Living Things and their Environment

The interdependence of life - Abiotic factors (temperature)
The interdependence of life - Abiotic factors (light)
The interdependence of life - Abiotic factors (water)

By the end of the lesson, the learner should be able to:

- Explain how temperature affects living organisms
- Describe adaptations of organisms to different temperatures
- Value the importance of temperature in ecosystems

- Explain how light affects living organisms
- Describe adaptations of organisms to different light conditions
- Appreciate the role of light in ecosystems

- Discuss how temperature affects living organisms
- Research on adaptations of organisms to different temperatures
- Observe pictures/videos of organisms in different temperature zones
- Present findings to class
- Discuss how light affects living organisms
- Research on adaptations of organisms to different light conditions
- Observe plants grown under different light conditions
- Present findings to class

What is the role of living and non-living factors in environments?

- Mentor Integrated Science Grade 9 (pg. 113)
- Thermometers
- Pictures/videos of organisms in different temperature zones
- Digital devices
- Mentor Integrated Science Grade 9 (pg. 114)
- Light meters (if available)
- Plants grown under different light conditions
- Digital devices
- Mentor Integrated Science Grade 9 (pg. 115)
- Pictures of plants from arid and wet environments
- Water samples

- Observation - Oral questions - Written assignments - Group presentations

Living Things and their Environment

The interdependence of life - Abiotic factors (wind)

By the end of the lesson, the learner should be able to:

- Explain how wind affects living organisms
- Describe adaptations of organisms to windy environments
- Appreciate the role of wind in ecosystems

- Discuss how wind affects living organisms
- Research on adaptations of organisms to windy environments
- Observe plants from windy and sheltered environments
- Present findings to class

What is the role of living and non-living factors in environments?

- Mentor Integrated Science Grade 9 (pg. 116)
- Pictures of plants from windy and sheltered environments
- Digital devices

- Observation - Oral questions - Written assignments - Group presentations

Living Things and their Environment

The interdependence of life - Abiotic factors (atmospheric pressure, pH and salinity)
The interdependence of life - Energy flow (food chains)

By the end of the lesson, the learner should be able to:

- Explain how atmospheric pressure, pH and salinity affect living organisms
- Describe adaptations of organisms to these abiotic factors
- Value adaptations to different environments

- Discuss how atmospheric pressure, pH and salinity affect living organisms
- Research on adaptations of organisms to these factors
- Test pH and salinity of different water samples if possible
- Present findings to class

What is the role of living and non-living factors in environments?

- Mentor Integrated Science Grade 9 (pg. 117)
- pH testing equipment (if available)
- Water samples of different salinity
- Digital devices
- Mentor Integrated Science Grade 9 (pg. 118)
- Charts showing food chains
- Pictures of local organisms

- Observation - Oral questions - Practical assessment - Written assignments

Living Things and their Environment

The interdependence of life - Energy flow (food webs)

By the end of the lesson, the learner should be able to:

- Explain the concept of food webs
- Construct simple food webs
- Value the complexity of feeding relationships in ecosystems

- Discuss the concept of food webs
- Identify how food chains interconnect to form food webs
- Construct simple food webs using organisms observed in the local environment
- Present food webs to class

What is the role of living and non-living factors in environments?

- Mentor Integrated Science Grade 9 (pg. 119)
- Charts showing food webs
- Pictures of local organisms
- Digital devices

- Observation - Oral questions - Food web construction assessment - Written assignments

Living Things and their Environment

The interdependence of life - Human activities (habitat change)
The interdependence of life - Human activities (introduction of new living things)
The interdependence of life - Interrelationships in Kenya national parks

By the end of the lesson, the learner should be able to:

- Explain how human activities lead to habitat change
- Describe the effects of habitat change on ecosystems
- Show concern for habitat conservation

- Explain the effects of introducing new species to ecosystems
- Describe examples of invasive species and their impacts
- Appreciate the importance of biodiversity conservation

- Discuss human activities that lead to habitat change
- Research on the effects of habitat change on ecosystems
- Debate on the balance between development and conservation
- Present findings to class
- Discuss the effects of introducing new species to ecosystems
- Research on examples of invasive species and their impacts
- Debate on the management of invasive species
- Present findings to class

What is the role of living and non-living factors in environments?

- Mentor Integrated Science Grade 9 (pg. 120)
- Pictures showing habitat change
- Digital devices
- Newspaper articles
- Mentor Integrated Science Grade 9 (pg. 122)
- Pictures of invasive species
- Digital devices
- Newspaper articles
- Mentor Integrated Science Grade 9 (pg. 123)
- Pictures of Kenya national parks
- Maps of Kenya national parks

- Observation - Oral questions - Debate assessment - Written assignments

Living Things and their Environment

The interdependence of life - Role of decomposers in ecosystems

By the end of the lesson, the learner should be able to:

- Explain the role of decomposers in ecosystems
- Identify examples of decomposers
- Appreciate the importance of decomposers in nutrient cycling

- Discuss the role of decomposers in ecosystems
- Observe pictures/videos of decomposers in action
- Research on examples of decomposers
- Create a model of nutrient cycling showing the role of decomposers

What is the role of living and non-living factors in environments?

- Mentor Integrated Science Grade 9 (pg. 125)
- Pictures/videos of decomposers
- Digital devices
- Materials to create models

- Observation - Oral questions - Model assessment - Written assignments

Force and Energy

Curved mirrors - Types of curved mirrors
Curved mirrors - Terms associated with concave mirrors
Curved mirrors - Determining focal length of concave mirror

By the end of the lesson, the learner should be able to:

- Describe the types of curved mirrors
- Differentiate between concave and convex mirrors
- Appreciate the applications of curved mirrors in day to day life

- Discuss the types of curved mirrors (concave, convex, and parabolic surfaces)
- Use shiny spoons to demonstrate the difference between concave and convex reflective surfaces
- Observe and record how images are formed by the inner and outer surfaces of the spoon

How are curved mirrors used in day to day life?

- Mentor Integrated Science (pg. 133)
- Shiny spoons
- Digital resources on curved mirrors
- Mentor Integrated Science (pg. 135)
- Digital resources
- Charts showing the structure of a concave mirror
- Mentor Integrated Science (pg. 137)
- Concave mirrors
- Rulers
- White screens or plain paper
- Mirror holders

- Observation - Oral questions - Written assignments

Force and Energy

Curved mirrors - Ray diagrams for concave mirrors
Curved mirrors - Image formation by concave mirrors (beyond C)

By the end of the lesson, the learner should be able to:

- Draw conventional ray diagrams for concave mirrors
- Identify the four special rays used in ray diagrams
- Show interest in the ray diagram approach to locate images

- Draw conventional ray diagrams of concave mirrors
- Identify and draw the four types of rays used in ray diagrams (ray through center of curvature, ray parallel to principal axis, ray through focus, ray through pole)
- Analyze how these rays help locate images

How do ray diagrams help in locating images formed by concave mirrors?

- Mentor Integrated Science (pg. 140)
- Plain paper
- Rulers
- Pencils
- Drawing instruments
- Mentor Integrated Science (pg. 143)
- Concave mirrors
- Digital resources

- Observation - Drawing assessment - Written assignments

Force and Energy

Curved mirrors - Image formation by concave mirrors (at C)
Curved mirrors - Image formation by concave mirrors (between C and F)
Curved mirrors - Image formation by concave mirrors (at F)

By the end of the lesson, the learner should be able to:

- Draw ray diagrams to locate images when objects are placed at C
- Describe the characteristics of images formed
- Show curiosity in investigating image formation

- Draw ray diagrams to locate images when objects are placed at the center of curvature
- Determine the characteristics of images formed
- Verify the results through practical observation

What are the characteristics of images formed when objects are placed at the center of curvature?

- Mentor Integrated Science (pg. 144)
- Concave mirrors
- Drawing instruments
- Digital resources
- Mentor Integrated Science (pg. 145)
- Mentor Integrated Science (pg. 147)

- Observation - Ray diagram assessment - Written descriptions

Force and Energy

Curved mirrors - Image formation by concave mirrors (between F and P)
Curved mirrors - Characteristics of images formed by concave mirrors
Curved mirrors - Locating images formed by concave mirrors experimentally

By the end of the lesson, the learner should be able to:

- Draw ray diagrams to locate images when objects are placed between F and P
- Describe the characteristics of images formed
- Appreciate the practical applications of this image formation

- Draw ray diagrams to locate images when objects are placed between the principal focus and the pole
- Determine the characteristics of images formed
- Discuss practical applications like magnifying mirrors

What are the characteristics of images formed when objects are placed between the principal focus and the pole?

- Mentor Integrated Science (pg. 148)
- Concave mirrors
- Drawing instruments
- Digital resources
- Mentor Integrated Science (pg. 149)
- Previous ray diagrams
- Mentor Integrated Science (pg. 150)
- Mirror holders
- Screens
- Candles or light sources
- Rulers

- Observation - Ray diagram assessment - Written descriptions

Force and Energy

Curved mirrors - Terms associated with convex mirrors
Curved mirrors - Ray diagrams for convex mirrors
Curved mirrors - Image formation by convex mirrors
Curved mirrors - Locating images formed by convex mirrors experimentally
Curved mirrors - Applications of curved mirrors (concave mirrors)

By the end of the lesson, the learner should be able to:

- Identify the terms associated with convex mirrors
- Compare the structure of convex mirrors with concave mirrors
- Appreciate the differences between concave and convex mirrors

- Draw ray diagrams to locate images formed by convex mirrors
- Describe the characteristics of images formed by convex mirrors
- Appreciate the consistent nature of images formed by convex mirrors

- Discuss the terms associated with convex mirrors (aperture, center of curvature, pole, principal axis, principal focus, focal length)
- Draw and label the parts of a convex mirror
- Compare terms used in convex mirrors with those in concave mirrors
- Draw ray diagrams to locate images formed by convex mirrors for different object positions
- Determine the characteristics of images formed
- Discuss why convex mirrors always form virtual, upright, and diminished images

How does the structure of convex mirrors differ from concave mirrors?
What are the characteristics of images formed by convex mirrors?

- Mentor Integrated Science (pg. 153)
- Convex mirrors
- Digital resources
- Charts showing the structure of convex mirrors
- Mentor Integrated Science (pg. 154)
- Plain paper
- Rulers
- Pencils
- Drawing instruments
- Mentor Integrated Science (pg. 156)
- Convex mirrors
- Drawing instruments
- Digital resources
- Mentor Integrated Science (pg. 159)
- Mirror holders
- Objects of various sizes
- Rulers
- Mentor Integrated Science (pg. 161)
- Concave mirrors
- Examples of devices using concave mirrors

- Observation - Drawings and labels - Written assignments
- Observation - Ray diagram assessment - Written descriptions

Force and Energy

Curved mirrors - Applications of curved mirrors (convex mirrors)
Curved mirrors - Applications of curved mirrors (parabolic reflectors)

By the end of the lesson, the learner should be able to:

- Identify applications of convex mirrors in daily life
- Explain how the properties of convex mirrors make them suitable for specific applications
- Value the role of curved mirrors in enhancing safety and efficiency

- Research and discuss applications of convex mirrors (driving mirrors, security mirrors, eliminating blind spots)
- Explain how the wide field of view property of convex mirrors relates to their applications
- Observe examples of convex mirrors in use

What are the practical applications of convex mirrors in our daily lives?

- Mentor Integrated Science (pg. 162)
- Convex mirrors
- Digital resources
- Examples of devices using convex mirrors
- Mentor Integrated Science (pg. 163)
- Examples of devices using parabolic reflectors

- Observation - Oral presentations - Written assignments

Force and Energy

Waves - Meaning of waves
Waves - Generating waves in nature
Waves - Transverse and longitudinal waves

By the end of the lesson, the learner should be able to:

- Explain the meaning of waves in science
- Describe waves as a transmission of disturbance that carries energy
- Show interest in understanding wave phenomena in nature

- Read the story about John and ripples in the dam
- Discuss what happens when an object is dropped in still water
- Observe the movement of water waves and how they transport energy without moving matter

How are waves applied in our day to day life?

- Mentor Integrated Science (pg. 166)
- Basin with water
- Small objects to drop in water
- Digital resources
- Mentor Integrated Science (pg. 167)
- Rope
- Speakers
- Rice or sand
- Mentor Integrated Science (pg. 169)
- Slinky springs
- Cloth pieces for marking
- Digital resources showing wave motion

- Observation - Oral questions - Written assignments

Force and Energy

Waves - Classifying waves
Waves - Amplitude and wavelength
Waves - Frequency and period

By the end of the lesson, the learner should be able to:

- Classify various waves into transverse and longitudinal categories
- Give examples of transverse and longitudinal waves in nature
- Value the importance of classification in scientific study

- Study different wave examples provided in the textbook
- Classify the waves into transverse and longitudinal categories
- Research and identify real-world examples of both types of waves
- Create a classification chart of common waves

How are waves classified based on particle movement?

- Mentor Integrated Science (pg. 171)
- Digital resources
- Charts showing different wave types
- Wave demonstration equipment
- Mentor Integrated Science (pg. 172)
- Wave diagrams
- Rulers
- Graph paper
- Digital simulations
- Mentor Integrated Science (pg. 173)
- String and masses
- Stopwatches

- Observation - Classification exercises - Oral presentations - Written assignments

Force and Energy

Waves - Practical: Period of waves
Waves - Wave speed
Waves - Phase of waves
Waves - Oscillation in phase
Waves - Oscillation out of phase

By the end of the lesson, the learner should be able to:

- Determine the period of oscillation experimentally
- Calculate frequency from period measurements
- Value precision and accuracy in scientific measurements

- Explain the concept of phase in wave motion
- Differentiate between in-phase and out-of-phase oscillations
- Appreciate the mathematical precision in describing wave relationships

- Set up an experiment with a mass on a string
- Time multiple oscillations and calculate average period
- Calculate frequency from period measurements
- Record and analyze results
- Conduct experiments with identical pendulums oscillating in phase
- Observe pendulums with same frequency but different amplitudes
- Compare pendulums oscillating in opposite directions
- Create and analyze displacement-time graphs for different phase relationships

How is the period of oscillation measured experimentally?
What determines whether waves are in phase or out of phase?

- Mentor Integrated Science (pg. 175)
- Stands with clamps
- Strings
- Masses
- Stopwatches
- Mentor Integrated Science (pg. 176)
- Calculators
- Wave speed problems
- Digital resources
- Wave demonstration equipment
- Mentor Integrated Science (pg. 178)
- Stands with clamps
- Strings and identical masses
- Stopwatches
- Graph paper
- Mentor Integrated Science (pg. 179)
- Pendulum apparatus
- Measuring equipment
- Mentor Integrated Science (pg. 181)

- Observation - Practical assessment - Data analysis - Written reports
- Observation - Practical assessment - Graph interpretation - Written reports

Force and Energy

Waves - Characteristics of waves: straight-line motion
Waves - Characteristics of waves: reflection
Waves - Characteristics of waves: bending

By the end of the lesson, the learner should be able to:

- Identify parts of a ripple tank
- Demonstrate that waves travel in straight lines
- Show interest in systematic investigation of wave properties

- Identify parts of a ripple tank
- Set up a ripple tank to demonstrate straight-line motion of waves
- Observe and trace wave fronts on paper
- Analyze the direction of wave propagation

How do we demonstrate that waves travel in straight lines?

- Mentor Integrated Science (pg. 183)
- Ripple tank
- Water
- Paper for tracing
- Rulers
- Mentor Integrated Science (pg. 184)
- Metal strips as reflectors
- Paper for tracing wave patterns
- Mentor Integrated Science (pg. 185)
- Glass plate to create shallow region

- Observation - Practical assessment - Drawing analysis - Written reports

Force and Energy

Waves - Characteristics of waves: diffraction
Waves - Remote sensing in relation to waves
Waves - Transmission, absorption and reflection in remote sensing
Waves - Applications of waves in everyday life

By the end of the lesson, the learner should be able to:

- Demonstrate diffraction of waves around obstacles
- Explain how gap size affects diffraction patterns
- Appreciate diffraction as a fundamental wave property

- Set up a ripple tank with barriers having gaps of different sizes
- Generate waves and observe their behavior passing through gaps
- Compare diffraction patterns with different gap widths
- Relate observations to wave theory

How do waves behave when passing through gaps or around obstacles?

- Mentor Integrated Science (pg. 186)
- Ripple tank
- Water
- Metal barriers with adjustable gaps
- Paper for tracing wave patterns
- Mentor Integrated Science (pg. 187)
- Digital resources
- Diagrams of remote sensing processes
- Video clips on remote sensing
- Mentor Integrated Science (pg. 188)
- Examples of remote sensing data
- Mentor Integrated Science (pg. 190)
- Examples of wave-based technologies
- Video clips on wave applications

- Observation - Practical assessment - Drawing analysis - Written reports