Presentation is loading. Please wait.

Presentation is loading. Please wait.

Climate & Climatic Variation (Chapter 2). CLIMATE = 1. Statistics of Weather Daily Precipitation - Iowa/Nebraska.

Published byAlison Greer Modified over 9 years ago

Similar presentations

Presentation on theme: "Climate & Climatic Variation (Chapter 2). CLIMATE = 1. Statistics of Weather Daily Precipitation - Iowa/Nebraska."— Presentation transcript:

1 Climate & Climatic Variation (Chapter 2)

2 CLIMATE = 1. Statistics of Weather Daily Precipitation - Iowa/Nebraska

3 CLIMATE = 1. Statistics of Weather 2.The expected weather + departures from expected weather

4 CLIMATE Reflects the geophysical processes active at a location…

5 Northeastern Siberia

6 Namibia

7 Amazon Rainforest

8 CLIMATE = …and how they might change (e.g., seasonally)… Winter Daily Precipitation - Iowa/Nebraska

9 CLIMATE = Summer Daily Precipitation - Iowa/Nebraska …and how they might change (e.g., seasonally)…

10 … and in the future! (and of course the past)

11 CLIMATE 1.Implies samples over a period of time. How long? How frequent? 2. WMO standard: 30 years -which 30? -paleoclimate? 3. There is no universal standard, but must define the interval for the topic at hand

12 CLIMATE 1.Has regular cycles …

13 Cycles - Net Radiation F SH F LH - Net Radiation F SH Grassland Dry Lake Diurnal

14 Cycles Annual Soil Temperature at depths marked

15 CLIMATE 1.Has regular cycles … 2.… with other types of variability superimposed …

16 Climatic Variation and Change (IPCC TAR, Ch. 2) Note: Trends, Abrupt Change, Stationarity

17 Climatic Variation and Change (IPCC TAR, Ch. 2) Note: Quasi-periodic Increased range of variability

18 Climatic Variation and Change Additional Factors 1.Abrupt change -external conditions (e.g., solar output) -internal feedbacks -passing a threshold (e.g. ice caps melting) 2. Multiple climate states from the same external conditions

19 The Climate System (IPCC TAR, Ch. 1)

20 The Climate System (IPCC TAR, Ch. 1)

21 The Climate System Three important controling factors: 1.Latitude - insolation - insolation 2.Elevation - temp. decrease with height 3.Closeness to oceans - heat reservoir

22 The Climate System (Peixoto & Oort, 1992) Water in the climate system:

23 The Climate System

24 Mean extreme temperatures and differences (˚C) : Northern Hemisphere 8.0 (Jan) 21.6 (Jul) 13.6 Southern Hemisphere 10.6 (Jul) 16.5 (Jan) 6.5 Globe 12.3 (Jan) 16.1 (Jul) 3.9

25 Thermal Inertia of Oceans Annual Temperature Range (Wallace & Hobbs, 1979)

26 The Climate System ( Michael Pidwirny, DLESE, 2004)

27 The Climate System Subsystems 1.Atmosphere - rapid changes - links other subsystems - greenhouse gases 2.Ocean -slow evolution (“memory”, “flywheel”) -chemical role, esp. CO 2 3.Land - range of time scales - cryosphere & biosphere roles - location of continents

28 Cryosphere Area (10 6 km 2) Sea-lev. equiv. (m) Max extent (%) Min extent (%) N.H. Land snow & ice 2.2 (Grnl: 1.7) 7.8 Sea ice 8.9 Total11.024 % (Feb)4 % (Aug) S.H. Land snow & ice 13.0 (Antr: 13) 73.5 Sea ice 4.2 Total17.213 % (Oct)7 % (Feb) Note: Time scales, albedo effects

29 Biosphere Note: albedo, evapotranspiration, surface roughness, gas exchanges (esp. CO 2 )

30 Feedbacks Internal couplings through linking processes Amplify or diminish initial induced climate change

31 Negative Feedback: Example How does Earth’s temperature get established and maintained?

32 Solar Constant At photosphere surface, solar flux ~ 6.2. 10 7 W-m -2

33 Solar Constant At Earth’s orbit, solar flux ~ 1360 W-m -2 At photosphere surface, solar flux ~ 6.2. 10 7 W-m -2

34 Planetary Albedo Scattering: air molecules, aerosols Reflection: clouds Surface albedo

35 What is Earth’s temperature? Balance: Radiation in = Radiation out Incoming = 1360 W-m -2 x (1-albedo) x (area facing sun) = 1360 x (1-0.3) x  a 2 = 1.2. 10 +17 W a

36 What is Earth’s temperature? Balance: Radiation in = Radiation out Incoming = 1360 W-m -2 x (1-albedo) x (area facing sun) = 1360 x (1-0.3) x  a 2 = 1.2. 10 +17 W a Outgoing =  T 4 x (area emitting) ; i.e., black body =  T 4 x 4  a 2

37 What is Earth’s temperature? Balance: Radiation in = Radiation out Incoming = 1360 W-m -2 x (1-albedo) x (area facing sun) = 1360 x (1-0.3) x  a 2 = 1.2. 10 +17 W a Balance implies T = {0.7  1360 W-m -2 )/4  } 1/4 = 255 K = -18 o C Outgoing =  T 4 x (area emitting) ; (i.e., black body) =  T 4 x 4  a 2

38 What is Earth’s temperature? Balance: Radiation in = Radiation out Difference? Must account for atmosphere (greenhouse effect). a Balance implies T = -18 o C Balance implies T = -18 o C Observed surface T = +15 o C

39 What if temperature decreases? The same: Incoming = 1.2. 10 +17 W Outgoing =  T 4 x (area emitting) =  T 4 x 4  a 2 a

40 What if temperature decreases? ~ Negative Feedback ~ These are the same: Incoming = 1.2. 10 +17 W Outgoing =  T 4 x (area emitting) =  T 4 x 4  a 2 a But for T < 255 K:  imbalance  Incoming solar exceeds outgoing IR  net energy input  T increases

41 Negative Feedback 1.Perturb climate system 2.Negative feedback moves climate back toward starting point 3.A stabilizing factor

42 Positive Feedback: Example How does Earth’s temperature get established and maintained?

43 Greenhouse Effect IR radiation absorbed & re-emitted, partially toward surface Solar radiation penetrates

44 Greenhouse Effect IR radiation absorbed & re-emitted, partially toward surface Emitted IR: ~200-500 W-m Net IR: ~25-100 W-m

45 Greenhouse Effect Cooler atmosphere: - Less water vapor - Less IR radiation absorbed & re-emitted Solar radiation penetrates

46 Greenhouse Effect Cooler atmosphere: - thus less surface warming - cooler surface temperature Solar radiation penetrates

47 Positive Feedback 1.Perturb climate system 2.Positive feedback moves climate away from starting point 3.A destabilizing factor Other examples (textbook): - ice-albedo feedback - CO 2 -ocean temperature feedback

48 Feedbacks Distinguish between: 1. external forcing change - e.g., insolation, volcanism - often predictable 2. Internal feedback mechanisms - nonlinear, coupled interactions - generally less predictable (stochastic)

49 Black Body Curves 6,000 K 255 K Emission Wavelength [  ] Solar (shortwave, visible) Terrestrial (longwave, infrared) Radiation Spectrum

50 Daily Solar Radiation at Top of Atmos. [10 6 J-m -2 ]

51 Earth’s mean annual radiation and energy balance

52 Absorbed Solar Radiation

53 Outgoing Terrestrial Radiation

54 Key Energy Fluxes at Surface Sensible Heat T air F SH =  C p (wT) s F SH ≈ -  C p C H (T air -T s ) C H = C H (V, z o, d  /dz) TsTs

55 Surface Sensible Heat Flux (Peixoto & Oort, 1992)

56 Latent Heat F LH ~ -  C p C W {e air -e sat (Ts)} C W = C W (V, z o, d  /dz) but also C W = C W (physiology) soil moisture C W  leaf temp. sunlight CO 2 level Key Energy Fluxes at Surface

57 Surface Evaporation (Peixoto & Oort, 1992)

58 Cycles - Net Radiation F SH F LH - Net Radiation F SH Grassland Dry Lake Diurnal  Less cooling by evaporation  T s increases  F SH larger

59 Role of Albedo Scattering: air molecules, aerosols Reflection: clouds Surface albedo Ocean 2-6% Snow 40-95% Crop 15-25% Forest 5-10% Cities 14-18%

60 Role of Albedo Albedo changes with latitude - changing land surface - changes in incidence angle Albedo changes with time - land changes (e.g., ice sheets) - cloud cover

61 Role of Albedo Albedo changes with latitude

62 Role of Greenhouse Gases Primary gases: water vapor, CO 2, methane (CH 4 ), nitrous oxide (N 2 O), ozone (O 3 )

63 Time Scales of Climatic Variation (IPCC TAR, Ch. 2) Note: Magnitude of changes Reduced “detectability” farther back in time

64 (IPCC TAR, Ch. 2) Different size of changes Time Scales of Climatic Variation

65

66

67 Earth’s Orbital Parameters Perihelion (~ Jan 3) Vernal Equinox (~ March 21) Aphelion (~ July 5)

68 Earth’s Orbital Parameters Eccentricity = SQRT(a 2 - b 2 )/a ; for circle, = 0 Longitude of perihelion (one choice: angle from NH vernal equinox) Tilt of rotation axis (obliquity) b a

69 Variability of Earth’s Orbital Parameters

70 Earth’s Orbital Parameters Periodic variations CurrentRange~ Period (yr.) Eccentricity: ~ 0.02[0.0 - 0.05]95,800 Longitude of perihelion ~ 270˚[0˚ - 360˚]21,700 Obliquity 23.4˚[21.8˚ - 24.4˚]41,000 b a

71 Earth’s Orbital Parameters Seasonal efffect of variations (little annual effect) Eccentricity: intensity of seasons Longitude of perihelion NH-SH differences in summer insolation Obliquityextratropical summer-winter differences b a

72 Variability of Earth’s Orbital Parameters

73 Changes in Earth’s Orbit Some paleo-records can resolve different frequencies in an orbital element’s variability (e.g., 19,000 and 23,000 yr periods in precession). Some can detect “beat” frequencies. Relative importance of frequencies changes with time - and may not correspond to dominant frequencies in climatic response. Shorter, lower amplitude frequencies might be important for decadal-millenial climate changes.

74 Changes in Earth’s Orbit Changes in Earth’s orbit affect - annual insolation cycle - past glacial-interglacial variability Croll (late 1800s) Milankovitch (1941) Berger (1970s)

75 Changes in Earth’s Orbit Changes in Earth’s orbit affect - annual insolation cycle - past glacial-interglacial variability Optimum conditions: minimum obliquity, high eccentricity, aphelion during NH summer - allow snow to persist through summer - allow relatively warm winter (increased subtropical evap. & increased snowfall) - transition seasons may also be important for snow-cover expansion

76 Variability of Earth’s Orbital Parameters

77 Milankovitch Theory

78 Global RegionalRegionalRegionalRegional MicroscaleMicroscaleMicroscaleMicroscaleMicroscaleMicroscaleMicroscaleMicroscaleMicroscale Plant A Crop BCrop A Insect A Soil Pathogen B Air-Transported Pathogen A FieldFieldFieldFieldFieldFieldFieldFieldFieldField RegionalRegionalRegionalRegional Continental Hydrology, Soil Microbiology, Soil Biochemistry Soil A H 2 O, temperature, nutrients, microbes, soil carbon, trace chemicals Soil A H 2 O, temperature, nutrients, microbes, soil carbon, trace chemicals Soil B H 2 O, temperature, nutrients, microbes, soil carbon, trace chemicals Soil B H 2 O, temperature, nutrients, microbes, soil carbon, trace chemicals Soil C H 2 O, temperature, nutrients, microbes, soil carbon, trace chemicals Scales of Climate Scales of Landforms Soil Pathogen D Plant B Insect B Air-Transported Pathogen B Human Influences Management Chemical s Erosion Chemical s Surface slope, IR Radiation, Evaporation, Biogeochemicals Detritus Particulate Deposition, Precipitation, Solar Radiation, IR Microclimate A Solar, IR, wind, CO 2, CO, NO x,SO 2, H 2 O, temperature, trace gases, shading, particulate matter Solar, IR, wind, CO 2, CO, NO x,SO 2, H 2 O, temperature, trace gases, shading, particulate matter Solar, IR, wind, CO 2, CO, NO x,SO 2, H 2 O, temperature, trace gases, shading, particulate matter Microclimate CMicroclimate B Chemical s

79 Climate & Climatic Variation (Chapter 2) END

Download ppt "Climate & Climatic Variation (Chapter 2). CLIMATE = 1. Statistics of Weather Daily Precipitation - Iowa/Nebraska."

Similar presentations

The Earth’s Energy Budget Chapter 3 Objectives Trace the flow of energy through the atmosphere.

The Earth’s Energy Budget Chapter 3 Objectives Trace the flow of energy through the atmosphere.
Seasons.

Seasons.
The Atmosphere, Climate, and Global Warming

The Atmosphere, Climate, and Global Warming
Earth’s Global Energy Balance Overview

Earth’s Global Energy Balance Overview
Temperature and Its Variation

Temperature and Its Variation
Seasonal & Diurnal Temp Variations ATS351 Lecture 3.

Seasonal & Diurnal Temp Variations ATS351 Lecture 3.
Why the Earth has seasons  Earth revolves in elliptical path around sun every 365 days.  Earth rotates counterclockwise or eastward every 24 hours.

Why the Earth has seasons  Earth revolves in elliptical path around sun every 365 days.  Earth rotates counterclockwise or eastward every 24 hours.
Greenhouse Effect. Thermal radiation Objects emit electromagnetic radiation –The hotter they are, the faster the energy output (  T 4 ) –The hotter they.

Greenhouse Effect. Thermal radiation Objects emit electromagnetic radiation –The hotter they are, the faster the energy output (  T 4 ) –The hotter they.
Energy Input: Solar Radiation decreases poleward reduced in areas of frequent cloud total energy input to atmosphere highest at equator, but highest insolation.

Energy Input: Solar Radiation decreases poleward reduced in areas of frequent cloud total energy input to atmosphere highest at equator, but highest insolation.
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)
The dominant periodicities are the same as those from astronomical calculations of changes in the Earth’s orbital parameters.

The dominant periodicities are the same as those from astronomical calculations of changes in the Earth’s orbital parameters.
Global Warming 101 Huge Amount in the Media on this Issue.

Global Warming 101 Huge Amount in the Media on this Issue.
CLIMATE CHANGE Global Temperatures: Past, Present, and Future.

CLIMATE CHANGE Global Temperatures: Past, Present, and Future.
Visualizing Physical Geography Copyright © 2008 John Wiley and Sons Publishers Inc. Chapter 3 Air Temperature.

Visualizing Physical Geography Copyright © 2008 John Wiley and Sons Publishers Inc. Chapter 3 Air Temperature.
Chapter 3. Why the Earth has seasons  Earth revolves in elliptical path around sun every 365 days.  Earth rotates counterclockwise or eastward every.

Chapter 3. Why the Earth has seasons  Earth revolves in elliptical path around sun every 365 days.  Earth rotates counterclockwise or eastward every.
Last Class – Global What transformations occur as energy flows through the earth system. Relationship between distance from the source and amount of energy.

Last Class – Global What transformations occur as energy flows through the earth system. Relationship between distance from the source and amount of energy.
Essential Principles Challenge

Essential Principles Challenge
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.

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.
CHAPTER 5. * Weather is daily changes in temp and precipitation. * CLIMATE is the average year to year conditions.

CHAPTER 5. * Weather is daily changes in temp and precipitation. * CLIMATE is the average year to year conditions.
Climate Change UNIT 3 Chapter 7: Earth’s Climate System

Climate Change UNIT 3 Chapter 7: Earth’s Climate System

Similar presentations

Ads by Google