THE STUDY OF THE ENTIRE ATMOSPHERE, INCLUDING ITS WEATHER.

Slides:

Advertisements

Similar presentations

Advertisements

What is Weather?.

Using Weather Data Earth Science Unit II.

Earth’s Weather Patterns

GLOBAL CLIMATES & BIOMES

Earths Atmosphere.

WEATHER PATTERNS.

Ch Atmosphere Atmosphere – 99% Nitrogen and Oxygen

The atmosphere S6E4a: Demonstrate that land and water absorb and lose heat at different rates and explain the resulting effects on weather patterns.

Weather, Winds, and Fronts

Meteorology Part 2: Weather Variables

Topic VI “Meteorology”

Weather Dynamics Science 10 G.Burgess Our weather is dependant on the movements of air and water. Light from the sun heats the Earth and oceans.

Earth’s Weather and Climate

Air Pressure: The weight of the air in the atmosphere pressing down. At sea level the air pressure is mb (millibars) = 1 atmosphere 1 atmosphere.

Things we need to talk about: Astro Test When you can retake (By May 1!) Grades Tuesday 4/23/2012.

The Atmosphere Basic Structure.

Chapter 2 Section 3 Winds.

Weather Unit Foldable In the upper right hand corner write

What is weather? 1 Weather Factors

Moisture, Clouds, and Precipitation

Weather An Overview. Atmosphere b Is a mixture of the gasses that surround the Earth.  The atmosphere gives us the air we breath as well as protects.

Water in the Atmosphere Chapter 18. H 2 O exists in atmosphere in all three states of matter…

The study of weather = METEROLOGY The study of weather = METEROLOGY Weather is the condition of the atmosphere at any given time or place Weather is the.

Weather Factors Chapter Two. Energy in the Atmosphere Most energy from the sun reaches Earth in the form of visible light and infrared radiation, and.

Clouds and Humidity.

Atmosphere Chapter 11 Notes. Composition of the Atmosphere Currently: – Nitrogen (N 2 ): 78% – Oxygen (O 2 ): 21% – Argon (Ar) – Carbon dioxide (CO 2.

Energy of the Atmosphere Sun – 98% of the energy in Earth’s atmosphere comes from the sun in the form of electromagnetic waves. Radiation – is the direct.

the state of the atmosphere at a given time and place depends on: amount of cloudstemperature air pressurewind amount of moisture.

Earth’s Atmosphere and Weather. The earth has layers on the inside and layers on the outside, aka the atmosphere. From the outside in: Thermosphere -

11.1 Atmospheric Basics atmosphere.

Weather Patterns.

EARTH SCIENCE Prentice Hall EARTH SCIENCE Tarbuck Lutgens 

Air and Weather Chapter 9 and 10. Atmosphere ► 5 layers: ► 1. Troposphere – area closest to the ground, 75%of the gases, dust, ice and liquid water-Weather,

Energy in the Atmosphere Energy from the sun travels to Earth as electromagnetic waves – mostly visible light, infrared radiation (longer wavelengths)

The Atmosphere © Lisa Michalek.

Chapter 18 The Atmosphere. Earth’s Atmosphere Made of a mixture of lots of gases 79% 21%

Weather. What is weather? The condition of the air (or atmosphere) at a given location at a give time.

Weather. Atmosphere and Air Temperature insolation – the amount of the Sun’s energy that reaches Earth at a given time and place insolation – the amount.

Atmosphere. Composition of the Earth’s Atmosphere The is a mixture of gases with some suspended solids and liquids. The atmosphere is a mixture of gases.

EARTHS SYSTEMS. ATMOSPHERE Invisible layers of air primarily made up of Nitrogen (75%), Oxygen (20.9%), and Argon (.9%) gases.

Weather Chapter 1: Section 1 The Atmosphere Weather is the condition of Earth’s atmosphere at a particular place and time. Atmosphere: layer of gases that.

Surface Condensation Water vapor condensing on large surfaces is called dew. Dew Point is the temperature that saturation occurs and condensation begins.

Warm Up 1. At 25 0 C, air contains 15 gH 2 O / m 3 air. Saturation point: 20 g/m 3 Calculate the relative humidity. 2. What is the dry adiabatic rate?

by Brent Rivenbark and Rosalind Byrd

Weather Factors Chapter 12 SOL 6.3. Energy from the sun travels in electromagnetic waves. Energy from the sun travels in electromagnetic waves. Radiation=

Define the following vocabulary words: can be found in ch

Understanding Weather

Earth’s Energy Budget. Modes of Energy Travel Heat Energy can be transferred in three specific ways: Heat Energy can be transferred in three specific.

Chapter 15 The Atmosphere Mr. Manskopf Notes Also At

Weather Brain Pop Weather. What is Weather? Weather is the condition of Earth’s atmosphere from day to day. Earth’s atmosphere is the envelope of gases.

Weather. Atmosphere and Air Temperature insolation – the amount of the Sun’s energy that reaches Earth at a given time and place insolation – the amount.

Earth’s Atmosphere And Weather. Composition of the Atmosphere 78% nitrogen: little effect on weather 21% oxygen: component necessary for human life Argon:

Earth’s Atmosphere And Weather. Composition of the Atmosphere 78% Nitrogen 21% Oxygen 0.9% Argon 0.04% Carbon Dioxide Water Vapor 0 – 4% % Ozone.

Weather refers to the state of the atmosphere at a specific time and place. Weather describes conditions such as air pressure, wind, temperature, and.

Importance of the Atmosphere Earth's atmosphere is a mixture of gases that surrounds Maintains balance of heat Protects life forms from sun’s rays 1 1.

Chapter 18 Evaporation, Condensation, and Precipitation.

Meteorology Earth’s Atmosphere Weather and Climate.

Atmosphere Notes. The Atmosphere The Earth's atmosphere is a thin layer of gases that surrounds the Earth. It composed of 78% nitrogen 21% oxygen 0.9%

Chapter 11 The Atmosphere

Ch Atmosphere Atmosphere – 99% Nitrogen and Oxygen

Weather: Chapter 14 Sec 14.1 Meteorology Meteorologist

Seasons and Atmosphere

Seasons and Atmosphere

Weather Terms/ Tools Meteorology Meteorologist Forecast Mass

Presentation transcript:

THE STUDY OF THE ENTIRE ATMOSPHERE, INCLUDING ITS WEATHER

AIR IS A MIXTURE OF MANY GASES IN EARTH’S LOWER ATMOSPHERE NITROGEN AND OXYGEN TOGETHER FORM ABOUT 99% OF DRY AIR BY VOLUME THE REMAINING 1 % IS MAINLY ARGON AND CARBON DIOXIDE

TROPOSPHERE- IS THE LOWEST LAYER OF THE ATMOSPHERE (0-12 km) IN WHICH ALL OF EARTH’S WEATHER OCCURS. THE JET STREAM IS LOCATED BETWEEN 6-12 km. GRADUALLY DECREASES IN TEMP. WITH AN INCREASE IN ALTITUDE. CONTAINS ALL WATER VAPOR.

TROPOPAUSE-THE TOP OF THE TROPOSPHERE WHERE THE DECREASE IN TEMP. STOPS STRATOSPHERE- REACHES FROM THE TROPOPAUSE TO ABOUT 50 KM ABOVE EARTH STEADY WINDS AND FEW WEATHER CHANGES (PLANES FLY HERE!) STEADY INCREASE IN TEMP. WITH THE INCREASE OF ALTITUDE, WHICH IS CAUSED BY ABSORPTION FROM THE OZONE

STRATOPAUSE- THE TOP OF THE STRATOSPHERE WHERE THE TEMP. STOPS RISING. MESOSPHERE- TEMPERATURE DROPS AGAIN THERMOSPHERE- TEMPERATURE RISES AGAIN ABOUT 500 KM FROM EARTH OZONE – ULTRAVIOLET RAYS MAKE OXYGEN O3. THE OZONE LAYER ABSORBS SUN’S UV RAYS AND PROTECTS US FROM BURNING.

WEATHER- IS THE STATE OF THE ATMOSPHERE AT A GIVEN TIME AND PLACE TO TRY TO PREDICT WEATHER YOU NEED TO OBSERVE THE CLOUDS, WIND, TEMP., HUMIDITY, AIR PRESSURE AND PRECIPITATION OVER A PERIOD OF TIME.

ENERGY FROM THE SUN RESULTS IN CHANGES IN THE WEATHER. HEAT MOVES THROUGH THE ATMOSPHERE IN THREE WAYS CONDUCTION- AN OBJECT RECIEVES HEAT WHEN IT COMES INTO CONTACT WITH A HOTTER OBJECT. (EX. A PAN ON A HOT STOVE)

RADIATION- HOT BODIES RADIATE ENERGY IN SHORT WAVES (SUN); COLD BODIES RADIATE ENERGY IN LONGER WAVES (EARTH) CONVECTION- MOST EFFECTIVE; THE RISING OF HOT AIR AND SINKING OF COLD AIR RESULTS IN A STEADY FLOW. CONVECTION IS VERY IMPORTANT IN MOVING HEAT THROUGH THE ATMOSPHERE.

SOLAR ENERGY THAT REACHES THE EARTH; WE RECIEVE ONE TWO- BILLIONTH OF THE SUN’S RAYS

SHORT ULTRA VIOLET WAVES FROM THE SUN ARE ABLE TO REACH THE EARTH’S SURFACE, THEN LONGER INFRARED WAVES RE-RADIATED BY THE EARTH’S SURFACE ARE TRAPPED BY GREENHOUSE GASSES. (CFC’S AND CO2)

NORMAL LAPSE RATE – THE RATE OF COOLING WITH ALTITUDE (1  C FOR EVERY 160 METERS) TEMPERATURE INVERSION - WHEN THE AIR IS ESPECIALLY STILL COOLER AIR, BECAUSE OF ITS GREATER DENSITY, SETTLES CLOSE TO THE GROUND, AND THE WARMER AIR FORMS A BLANKET ABOVE IT IN A TEMPERATURE INVERSION. POLLUTANTS IN THE AIR, SUCH AS SMOKE AND SOOT, ARE ALSO TRAPPED CLOSE TO THE GROUND.

THE AMOUNT OF HEAT REQUIRED TO RAISE THE TEMP. OF SOMETHING 1ºC ** WATER HAS A HIGH SPECIFIC HEAT COMPARED TO SOIL. **

TO TAKE IN ENERGY AND HEAT UP. TO BOUNCE BACK ENERGY. TO ABSORB SHORT WAVE ENERGY AND GIVE OFF LONG WAVE ENERGY.

GOOD ABSORBERSPOOR ABSORBERS DARK-COLORED LIGHT COLORED ROUGH SURFACE SMOOTH SURFACE DRY SOIL WET SOIL

IN WATER, THE SUN’S RAYS GO TO A DEPTH OF MANY METERS. ON LAND, THE SUN’S RAYS HEAT ONLY THE TOP FEW CENTIMETERS OF SOIL WHICH HEATS UP FASTER??

WATER CAN SPREAD HEAT EASILY BECAUSE IT IS A FLUID SOME SOLAR ENERGY IS USED IN THE PROCESS OF EVAPORATION. THUS, LESS SOLAR ENERGY IS AVAILABLE TO RAISE THE TEMPERATURE OF THE WATER.

WATER COOLS MORE SLOWLY THAN LAND BECAUSE ITS HEAT IS SPREAD THROUGH A GREATER DEPTH

TEMPERATURE IS A MEASURE OF THE ENERGY OF MOLECULES. THE MORE ENERGY THE MOLECULES IN AIR HAVE, THE HOTTER IT FEELS. TEMPERATURE IS MEASURED IN DEGREES (CELSIUS, FAHRENHEIT, KELVIN)

THERMOMETERS ARE THE INSTRUMENTS USED TO MEASURE TEMPERATURE THE ALCOHOL EXPANDS WHEN HEATED THERMOGRAPHS ARE SELF-RECORDING THERMOMETERS

ISOTHERMS ARE LINES DRAWN ON MAPS CONNECTING PLACES WITH THE SAME TEMPERATURE

THE CHANGE FROM LIQUID WATER TO WATER VAPOR WATER VAPOR IS SPREAD THROUGHOUT THE TROPOSPHERE BY CONVECTION CURRENTS AND WINDS.

THE CAPACITY OF AIR FOR HOLDING WATER VAPOR AS AIR TEMPERATURE INCREASES SO DOES THE AMOUNT OF WATER VAPOR IT CAN HOLD SPECIFIC HUMIDITY- THE AMOUNT OF WATER VAPOR ACTUALLY PRESENT IN THE AIR.

RELATIVE HUMIDITY- COMPARES THE ACTUAL AMOUNT OF WATERVAPOR IN THE AIR(SPEC. HUMIDITY) WITH THE MAXIMUM AMOUNT OF WATER VAPOR THE AIR CAN HOLD AT THAT TEMPERATURE PSYCHROMETER- IS THE INSTRUMENT USED TO DETERMINE RELATIVE HUMIDITY

THE CHANGE FROM WATER VAPOR TO A LIQUID. THIS OCCURS WHEN THE TEMPERATURE DROPS LOW ENOUGH THAT THE CAPACITY FOR WATER VAPOR IN THE AIR DROPS BELOW THE SPECIFIC HUMIDITY.

DEW- WATER VAPOR WHICH CONDENSES ON SURFACES, SUCH AS GRASS, IN THE FORM OF A LIQUID. DEW POINT- TEMPERATURE AT WHICH SATURATION OCCURS. CLOUDS OR FOGS- FORM WHEN THE WATER VAPOR CONDENSES INTO DROPLETS

AIR MAY BE COOLED BELOW ITS DEW POINT IN MANY WAYS: CONTACTING A COLDER SURFACE RADIATING HEAT MIXING WITH COLDER AIR EXPANDING WHEN IT RISES

WATER VAPOR NEEDS TO CONDENSE ON SOMETHING!! CONDENSATION NUCLEI- TINY PARTICLES, SUCH AS SALT, SULFATE, OR NITRATE PARTICLES, ON WHICH WATER VAPOR CONDENSES WHEN COOLING OCCURS BY CONTACT WITH A COLDER SURFACE, THE WATER VAPOR CONDENSES DIRECTLY ON THAT SURFACE >0  C = DEW <0  C = FROST

SURFACE LAYERS OF AIR A FEW HUNDRED METERS THICK WHICH ARE COOLED BELOW THE DEW POINT. AS WATER VAPOR CONDENSES TINY DROPLETS STAY SUSPENDED IN THE AIR BY THE LIGHTEST AIR MOVEMENT.

RADIATION FOGS - AT NIGHT THE GROUND LOSES HEAT RAPIDLY. LIGHT WINDS MIX THE COLD BOTTOM AIR WITH THE AIR A SHORT DISTANCE FROM THE SURFACE. WHEN THE WHOLE LAYER OF AIR IS COOLED BELOW THE DEW POINT, A FOG FORMS. (COMMON IN HUMID VALLEYS AND NEAR RIVERS AND LAKES)

ADVECTION FOGS – RESULT WHEN WARM, MOIST AIR BLOWS OVER COOL SURFACES (EX. COASTAL CALIFORNIA)

CLOUDS FORM WHEN AIR ABOVE THE SURFACE COOLS BELOW THE DEW POINT

IS THE FALLING OF ANY FORM OF WATER FROM THE AIR TO THE EARTH’S SURFACE. OCCURS WHEN CLOUD DROPLETS GROW INTO DROPS HEAVY ENOUGH TO FALL TO EARTH.

RAINDROPS FORM FROM TINY DROPLETS AND THEN GROW BY BUMPING INTO AND COMBINING WITH OTHER DROPLETS. SLEET FORMS WHEN RAINDROPS FALL THROUGH THE FREEZING AIR AND FALL TO THE GROUND AS PELLETS OF ICE HAILSTONES BEGIN AS A FROZEN RAINDROP AND GROWS BY COLLECTING SMALLER ICE PARTICLES OR LIQUID CLOUD DROPLETS ACID RAIN FORMS WHEN WATER CONDENSES ON SULFATE AND NITRATE

THE WEIGHT OF THE ATMOSPHERE PER UNIT AREA **PRESSURE DECREASES WITH ALTITUDE**

IS AN INSTRUMENT USED TO MEASURE AIR PRESSURE MEASURES PRESSURE WITH A THIN METAL CAN

MILLIBAR- IS A METRIC UNIT OF PRESSURE **STANDARD SEA-LEVEL PRESSURE IS MB ** ISOBAR – LINES THAT JOIN POINTS HAVING THE SAME AIR PRESSURE AT A GIVEN TIME EACH LINE IS WORTH 4 MB

HIGH PRESSURE AREA (HIGH) – THE AREA OF THE LARGEST PRESSURE. THE PRESSURE IN A HIGH IS GREATER THAN THE SURROUNDING AIR LOW PRESSURE ARE (LOW) – THIS AREA HAS LOWER PRESSURE THAN THE SURROUNDING AREA PRESSURE GRADIENT – THE RATE OF CHANGE FOR AIR PRESSURE BETWEEN TWO POINTS

RISING BAROMETER - GREATER PRESSURE USUALLY MEANS COOLER, DRIER WEATHER (SINKING AIR) FALLING BAROMETER – LESS PRESSURE BECAUSE THE AIR IS WARM AND MOIST AND RISES. THIS CAN BE A SIGN OF PRECIPITATION

THE HORIZONTAL MOVEMENT OF AIR FROM AREAS OF HIGH AIR PRESSURE TO AREAS OF LOW AIR PRESSURE. THE CLOSER THE SPACING BETWEEN ISOBARS THE STRONGER THE WINDS WINDS BLOW ACROSS ISOBARS, FROM HIGH TO LOW AIR PRESSURE.

WIND FLOWS FROM HIGH PRESSURE AT THE POLES TO LOW PRESSURE AT THE EQUATOR THE WIND IS DEFLECTED BY THE EARTH’S ROTATION, CALLED THE CORIOLUS EFFECT

AN AIR MASS IS A HUGE SECTION OF THE LOWER TROPOSPHERE THAT HAS THE SAME KIND OF WEATHER (TEMPERATURE AND MOISTURE PROPERTIES) THROUGHOUT THE BEST SOURCE REGIONS FOR AIR MASSES ARE LARGE FLAT AREAS WHERE AIR CAN BE STAGNANT LONG ENOUGH TO TAKE ON THE CHARACTERISTICS OF THE SURFACE BELOW

AIR MASSES ARE NAMED FROM THEIR SOURCE REGION AIR MASSES HAVE TWO CHARACTERISTICS: TEMPERATURE DEPENDS ON WHETHER IT COMES FROM THE TROPICS OR POLAR REGIONS THE HUMIDITY OF THE AIR MASS DEPENDS ON WHETHER IT COMES FROM LAND OR SEA c - CONTINENTAL T – TROPICAL m – MARITIME P – POLAR A - ARCTIC

BOUNDARIES BETWEEN AIRMASSES ARE CALLED FRONTS

1) COLD AIR IS ADVANCING AND REPLACING WARM AIR 2) COLD FRONTS ARE STEEPER AND MOVE FASTER THAN WARM FRONTS 3) THE AIR RISES UPWARD RAPIDLY FORMING CUMULONIMBUS

5) PRECIPITATION COVERS 75 – 100 MILES AND OCCURS BOTH BEFORE AND AFTER A COLD FRONT PASSES AT THE SURFACE 6) COLD FRONTS TRAVEL AT SPEEDS BETWEEN MPH 4) HEAVY PRECIPITATION AND THUNDERSTORMS WHICH START AND END QUICKLY ARE ASSOCIATED WITH COLD FRONTS

7) AS SOON AS THE FRONT PASSES THE TEMPERATURE WILL DECREASE AND THE WIND SPEED MAY RISE. The Weather Channel Map Symbol

1) WARM AIR IS ADVANCING AND REPLACING COLD AIR 2) WARM FRONTS MOVE SLOWER; WARM AIR MOVES UP A GENTLE FRONTAL SURFACE 3) WARM AIR MAY TRAVEL 1000 KM BEFORE RISING 2 OR 3 KM

4) FIRST CIRRUS AND CIRROSTRATUS CLOUDS FORM AND THEN THERE ARE ALTOSTRATUS CLOUDS. FINALLY, STEADY RAIN FALLS FROM NIMBOSTRATUS CLOUDS 5) PRECIPITATION CAN OCCUR FOR 225 – 275 MILES AHEAD OF WHERE THE FRONT TOUCHES THE GROUND

6) WARM FRONTS TRAVEL AT SPEEDS BETWEEN 20–25 MPH 7) WARMER TEMPERATURES FOLLOW THE PASSING WARM FRONT The Weather Channel

1.) A COLD FRONT IS ADVANCING AND COMBINING WITH A WARM FRONT 2.) OCCLUDED FRONTS MOVE THE SLOWEST OF ALL (20 MPH) 3.) THESE FRONTS ARE ASSOCIATED WITH CIRRUS AND STRATUS CLOUDS IN FRONT OF NIMBOSTRATUS AND CUMULONIMBUS CLOUDS

4.) PRECIPITATION OCCURS FOR ABOUT 400 MILES, MOST OF WHICH IS IN FRONT OF THE FRONTAL BOUNDARY 5.) COOL AIR IS IN FRONT, AS WARM AIR IS FORCED UP BY THE COLD AIR WHICH FOLLOWS THE PASSING OCCLUDED FRONT