Presentation is loading. Please wait.

Presentation is loading. Please wait.

Atmospheric TU Delft Stephan de Roode, Harm Jonker clouds, climate and weather air quality in the urban environmentenergy.

Published byRichard Buck Osborne Modified over 9 years ago

Similar presentations

Presentation on theme: "Atmospheric TU Delft Stephan de Roode, Harm Jonker clouds, climate and weather air quality in the urban environmentenergy."— Presentation transcript:

1 Atmospheric Physics @ TU Delft Stephan de Roode, Harm Jonker clouds, climate and weather air quality in the urban environmentenergy

2 Conservation equations Mass Momentum "Navier Stokes" Water Heat

3 Clouds & Climate Landsat satellite 65 km 10 km Large Eddy Model ~mm~100m ~1  m-100  m Earth ~13000 km

4 Cloud dynamics 10 m100 m1 km10 km100 km1000 km10000 km turbulence  Cumulus clouds Cumulonimbus clouds Mesoscale Convective systems Extratropical Cyclones Planetary waves Large Eddy Simulation (LES) Model Limited Area Weather Model (LAM) Numerical Weather Prediction (NWP) Model Global Climate Model The Zoo of Atmospheric Models DNS mm Cloud microphysics Fundamental Engineering

5 Cloud dynamics 10 m100 m1 km10 km100 km1000 km10000 km turbulence  Cumulus clouds Cumulonimbus clouds Mesoscale Convective systems Extratropical Cyclones Planetary waves Large Eddy Simulation (LES) Model Current developments DNS mm Cloud microphysics Limited Area Weather Model (LAM) Global Climate Model Numerical Weather Prediction (NWP) Model Fundamental Engineering

6 Cloud dynamics 10 m100 m1 km10 km100 km1000 km10000 km turbulence  Cumulus clouds Cumulonimbus clouds Mesoscale Convective systems Extratropical Cyclones Planetary waves Large Eddy Simulation (LES) Model The Zoo of Atmospheric Models DNS mm Cloud microphysics Limited Area Weather Model (LAM) Global Climate Model Numerical Weather Prediction (NWP) Model Harm Jonker Stephan de Roode Pier Siebesma (KNMI/TUD)

7 Computing the weather

8 Wien’s law: Stefan-Boltzmann Planck:

9 Solar radiation UV image of the sun source: SOHO EIT The sun Surface temperature T sun = 5778 K Radius R sun = 6.96342×10 5 km Total energy production: Q =  T sun 4 x 4  R sun 2 = 3.85×10 26 W energy emitted (W/m 2 ) total surface area (m 2 )

10 Solar constant S 0 : flux of solar energy at the top of the Earth's atmosphere Distance R E-S = 1.496×10 11 m Energy conservation: Flux integrated over the imaginairy surface area of a sphere centered around the sun is constant => Q =  T sun 4 x 4  R sun 2 = S 0 x 4  R E-S 2

11 Radiative equilibrium for an Earth without an atmosphere Radiative equilibrium temperature  p = Earth surface albedo Fraction of solar radiation absorbed by the Earth = Radiation emitted by the Earth

12 Radiative Earth equilibrium temperature (no atmosphere) sea land ice snow mean albedo Earth real mean T earth = 288 K

13 Scattering and absorption absorption cross section  a : effective area of the molecule for removing energy from the incident beam shortwave longwave scattering cross section  sca absorption cross section  a

14 Apply energy balance Energy conservation of the system

15 Apply energy balance Energy conservation of the system Radiative energy balance of the atmosphere

16 Apply energy balance Energy conservation of the system Radiative energy balance of the atmosphere Radiative equilibrium temperature of the Earth surface

17 Radiative equilibrium temperature for an Earth with an atmosphere mean emissivity atmosphere 16°C enhanced greenhouse effect

18 Stephens et al., 2012

19 Clouds in a future climate Dufresne & Bony, Journal of Climate 2008 Radiative effects only Water vapor feedback Surface albedo feedback Cloud feedback

20 The playground for cloud physicists: Hadley circulation deep convectionshallow cumulusstratocumulus

21 Study the evolution of a low cloud deck during its advection towards the tropics deep convectionshallow cumulusstratocumulus

22 Study the effects of clouds on the radiation budget with a high- resolution turbulence model

23 Clouds are strong reflectors of solar radiation cloud layer geometric thickness [m] A total amount of about 0.1 mm of liquid water in an atmospheric column is sufficient to reflect 50% of the downward solar radiation courtesy Kees Floor stratocumulus

24 The Eddington (E) Index Arthur Eddington (Einstein and Eddington, HBO-BBC co-production, 2008 ) Chandrasekhar (Nobel prize for physics 1983) (E-Index 84!)

25 Navier Stokes in DWDD http://dewerelddraaitdoor.vara.nl/media/308806

26 Journal papers writing a paper, how to deal with citations, co-authors? H-index peer review journal impact factor open access journals

27 Exercises 22 October: Paper discussions Stephens et al., 2012: An update on Earth's energy balance in light of the latest global observations, Nature Geosciences. (group 1 presents, group 2 asks questions) Stevens and Bony, 2013: Water in the atmosphere, Physics Today. (group 3 presents, group 4 asks questions) 29 October?: One paper, one exercise Dufresne and Bony, 2008: An assessment of the primary sources of spread of global warming estimates from coupled atmosphere-ocean models, J. Climate. (group 2 presents, group 1 asks questions) Exercise on equilibrium state solutions of low clouds. (group 3 presents, group 4 asks questions)

Download ppt "Atmospheric TU Delft Stephan de Roode, Harm Jonker clouds, climate and weather air quality in the urban environmentenergy."

Similar presentations

Clouds and radiation in a LSM L=50km. Veldhoven, 2009. 2 Stratocumulus cloud albedo: example cloud layer depth = 400 m effective cloud droplet.

Clouds and radiation in a LSM L=50km. Veldhoven, Stratocumulus cloud albedo: example cloud layer depth = 400 m effective cloud droplet.
Veldhoven, 2009. 1 Large-eddy simulation of stratocumulus – cloud albedo and cloud inhomogeneity Stephan de Roode (1,2) & Alexander Los (2)

Veldhoven, Large-eddy simulation of stratocumulus – cloud albedo and cloud inhomogeneity Stephan de Roode (1,2) & Alexander Los (2)
Bare rock model Assumptions

Bare rock model Assumptions
MET 112 Global Climate Change

MET 112 Global Climate Change
Modeling Stratocumulus Clouds: From Cloud Droplet to the Meso-scales Stephan de Roode Clouds, Climate & Air Quality Multi-Scale Physics (MSP), Faculty.

Modeling Stratocumulus Clouds: From Cloud Droplet to the Meso-scales Stephan de Roode Clouds, Climate & Air Quality Multi-Scale Physics (MSP), Faculty.
Chapter 17 Study Guide Answers

Chapter 17 Study Guide Answers
Low clouds in the atmosphere: Never a dull moment Stephan de Roode (GRS) stratocumulus cumulus.

Low clouds in the atmosphere: Never a dull moment Stephan de Roode (GRS) stratocumulus cumulus.
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 SOEE3410 Ken Carslaw Lecture 3 of a series of 5 on clouds and climate Properties and distribution of clouds Cloud microphysics.
Climate Forcing and Physical Climate Responses Theory of Climate Climate Change (continued)

Climate Forcing and Physical Climate Responses Theory of Climate Climate Change (continued)
Buoyancy driven turbulence in the atmosphere

Buoyancy driven turbulence in the atmosphere
Energy Budget of the Earth- Atmosphere System. Energy Transfer Conduction -- direct molecular transfer Convection -- fluids; air or water –Sensible heat.

Energy Budget of the Earth- Atmosphere System. Energy Transfer Conduction -- direct molecular transfer Convection -- fluids; air or water –Sensible heat.
CHAPTER 7: THE GREENHOUSE EFFECT. MILLENIAL NH TEMPERATURE TREND [IPCC, 2001]

CHAPTER 7: THE GREENHOUSE EFFECT. MILLENIAL NH TEMPERATURE TREND [IPCC, 2001]
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 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.

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.
Modeling Clouds and Climate: A computational challenge Stephan de Roode Clouds, Climate & Air Quality Multi-Scale Physics (MSP), Faculty of Applied Sciences.

Modeling Clouds and Climate: A computational challenge Stephan de Roode Clouds, Climate & Air Quality Multi-Scale Physics (MSP), Faculty of Applied Sciences.
1 MET 112 Global Climate Change MET 112 Global Climate Change - Lecture 2 The Earth’s Energy Balance Dr. Craig Clements San José State University Outline.

1 MET 112 Global Climate Change MET 112 Global Climate Change - Lecture 2 The Earth’s Energy Balance Dr. Craig Clements San José State University Outline.
EFFECTIVE TEMPERATURE OF THE EARTH SYSTEM First the Sun : 1. The spectrum of solar radiation measured outside the Earth’s atmosphere matches closely that.

EFFECTIVE TEMPERATURE OF THE EARTH SYSTEM First the Sun : 1. The spectrum of solar radiation measured outside the Earth’s atmosphere matches closely that.
Heat Energy Solar and gravitational energy are the fundamental sources of energy for the Earth's climate system. Air-sea exchanges of heat (& freshwater)

Heat Energy Solar and gravitational energy are the fundamental sources of energy for the Earth's climate system. Air-sea exchanges of heat (& freshwater)
MET 61 1 MET 61 Introduction to Meteorology MET 61 Introduction to Meteorology - Lecture 8 “Radiative Transfer” Dr. Eugene Cordero San Jose State University.

MET 61 1 MET 61 Introduction to Meteorology MET 61 Introduction to Meteorology - Lecture 8 “Radiative Transfer” Dr. Eugene Cordero San Jose State University.
Current issues in GFS moist physics Hua-Lu Pan, Stephen Lord, and Bill Lapenta.

Current issues in GFS moist physics Hua-Lu Pan, Stephen Lord, and Bill Lapenta.

Similar presentations

Ads by Google