Weather

Weather Systems

Understanding Atmospheric Circulation and Weather Patterns

CAPS Grade 10 Geography

Note:

This topic forms part of the CAPS-aligned Grade 10 Geography curriculum, focusing on weather systems, atmospheric circulation, and weather prediction techniques.

Overview Curriculum Overview

Weather systems are large-scale patterns of atmospheric circulation that influence weather conditions over particular areas. Understanding these systems is crucial for predicting weather patterns and preparing for extreme weather events.

Key Concepts

Atmospheric Pressure Wind Systems Cyclones Weather Maps Frontal Systems Extreme Weather

Meteorology Basic Meteorological Concepts

Atmospheric Pressure

High & Low

High Pressure (Anticyclones): Descending air, clear skies, stable conditions
Low Pressure (Cyclones): Rising air, cloud formation, unsettled weather
Measurement: Millibars (mb) or hectopascals (hPa)
Instrument: Barometer

Temperature Systems

Gradients

Temperature Gradient: Rate of temperature change over distance
Environmental Lapse Rate: 6.5°C decrease per 1000m altitude
Diurnal Range: Difference between daily max and min temperatures
Instrument: Thermometer

Humidity & Precipitation

Moisture

Humidity: Amount of water vapor in air
Dew Point: Temperature at which condensation occurs
Precipitation Forms: Rain, snow, hail, sleet, drizzle
Instrument: Hygrometer, Rain Gauge

Wind Systems

Air Movement

Causes: Pressure gradients, Coriolis effect, friction
Measurement: Direction and speed (knots or km/h)
Global Winds: Trade winds, westerlies, polar easterlies
Instrument: Anemometer, Wind Vane

Instruments Weather Instruments & Maps

Thermo

Thermometer

Measures air temperature

Temperature

Baro

Barometer

Measures atmospheric pressure

Pressure

Anemo

Anemometer

Measures wind speed

Wind

Vane

Wind Vane

Measures wind direction

Wind

Rain

Rain Gauge

Measures precipitation

Precipitation

Hygro

Hygrometer

Measures humidity

Moisture

Weather Map Interpretation

Isobars

Lines connecting points of equal pressure

Close isobars = strong winds

Isotherms

Lines connecting points of equal temperature

Show temperature gradients

Front Symbols

Lines showing frontal boundaries

Triangles = cold front, semicircles = warm front

Pressure Systems

H (High) and L (Low) markers

H = clockwise rotation in SH, L = anticlockwise

Pressure High & Low Pressure Systems

High Pressure (Anticyclone)

Characteristics

Air Movement: Descending, diverging at surface
Rotation: Clockwise in Southern Hemisphere
Weather: Clear skies, stable conditions
Formation: Cooling and sinking of air

Associated Weather

Sunny, dry conditions; light winds; temperature inversions possible; fog formation in valleys

Low Pressure (Cyclone)

Characteristics

Air Movement: Rising, converging at surface
Rotation: Anticlockwise in Southern Hemisphere
Weather: Cloudy, unsettled conditions
Formation: Heating and rising of air

Associated Weather

Cloud formation, precipitation, strong winds, potential for storms

Cyclones Cyclone Systems

Mid-latitude Cyclones (Temperate Cyclones)

30-60° latitude, frontal boundaries

Formation & Structure

Form along polar fronts where air masses meet
Develop wave-like disturbances along fronts
Consist of warm and cold sectors
Diameter: 1000-2000 km
Life span: 3-7 days

Frontal Systems

Cold Front

Cold air advances under warm air

Heavy rain, thunderstorms, temperature drop

Warm Front

Warm air advances over cold air

Light rain, drizzle, gradual warming

Occluded Front

Cold front catches warm front

Complex precipitation, weakening system

Stationary Front

Little to no movement

Extended precipitation, little temperature change

Life Cycle Stages

Initial Stage

Wave develops on polar front

Development

Pressure falls, circulation intensifies

Mature Stage

Well-developed fronts, maximum intensity

Occlusion

Cold front overtakes warm front

Dissipation

System weakens, fills with air

Tropical Cyclones (Hurricanes/Typhoons)

5-20° latitude, over warm oceans (>26.5°C)

Formation Requirements

Warm ocean waters (minimum 26.5°C to 50m depth)
Atmospheric instability and convection
High humidity in lower to middle troposphere
Low vertical wind shear
Coriolis force (minimum 5° from equator)
Pre-existing disturbance

Structure

Eye

Center of cyclone

Diameter: 30-65 km
Calm winds, clear skies
Sinking air, warm temperatures

Eyewall

Ring of intense storms

Strongest winds, heaviest rain
Rising air, towering clouds
Most destructive region

Rainbands

Spiral bands of clouds

Extend outward from eyewall
Bands of showers and thunderstorms
Can produce tornadoes

Impacts & Safety

Storm Surge

Rise in sea level due to low pressure and winds

High Danger

Heavy Rainfall

Flooding and landslides

Medium Danger

High Winds

Structural damage, flying debris

High Danger

Tornadoes

Form in outer rainbands

Medium Danger

Safety Measures

Follow evacuation orders
Secure property and windows
Prepare emergency kit (food, water, medicines)
Stay informed via official channels
Avoid floodwaters and damaged areas

Local Local Weather Phenomena

Thunderstorms

Convection, instability, moisture

Formation: Cumulonimbus clouds
Features: Lightning, thunder, heavy rain
Types: Single-cell, multi-cell, supercell
Hazards: Flash floods, lightning strikes

Tornadoes

Severe thunderstorm rotation

Formation: Mesocyclone in supercell thunderstorms
Features: Funnel cloud, violent winds
Scale: Enhanced Fujita (EF) scale
Hazards: Extreme wind damage, flying debris

Heat Waves

High pressure systems, heat domes

Definition: Prolonged period of excessive heat
Impacts: Heat exhaustion, drought, wildfires
Mitigation: Stay hydrated, avoid peak sun

Cold Waves

Arctic air masses, polar vortex

Definition: Prolonged period of extreme cold
Impacts: Frostbite, hypothermia, crop damage
Mitigation: Layer clothing, heat shelters

Droughts

Prolonged precipitation deficit

Types: Meteorological, agricultural, hydrological
Impacts: Water shortages, crop failure, wildfires
Management: Water conservation, drought-resistant crops

Floods

Heavy rainfall, storm surges, snowmelt

Types: Flash floods, river floods, coastal floods
Impacts: Property damage, displacement, disease
Prevention: Flood barriers, proper drainage

Skills Skills Development

Map

Map Interpretation

Reading weather maps, isobars, isotherms, frontal symbols

Data

Data Analysis

Analyzing temperature, pressure, wind, and precipitation data

Predict

Weather Prediction

Using observations and data to forecast weather conditions

Critical

Critical Thinking

Evaluating weather information sources and reliability

Safety

Safety Planning

Developing emergency plans for extreme weather events

Comm

Communication

Presenting weather information clearly and accurately

Assessment Assessment Methods

Tests & Exams

Knowledge of meteorological concepts and weather systems

Weather Map Exercises

Interpreting and analyzing synoptic weather maps

Instrument Readings

Recording and interpreting weather instrument data

Case Studies

Analyzing historical weather events and their impacts

Research Projects

Investigating local weather patterns or extreme events

Practical Reports

Documenting weather observations and measurements

CAPS Curriculum Requirements

✓

Understand basic meteorological concepts and terminology

✓

Interpret weather maps and symbols accurately

✓

Differentiate between high and low pressure systems

✓

Explain formation and characteristics of mid-latitude cyclones

✓

Understand tropical cyclone development and impacts

✓

Analyze local weather phenomena and their causes

✓

Apply weather knowledge to real-world situations and safety

Learning Resources

PDF

Weather Systems Notes

Complete PDF summary with diagrams

Maps

Weather Map Collection

Sample weather maps for practice

Instruments

Instrument Guide

Guide to weather instruments and readings

Case

Case Studies

Analysis of historical weather events