Lake Superior Eddy Covariance Stannard Rock Light PI: Peter Blanken, CU-Boulder Reported by Ankur Desai DO NOT DISTRIBUTE.

Slides:

Advertisements

Similar presentations

Atmosphere & Weather Energy Budgets

Advertisements

A NEW LAND-LAKE SENSOR NETWORK FOR MEASURING GREENHOUSE GAS, WATER, AND ENERGY EXCHANGES: USE IN EDUCATION AND OUTREACH 1. Introduction Stepien, Carol.

Watershed Hydrology, a Hawaiian Prospective: Evapotranspiration Ali Fares, PhD Evaluation of Natural Resource Management, NREM 600 UHM-CTAHR-NREM.

MET 112 Global Climate Change

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

Earth’s Global Energy Balance Overview

Sandy desert Modifications of the surface radiation budget.

Sandy Deserts Negligible Evaporation Q*  Q H + Q G Not terribly high Instability in afternoon.

Atmospheric Analysis Lecture 3.

1. a. What is shown here? weather or climate ? b. What is the local time (MDT) this analysis is valid for?

Outline Further Reading: Chapter 05 of the text book - factors affecting temperature - diurnal cycle - seasonal cycle Natural Environments: The Atmosphere.

Chapter 6: Global Fluxes and The Deep Circulation Heat Budget Conservation of Salt Oceanic Water Masses Oceanic Mixing Temperature - Salinity Diagrams.

Lecture ERS 482/682 (Fall 2002) Snow hydrology ERS 482/682 Small Watershed Hydrology.

ATS Lecture 2 Energy & Radiation Surface Maps.

Fire Weather: Temperature & Moisture. Weather and the Earth’s Heat Balance Weather = motion in the atmosphere due to unequal heating Over time, the amount.

ERS 482/682 Small Watershed Hydrology

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.

Evaporative heat flux (Q e ) 51% of the heat input into the ocean is used for evaporation. Evaporation starts when the air over the ocean is unsaturated.

Chapter 4 The Energy Balance of The Surface Kiehl and Trenberth (1997) 1.Why The SEB? 2.What and How? a.SEB components (Rn, SH, LE, G, B, Tskin, ε, α,

Discussion Session Lisha M. Roubert University of Wisconsin-Madison Department of Atmospheric & Oceanic Sciences.

Evapotranspiration - Rate and amount of ET is the core information needed to design irrigation projects, managing water quality, predicting flow yields,

MODELING OF COLD SEASON PROCESSES Snow Ablation and Accumulation Frozen Ground Processes.

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

These notes are provided to help you pay attention IN class. If I notice poor attendance, fewer notes will begin to appear on these pages Snow Measuring.

Energy: Warming the earth and Atmosphere

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.

Ch3: Energy Balance and Temperature. 1.About the first in-class assignment 2.About reading the textbook.

1. Atmospheric Circulation. Thermosphere Mesosphere Stratosphere Troposphere 300 km 50 km 40 km 10 km 400 km altitude Exosphere is the Earth’s  110 km.

Earth’s Energy Balance 100 units of solar radiation hits the top of the atmosphere 100 units of solar radiation hits the top of the atmosphere Surface.

Climate and Weather David M. Hassenzahl ENV 206: Introduction to Climate Change.

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

近地面微氣象學授課老師 : 游政谷 ( Micrometeorology near the Ground ) Micrometeorology(2)

Kevin Czajkowski, Richard Becker, Changliang Shao Jiquan Chen, Carol Stepien, Thomas Bridgeman, Housen Chu 4/24/2014.

Influence of Clouds on Surface Heat Fluxes in an Energy Deficient Regime Dea Doklestic G&G 570 Class Project Heat Budget Group Presentation, June 16, 2011.

Lecture 8 Evapotranspiration (1) Evaporation Processes General Comments Physical Characteristics Free Water Surface (the simplest case) Approaches to Evaporation.

Lecture 2: Energy in the Atmosphere Vertical structure of the static atmosphere Basics from physics: force, work, heat Transferring energy in the atmosphere.

Kinematic Structure of the WAFR Monsoon ATS mb NCEP Climatology Zonal Winds.

Meteorology Lecture 1 Weather and Climate Review.

Weather Review. Air Masses Air Mass – A large body of air through which temperature and moisture are the same. Types 1. Continental – formed over land.

HUMIDITY  Humidity is the amount of water vapor in the air. Water vapor is the gas phase of water and is invisible. Humidity indicates the likelihood.

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.

Climatic Controls: Water Bodies and Continents. How are water bodies and land masses connected? Water bodies provide sources of moisture for the land.

Biometeorology Lecture 2: Surface Energy Balance Professor Noah Molotch September 5, 2012.

ATM 301 Lecture #11 (sections ) E from water surface and bare soil.

17.1 Atmosphere Characteristics

Evapotranspiration Eric Peterson GEO Hydrology.

CE 374K Hydrology, Lecture 4 Atmosphere and Atmospheric water Energy balance of the earth Drought in Texas Atmospheric circulation Atmospheric water Reading.

Earth’s climate and how it changes

OEAS 604: Introduction to Physical Oceanography Surface heat balance and flux Chapters 2,3 – Knauss Chapter 5 – Talley et al. 1.

Photo: Pamela R. Cox 2013 Elizabethtown, Kentucky.

LACEMOP Factors that Shape Weather. Some Definitions Weather : a condition of the atmosphere in one place during a short period of time Climate : weather.

Kinetic Energy In The Atmosphere Kinetic Energy is the energy of motion Heat - the total kinetic energy of the atoms composing a substance (atmospheric.

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.

The Arctic boundary layer: Characteristics and properties Steven Cavallo June 1, 2006 Boundary layer meteorology.

Evaporation What is evaporation? How is evaporation measured?

Composition of the Atmosphere 14 Atmosphere Characteristics  Weather is constantly changing, and it refers to the state of the atmosphere at any given.

Water in the Atmosphere Chapter 18, Section 1. Water in the Atmosphere  Precipitation – any form of water that falls from a cloud  When it comes to.

Atmosphere-ocean interactions Exchange of energy between oceans & atmosphere affects character of each In oceans –Atmospheric processes alter salinity.

Latitudinal effects Intensity of insolation is not the same at all latitudes Earth is roughly spherical, so insolation passing through 1 m 2 screen –Illuminates.

Climate & Biomes. Weather Short term day to day changes in temperature, air pressure, humidity, precipitation, cloud cover, & wind speed Result of uneven.

Essentials of Oceanography, Thurman and Trujillo Chapter VI: Air-Sea Interaction.

0 The vertical structure of the open ocean surface mixed layer 11:628:320 Dynamics of Marine Ecosystems.

Hydrologic Losses - Evaporation

Surface Energy Budget, Part I

E from water surface and bare soil

Heat Transfer and the Movement of Air

Hydrologic Losses - Evaporation

Energy Budgets Some parts of the earth receive a lot of solar energy (surplus), some receive less (deficit). In order to transfer this energy around, to.

Sun Earth Sun: shortwave radiation Earth: longwave radiation.

3. Local winds and global winds are generally a result of which of the following? A). Earth’s tilted axis. B). Unpredictable changes in the atmosphere.

Presentation transcript:

Lake Superior Eddy Covariance Stannard Rock Light PI: Peter Blanken, CU-Boulder Reported by Ankur Desai DO NOT DISTRIBUTE

Micrometeorology Figure 1: General Meteorology. Air (blue lines) temperature and humidity greater than that at water surface (green lines) until roughly DOY 200 (July 18) indicating the lake is in a period of energy storage: gradients for sensible heat (temperature) and latent heat (vapor pressure) directed towards the water surface (water still quite cold). After DOY 200, however, note that the difference between lake and air vapor pressures decreases due to increasing water surface temperatures. Significant cooling and drying DOY Total rain = 98.5 mm.

Water surface Figure 2: 24-hr mean air (blue) and water surface (green) temperature and vapor pressure, and differences. The difference between air and water temperature is decreasing, as is the difference between air/water vapor pressure. The former results in a decrease in the downward sensible heat flux, while the latter results in an increase in the upwards latent heat flux..

Wind Rose Figure 3. Wind rose/intensity plot for all days, showing prevailing “calm” winds from the northwest, and now stronger, more persistent winds from the southeast

Wind Roses Figure 3a - LEFT. Wind rose/intensity plot for DOY = 220 (LE- active period).

Radiation Figure 4. Radiation balance (all in W m -2 ). Blue lines are downwards; green are upwards; except for net radiation. Most (nearly all) of the net radiation (which is large) is due to the incident short-wave radiation. Assuming an albedo of 0.07, the net short-wave is huge, and the net long-wave is small, so most of the net radiation is a result of the incident solar. At this time of the year, nearly all of the net radiation is used for lake heat storage (turbulent fluxes are small: see Figure 5). This is the exact same behavior Great Slave showed in June. Around DOY 200 (July 18), notice the decrease in net long-wave due to the steady increase in emitted long-wave (due to higher water surface temperatures: see Figure 2).

Energy Fluxes Figure hr mean energy balance (all in W m -2, except evaporative fraction). LE and H were small and often directed towards the surface in June (mean LE and H were and W m -2, respectively). Evaporative fraction was typically less than 1, indicating more H that LE. Lake was in a “heat storage mode”, with the large Rn around the summer solstice being used in an attempt to raise the temperature of the massive body of water. Looks like evaporation is beginning to “ramp up”: notice the evaporation event around DOY , and again around DOY 215, and recently DOY (intrusion of cold, dry air). Also notice the evaporative fraction, LE/(LE+H) is beginning to increase post DOY 210.

Wind and drag Figure 7. Relationship between U and u* (the slope is essentially the drag coefficient), indicating the difficulty of wind to deform the surface.

Evaporation Figure 9. For June (blue dots), E (total mm per day) was usually negative (condensation), and the water was so cold that the saturation vapor pressure was less that the ambient, making the x-axis values negative. Beginning late July-early August (red dots), as E became positive, you can see the mass transfer coefficient beginning to develop.

CO 2 flux Figure 10: Carbon dioxide concentration and flux. CO 2 concentration is decreasing as the growing season progresses. There was CO 2 uptake during the DOY event, and beyond – need to explore this to make sure it’s real.

E vs P Figure 11. Cumulative evaporation (92.8 mm). Before September 1 (DOY 245), a total of 14.8 mm. After September 1, mm; 91% of the evaporation has occurred after September 1. P = E on October 3 (~80 mm).