Stull: Chap: 4 and W&H chap: 9

Slides:

Advertisements

Similar presentations

Micrometeorology Surface Layer Dynamics and Surface Energy Exchange

Advertisements

Electromagnetic Radiation

MET 112 Global Climate Change

The Earth’s Global Energy Balance

Chapter 12 : Thermal Radiation

Soil temperature and energy balance. Temperature a measure of the average kinetic energy of the molecules of a substance that physical property which.

Measurement of Radiation - Solar radiation - Long wave radiation - Net radiation - Exposure of radiation sensors.

Electromagnetic Radiation Electromagnetic Spectrum Radiation Laws Atmospheric Absorption Radiation Terminology.

1. 2 Definition 1 – Remote sensing is the acquiring of information about an object or scene without touching it through using electromagnetic energy a.

Radiative Atmospheric Divergence using ARM Mobile Facility, GERB data and AMMA stations A proposal led by Tony Slingo to deploy the new ARM Mobile Facility.

Photosynthetically-active radiation (spectral portion, CI) h h h h h h h h.

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.

Atmospheric scatterers

Climate Earth’s Radiation Balance. Solar Radiation Budget Life on earth is supported by energy from the sun Energy from the sun is not simply absorbed.

MET 60: Chapter: 4 (W&H) and 2 (Stull) Radiative Transfer Dr. Craig Clements San José State University.

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.

Microclimatological Instrumentation Lethbridge Microclimate Station (Flanagan) Trent Weather Station (Lafleur)

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.

Micrometeorology Instrumentation Micrometeorology is the study of the atmosphere near the surface and its associated turbulence and transport of scalars.

Outline Further Reading: Chapter 04 of the text book - matter-energy interactions - shortwave radiation balance - longwave radiation balance Natural Environments:

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.

THE RADIATION BUDGET (Exercise) Exercise: Monitor radiation budget at 2 sites (urban rural) using instruments.

A Basic Introduction to Boundary Layer Meteorology Luke Simmons.

MET 61 1 MET 61 Introduction to Meteorology MET 61 Introduction to Meteorology - Lecture 8 “Radiative Transfer” Dr. Eugene Cordero San Jose State University.

What is the Greenhouse Effect?. Review of last lecture – The two basic motions of the Earth – What causes the four seasons: the Earth’s tilt and the 3.

Lecture 1: Introduction to the planetary energy balance Keith P Shine, Dept of Meteorology,The University of Reading

Atmospheric temperature

Quick Review of Remote Sensing Basic Theory Paolo Antonelli CIMSS University of Wisconsin-Madison Benevento, June 2007.

Pat Arnott, ATMS 749 Atmospheric Radiation Transfer ATMS 749 Atmospheric Radiation Transfer.

1 Met 10 Weather Processes Jeff Gawrych Temperature, Heat Transfer and Earth’s Energy Balance.

Atmospheric InstrumentationM. D. Eastin Measurement of Radiation.

Radiation in the Atmosphere (Cont.). Cloud Effects (2) Cloud effects – occur only when clouds are present. (a) Absorption of the radiant energy by the.

Tananyag fejlesztés idegen nyelven Prevention of the atmosphere KÖRNYEZETGAZDÁLKODÁSI AGRÁRMÉRNÖKI MSC (MSc IN AGRO-ENVIRONMENTAL STUDIES)

SATELLITE METEOROLOGY BASICS satellite orbits EM spectrum

Energy: Warming the Earth & the Atmosphere

The Atmosphere.

GEOGRAPHY 3015A. IT WAS AN INTERESTING SUMMER!

Chapter 4 Atmosphere and Surface Energy Balances Robert W. Christopherson Charlie Thomsen.

USE THESE VALUES. e(T) = e s (T Dew ) PRACTICE WITH STABILITY.

EG2234: Earth Observation Interactions - Land Dr Mark Cresswell.

Copyright © 2013 Pearson Education, Inc. The Atmosphere: An Introduction to Meteorology, 12 th Lutgens Tarbuck Lectures by: Heather Gallacher, Cleveland.

Sun’s Energy Quick Review. Radiation that bounces off a surface is 1. reflected energy 2. transmitted energy 3. emitted energy 4. absorbed energy.

Surface energy balance (2). Review of last lecture –What is energy? 3 methods of energy transfer –The names of the 6 wavelength categories in the electromagnetic.

What is temperature? Measure of the average random kinetic energy of the molecules of a substance Physical property that determines the direction of heat.

ATM 301 Lecture #9 (6.1, Appendix D) Surface Energy Fluxes and Balance Major Surface Energy Fluxes Review of Radiation Solar Radiation Thermal Radiation.

Solar and Earth Radiation. Solar radiation – Any incoming radiation measured at the earth’s surface Earth radiation – The long-wave band of radiation.

Microclimatological Instrumentation.

Incoming & Outgoing of Energy of the Earth. The Earth’s Energy Balance The Earth's average temperature remains fairly constant from year to year. Therefore,

SIO 210: Light and Optics Oct. 12, 2009 Uwe Send Reading: DPO chapter 3 J.R. Apel, Principles of Ocean Physics,

The Atmosphere: Structure and Temperature

Electromagnetic Radiation Solar radiation warms the planet Conversion of solar energy at the surface Absorption and emission by the atmosphere The greenhouse.

1 MET 112 Global Climate Change MET 112 Global Climate Change - Lecture 3 The Earth’s Energy Balance Dr. Eugene Cordero San Jose State University Outline.

Within dr, L changes (dL) from… sources due to scattering & emission losses due to scattering & absorption Spectral Radiance, L(, ,  ) - W m -2 sr -1.

Evaporation What is evaporation? How is evaporation measured? How is evaporation estimated? Reading for today: Applied Hydrology Sections 3.5 and 3.6 Reading.

Quick Review of Remote Sensing Basic Theory Paolo Antonelli SSEC University of Wisconsin-Madison Monteponi, September 2008.

Earth and Space Science TEK 14 a 14) Fluid Earth. The student knows that Earth’s global ocean stores solar energy and is a major driving force for weather.

Planck’s law  Very early in the twentieth century, Max Karl Ernest Ludwig Planck put forth the idea of the quantum theory of radiation.  It basically.

Electromagnetic Radiation Principles

Radiation Balance.

Radiation Balance. Radiation Balance In atmosphere, radiation can be… transmitted absorbed reflected.

Schedule 12 lectures 3 long labs (8 hours each) 2 homework

Surface Energy Budget, Part I

Soil temperature and energy balance

Outline of the course The Basics The global hydrological cycle

Global energy balance SPACE

Natural Environments: The Atmosphere

Lecture 6: Energy balance and temperature (Ch 3)

ATOC 4720 class29 1. How the energy balance is achieved in the earth-atmosphere system 2. The energy balance of the upper atmosphere 3. The energy balance.

The Earth’s Energy Budget/ Heat Balance

Presentation transcript:

Stull: Chap: 4 and W&H chap: 9 Micrometeorology Boundary Layer Meteorology Surface Energy Budget Micrometeorology is the study of the atmosphere near the surface and its associated turbulence and transport of scalars. It deals with the small horizontal and short temporal scales of motion in meteorology. Typically, less than 1 km and 1 hr. The atmospheric boundary layer is formed as a consequence of the interactions between the atmosphere and the surface of earth. Micrometeorologists study these interactions. A variety of instrumentation is used to measure the atmospheric boundary layer and related turbulence. Stull: Chap: 4 and W&H chap: 9

Boundary Layer Defined A boundary layer is the layer next to a physical boundary such as the inside wall of a pipe. In our case the earth’s surface. Transport processes modify the lowest 100 to 3000 m AGL (above ground level) of the troposphere creating the boundary layer. The atmosphere above the boundary layer is called the free atmosphere, typically. The boundary layer air separates the atmosphere from the earth’s surface. Actually, the atmosphere really doesn’t know that the earth is below it.

Planetary Boundary Layer The layer of air influenced by surface friction is called the planetary boundary layer (PBL). Define the boundary layer as that part of the troposphere that is directly influenced by the presence of the earth’s surface, and responds to surface forcings with a timescale of ~ 1 hr or less.

Pollutants in the Atmospheric Boundary Layer

5 August 2006 Evening (6 PM) University of Houston Sounding

University of Houston 26 Sept 2006 0700 CDT 1000 1300 1600 1900

Background: definitions What is turbulence? Simply defined as perturbation from the mean.

How do we measure u′? A sonic anemometer measures at very high sampling rates. This is typically at 10 or 20 Hz. Data from a high temporal resolution time series is used to calculate the mean of the time series and subsequently a perturbation from the mean. Once the perturbations are calculated, turbulent statistics can be calculated.

Turbulent Sensible Heat Flux Turbulent Flux? Transport of a quantity by eddies or swirls. The covariance of a velocity component and any quantity. Eddy Mixes some air down And some air up z  ´= neg. w´= neg. Turbulent Sensible Heat Flux ´= + Net upward heat flux w´= +

Turbulent Heat Flux Sensible Heat Flux: Latent Heat Flux:

Variance One statistical measure of the dispersion of data about the mean is the biased variance It is a good measure of the dispersion of a sample of BL observations. However, recall that Substituting this into the biased definition of variance:

Turbulence Kinetic Energy (TKE) is a measure of the intensity of turbulence simply the summed velocity variances

Radiation Definitions Radiation flux: is the amount of radiation coming from a source per unit time in W. Radiant intensity: is the radiant flux leaving a point on the source, per unit solid angle of space surrounding the point. [W/steradian] Radiance: is the radiant flux emitted by a unit area of a source or scattered by a unit area of a surface.[W m-2 sr-1] Irradiance: is the radiant flux incident on a receiving surface from all directions, per unit area W m-2. Absorptance, reflectance, transmittance: fractions of the incident flux that are absorbed, reflected, or transmitted by a medium. Global Solar radiation: is the solar irradiance received on a horizontal surface [W m-2]. This is the sum of direct solar beam plus the diffuse component of skylight, and is the physical quantity measured by a pyranometer.

Radiation Definitions Visible Radiation: is the spectral range of the standard observer. Most of the visible radiation lies between 400 nm and 730 nm. Ultraviolet Radiation: is the radiation with wavelengths in the range 100 to 400 nm. It is subdivided into three ranges: UVA is 315-400 nm, UVB is 280-315 nm, and UVC is 100-280 nm. Infrared Radiation: is the radiation with wavelengths longer than 730 nm.

Radiation Definitions Direct solar radiation: is the radiation emitted from the solid angle of the sun’s disc, received on a surface perpendicular to the axis of this cone, comprising mainly unscattered and unreflected solar radiation. At the top of the atmosphere this is usually: 1367 W m-2 . The direct solar radiation at the earth’s surface is the physical quantity measured by a pyrheliometer. Diffuse Solar Radiation: (Sky radiation) is the downward scattered and reflected radiation coming from the whole hemisphere. Diffuse radiation can be measured by a pyranometer mounted in a shadow band.

Radiation Definitions Photosynthetically Active Radiation (PAR): is the band of solar radiation between 400-700 nm that plants use in the photosynthesis process. PAR is usually expressed in moles of photons, a mole being Avogadro’s number of photons, 6.022 x 1023 photons. Albedo: is the fraction of incoming solar radiation to reflected solar radiation. α = SWreflect / SWincoming

Methods of Measurement Two primary methods in the measurement of radiation: Thermal detection: response to heat gain or loss due to absorption of incoming or emission of outgoing radiation. Photovoltaic detectors: convert absorbed radiation to a voltage. Shortwave or solar radiation is defined to be 0.3 μm to 4 μm BUT since high-quality glass windows are transparent from 0.3 to 3 μm, an upper limit of 3 μm is generally accepted. Longwave radiation sensors have windows transparent to radiation from 3 or 4 μm to at least 50 μm .

Types of instruments Radiation measuring instruments can be classified according to their use. The generic term for all radiation measuring instruments is the radiometer. A pyranometer is used to measure global solar radiation, so it must respond to both the direct solar beam and to diffuse sky radiation from the whole hemisphere. The sensing element must be a horizontal flat surface. A pyrgeometer is used to measure global, long-wave earth radiation. An instrument that measures the difference between incoming and outgoing radiation is called a pyrradiometer or net radiometer.

Pyranometers Typical sensitivity of a thermopile pyranometer is 4 μV W-1 m2 and the time constant 5 s.

Surface Energy Budget -Q* = QH + QE – QG + ΔQs The energy budget at the earth’s surface can be thought of as energy transferred through a layer at the surface. This includes turbulent energy transfer with the air above it, radiative transfer through the top of it, and molecular energy transfer into the soil below it. -Q* = QH + QE – QG + ΔQs -Q* = net upward radiation at surface QH = upward sensible heat flux QE = upward latent heat flux QG = upward molecular heat flux into the bottom ΔQS = storage/residual sun QH QE -Q* -QG

Surface Radiation Budget Shortwave longwave Diffuse and direct

Turbulent Heat Fluxes from Tower at UH Coastal Center (10 min Ave of Covariances) Surface Energy Balance: Q*=QH+QL+QG