth’s radiative balance or, how I learned to stop worrying and love the greenhouse effect If the Earth had no atmosphere: T  T 4 = S / 4 (1 — A) T =

Global Warming and Climate Sensitivity Professor Dennis L. Hartmann Department of Atmospheric Sciences University of Washington Seattle, Washington.

Radiative Properties of Clouds SOEE3410 Ken Carslaw Lecture 3 of a series of 5 on clouds and climate Properties and distribution of clouds Cloud microphysics.

Climate Sensitivity & Climate Feedback Instructor: Prof. Johnny Luo

Radiative Properties of Clouds SOEE3410 Ken Carslaw Lecture 3 of a series of 5 on clouds and climate Properties and distribution of clouds Cloud microphysics.

Radiative Properties of Clouds ENVI3410 : Lecture 9 Ken Carslaw Lecture 3 of a series of 5 on clouds and climate Properties and distribution of clouds.

Climate Change and its consequences Bill Menke October 4, 2005.

Evaluation II – The Atmosphere Feedback describes the situation when output from (or information about the result of) an event or phenomenon in the past.

Forcing the Climate. Climate Forcing Radiative Forcing Non-Radiative Forcing Change in the Earth’s energy balance.

Lesson 2 AOSC 621. Radiative equilibrium Where S is the solar constant. The earth reflects some of this radiation. Let the albedo be ρ, then the energy.

MET 12 Global Climate Change – Lecture 8

The Greenhouse Effect CLIM 101 // Fall 2012 George Mason University 13 Sep 2012.

Why do climates change ? Climate changes over the last millennium.

CH 24.3 Solar Radiation, Pressure, & Wind. Earth’s Energy Balance Input = Sun’s Energy = (Visible light + some UV) REFLECTED: ~ 25 % by clouds, dust,

Outline Further Reading: Chapter 04 of the text book - global radiative energy balance - insolation and climatic regimes - composition of the atmosphere.

Lecture 14 Climate Sensitivity, thermal inertia. Climate Sensitivity The change in equilibrium temperature per unit of radiative forcing.

Global Warming Cause for Concern. Cause for Concern? What is the effect of increased levels of carbon dioxide in the Earth’s atmosphere? Nobody knows.

Heating of the Atmosphere

Radiation Group 3: Manabe and Wetherald (1975) and Trenberth and Fasullo (2009) – What is the energy balance of the climate system? How is it altered by.

Climate Literacy Session: Causes Peter Coombe August 5, 2015.

Very Basic Climate Modeling Spring 2012, Lecture 5 1.

Earth’s Energy Balance Complexity, climate change and human systems HCOL 185.

Albedo varies with season and geography Surface cover that has a high albedo Snow & ice Cloud cover Aerosols 

Carbon Dioxide CO 2 RF = 1.66 W/m 2. Methane CH 4 RF = 0.48 W/m 2.

Understanding the Science of Climate Change Susquehanna University January 9, 2015

The Atmosphere: Part 8: Climate Change: Sensitivity and Feedbacks Composition / Structure Radiative transfer Vertical and latitudinal heat transport Atmospheric.

Ice Ages. From the Last class, this implies a change of /160 = 4% change in the incoming solar constant – this is too small of variation.

Goals for Today 1.PREDICT the consequences of varying the factors that determine the (a) effective radiating temperature and (b) mean surface temperature.

Blackbody Radiation/ Planetary Energy Balance

Introduction to Climate and Environmental Physics HS 2014 Lecture II Christoph Raible, Markus Leuenberger, Fortunat Joos and Thomas Stocker.

ENSC 425/625 Chapter 2UNBC1 Chapter 2 Systems approach Objectives: Couplings & Feedback loops Equilibrium states Perturbations & Forcings CO 2 -temp.-photosyn.

Global Change: Class Exercise Global Energy Balance & Planetary Temperature Mteor/Agron/Envsci/Envst 404/504.

1 Weather, Climate & Society ATMO 325 Global Energy Balance Greenhouse Effect.

Balance of Energy on Earth Yumna Sarah Maria. The global energy balance is the balance between incoming energy from the sun and outgoing heat from the.

The Greenhouse Effect. A greenhouse is a building used to grow plants when the outside temperature is too low. The roof of the greenhouse prevents convection.

SOLAR CONSTANT Wm W m -2 is radiated on a plane tangent to the Earth at all times – the “Solar Constant.” This amounts to only.

Faint Young Sun Paradox

Atmospheric Structure and Insolation

Natural Environments: The Atmosphere

Climate feedbacks: Water vapor, snow/ice albedo, and clouds

How the Greenhouse Effect Works/Feedback factors

Composition & Structure

8.10 Feedback Loops and Climate

Global energy balance SPACE

Chapter 14: Climate Change

The absorption of solar radiation in the climate system

Climate Change and Earth

Chapter 3 Atmospheric Radiative Transfer and Climate

IPCC Climate Change Report

The Whole Earth Course Why the climate problem is difficult…

Greenhouse Gases and Climate Modeling

What controls climate? Energy from the Sun – Radiation

Miss. Jadhav S.V. Assit.Professor

Global Warming Effects of increase CO2

Patterns in environmental quality and sustainability

Climate Variability and Change

Understanding Radiative Forcing

Atmosphere Thinking Sheet 1/30/18 or 1/31/18

What controls climate? Energy from the Sun – Radiation

Atmospheric Heating Notes

Global Change: Class Exercise

Faint Young Sun Paradox

Chapter 13: The Earth’s Changing Climate

Oceans and Atmosphere Oceans are the envelope of water

Climate Change – Causes and Impacts

Global Change: Class Exercise

Global Change: Class Exercise

Presentation transcript:

Climate Forcing

Direct Forcing from Volcanoes

Assumptions: 1 extra W per square meter gives you 0.25K increase in surface temperature but this requires 6 extra watts per square meter from the sun given the albedo.

Extra Forcings When water vapor is considered the constant is about double that of just BB radiation

Ice Age Calibration

Doubling CO2 scenario As of 2000 Combined positive (GHG) + negative (aerosols) seems to be about 2 Wm-2 Double CO2 = 5.35(ln2) = 3.7 Watts per square meter; Flux on ground is about 160 watts per square meter so this is equivalent to increase in sun’s output by 3.7/160 = 2.3%; Increase S in below relation by 2.3% to get 1.5 C of Temperature increase. This is equivalent to 2/160 = 1.25% leading to 0.8 C increase in the year 2000 Data suggest bigger increase most likely due to water vapor feedback

The heat content of the land-atmosphere-ocean system is

Feedbacks Water vapor changes Clouds Albedo changes Lapse rate Added GHGs These all change OLR (outgoing long wavelength radiation) At equilibrium

First term = changes in solar output Second term = changes in lapse rate Third term = water vapor Fourth term = GHG Fifth term = Clouds Sixth Term = Albedo change If each degree C of warming leads to a feedback factor f of additional warming this then leads to: Constraints: 0<f<1 for the series to converge; f > 1 = runaway (Venus)

F –H2O is about 0. 5 so doubling of C02 with H20 Feedback is now 1. 5/ F –H2O is about 0.5 so doubling of C02 with H20 Feedback is now 1.5/.5 = 3 C Suppose this results in more clouds and changes the albedo by 0.2 then this results in 1.5/(1-.5-.2) = 5 C If its only an albedo change then its 1.5/.8 = 1.9 C