The resources included here are designed to be stimulating, challenging and adequately differentiated. Time is precious to a teacher, and these 'oven ready lessons' include everything you need at a cost effective price. The resources included are perfect for subject specialists and non-specialists alike, and are produced through a modern/professional use of PowerPoint which utilises graphics, animation and timers (etc.) to promote maximum progress during lessons.
The resources included here are designed to be stimulating, challenging and adequately differentiated. Time is precious to a teacher, and these 'oven ready lessons' include everything you need at a cost effective price. The resources included are perfect for subject specialists and non-specialists alike, and are produced through a modern/professional use of PowerPoint which utilises graphics, animation and timers (etc.) to promote maximum progress during lessons.
This lesson explores the digestive systems of monogastric and ruminant animals, examining how each system is adapted to process different types of food. Through comparative analysis and interactive discussions, students learn the functions of key digestive structures and the dietary implications for each type. This lesson is perfect for students interested in animal biology and agricultural science, offering insights into digestive adaptations.
Learning Objectives:
Define and provide examples of monogastric and ruminant animals.
Explain the function of main structures within monogastric and ruminant digestive systems.
Compare the digestive processes and dietary adaptations between monogastric and ruminant animals.
Lesson Highlights:
Starter Activity: Students guess which animal is monogastric and which is ruminant, exploring the concept of “mono” (single) versus multi-chambered stomachs.
Monogastric Digestive System Overview: Examination of the digestive process in monogastric animals, covering the function of structures such as the stomach, small intestine, and cecum.
Ruminant Digestive System Overview: Detailed exploration of the four compartments of the ruminant stomach (rumen, reticulum, omasum, and abomasum) and their roles in breaking down fibrous plant material.
Comparative Summary Table: Students complete a table comparing digestive processes, noting adaptations in each system that support dietary needs.
Complete Answers and Timed Activities: Answers are provided for structured discussions, and timers are used to keep activities on track.
Included Materials:
PowerPoint Presentation with diagrams of monogastric and ruminant digestive systems
Worksheet for digestive system comparison and analysis
Answer key for all activities and discussion points
Reflection prompts to encourage self-assessment
This lesson package gives students a thorough understanding of digestive system adaptations, helping them appreciate how physiology aligns with diet and environment in agricultural animals.
This lesson introduces students to the physical characteristics of agricultural animals, with a specific focus on comparing Bos taurus indicus (Zebu cattle) and Bos taurus taurus (European cattle). Through discussions, examples, and comparative analysis, students learn how physical traits relate to animals’ natural environments and survival strategies. This lesson is ideal for students to gain an understanding of animal adaptation and suitability to specific climates.
Learning Objectives:
Define and describe physical characteristics relevant to agricultural animals.
Identify and compare the physical features of Bos taurus indicus and Bos taurus taurus.
Relate these characteristics to environmental adaptation and feeding behavior.
Lesson Highlights:
Starter Activity: Students observe images of animal features and connect each feature to its specific function, like heat dissipation in Brahman cattle.
Comparative Analysis: Exploration of the traits of Bos taurus indicus (e.g., hump, loose skin) versus Bos taurus taurus (e.g., body shape, skin texture) and how these features aid in survival in different climates.
Discussion on Adaptations: Examination of physical adaptations, such as ear size and leg structure, and their role in helping animals thrive in challenging environments.
Extended Writing Task: Students write a comparison of Bos taurus indicus and Bos taurus taurus, analyzing how each breed’s traits are suited to its natural habitat.
Complete Answers and Timed Activities: All answers are provided to support discussions, and timers are included to maintain lesson flow.
Included Materials:
PowerPoint Presentation with comparative visuals of cattle breeds
Worksheet for noting and analyzing physical characteristics
Answer key for discussion points and activities
Reflection prompts to encourage student assessment of their understanding
This lesson package provides students with an understanding of how physical traits support the survival and productivity of agricultural animals, focusing on adaptation to climate and environment.
This lesson provides students with an introduction to animal husbandry, focusing on breeding practices and the significance of specific traits for agricultural success. Through discussions, examples, and selective breeding case studies, students learn how animals are bred for desirable characteristics and explore regional livestock breeds adapted to North Queensland’s conditions. This lesson is ideal for students to understand the fundamentals of animal rearing and the principles of selective breeding.
Learning Objectives:
Describe the practices and goals of animal husbandry.
Define the concept of a breed and understand its importance in agriculture.
Identify agricultural animals of regional significance and their adapted traits.
Explain how selective breeding is used to produce desired characteristics in animals.
Lesson Highlights:
Starter Activity: Students guess the lesson title and discuss products produced through animal husbandry, leading into a discussion on the purpose of rearing animals.
Concept of Breeds: Introduction to the definition of a breed, with examples of characteristics important to North Queensland, like heat tolerance and disease resistance.
Selective Breeding Case Study: Students learn about selective breeding through global and local examples, understanding the process of selecting traits over generations.
Regional Breeds Exploration: Students explore local livestock breeds adapted to North Queensland and the specific traits that support their productivity and resilience.
Complete Answers and Timed Activities: All answers are provided for facilitation, and timers are used to keep the lesson flowing smoothly.
Included Materials:
PowerPoint Presentation with examples of animal husbandry practices and selective breeding
Worksheet for breed characteristics and selective breeding processes
Answer key for all discussion points and activities
Reflection prompts to encourage student assessment of their learning
This comprehensive lesson package introduces students to the core concepts of animal husbandry, selective breeding, and the significance of regionally adapted livestock breeds, providing a solid foundation for further studies in agricultural science.
This informative lesson explores the various business structures within the agricultural industry, including family farms, partnerships, companies, and land tenure. Through discussions, data analysis, and case studies, students learn about the benefits and challenges of each structure, as well as the importance of succession planning in farming. This lesson provides valuable insights into the organizational aspects of agricultural enterprises, ideal for helping students understand property management and business continuity in agriculture.
Learning Objectives:
Describe business structures in agriculture, including partnerships, companies, land tenure, family farms, and succession.
Compare the features, advantages, and challenges of different agricultural business structures.
Analyze data from the Australian Bureau of Statistics (ABS) to understand the impact of various industries.
Interpret data on physical and biological resources, such as soil, climate, vegetation, and topography, relevant to a production unit.
Lesson Highlights:
Starter Activity: Students discuss different types of agricultural business structures, such as family farms and partnerships, and consider the importance of succession planning.
Business Structure Breakdown: Examination of each business type with a focus on ownership, responsibilities, benefits, and challenges.
Data Analysis with ABS Resources: Students analyze industry data from the ABS to compare major and minor agricultural industries, examining factors like land use and economic impact.
Resource Interpretation Exercise: Interpretation of physical and biological resource data, including soil quality, climate conditions, and topography, for informed decision-making.
Complete Answers and Timed Activities: All answers are provided for easy facilitation, with timers to maintain lesson pace and engagement.
Included Materials:
PowerPoint Presentation with examples and explanations of business structures
Data analysis worksheet using ABS and DEF resources
Answer key for all activities and discussion questions
Reflection prompts for student self-assessment
This lesson package offers students a comprehensive look at agricultural business structures, equipping them with knowledge about property ownership, industry data analysis, and resource management in agriculture.
This lesson introduces students to prominent agricultural enterprises in Queensland, including both plant- and animal-based industries. Through case studies and research activities, students examine the resources (physical, human, and biological) required for successful agricultural operations. This lesson provides valuable insights into the significance of local and national enterprises in the agricultural sector, ideal for connecting students with real-world examples of regional production.
Learning Objectives:
State examples of significant agricultural enterprises in Queensland.
Describe local and national agricultural enterprises and their importance.
Outline the physical, human, and biological resources involved in agricultural enterprises.
Compare the resources required for plant-based and animal-based enterprises.
Lesson Highlights:
Starter Activity: Students discuss well-known agricultural products from Queensland and share any personal connections to agricultural enterprises.
Case Study on Teys Australia: Exploration of one of Australia’s largest beef processing companies, covering its employment impact, export significance, and sustainability initiatives.
Resource Analysis: Students examine the physical, human, and biological resources necessary for agricultural enterprises, using examples like farmland, skilled labor, and livestock.
Research Task: Students research and compare one plant-based and one animal-based enterprise, focusing on local and national examples.
Complete Answers and Timed Activities: Answers are provided for structured discussions, and timers ensure each activity progresses smoothly.
Included Materials:
PowerPoint Presentation with case studies and resource breakdowns
Worksheet for resource analysis and enterprise comparisons
Answer key for guided discussions and case study details
Reflection prompts for self-assessment
This lesson package helps students understand the economic and environmental significance of agricultural enterprises, offering a comprehensive look at the resources and sustainability practices that support these industries.
This lesson introduces students to the key components of agricultural systems, including inputs, processes, outputs, and subsystems, as well as the distinctions between intensive and extensive farming methods. Using examples, interactive discussions, and case studies, students learn how these elements work together to produce agricultural outputs efficiently. Perfect for providing students with a clear and structured understanding of the complexity and interconnectedness of agricultural systems.
Learning Objectives:
Describe the components of an agricultural system.
Explain the interconnections between system components in agriculture.
State the features of intensive animal and plant industries.
State the features of extensive animal and plant industries.
Lesson Highlights:
Starter Activity: Students analyze examples from the digestive system of ruminants to understand systems’ components and connect this to agricultural systems.
Detailed Component Breakdown: Exploration of agricultural inputs, outputs, processes, subsystems, and interactions.
Case Study Analysis: Students watch a video on agricultural practices, identifying and categorizing components (inputs, outputs, subsystems, etc.).
Intensive vs. Extensive Farming: Comparative analysis of intensive and extensive farming practices, emphasizing differences in scale, resources, and productivity.
Complete Answers and Timed Activities: All correct answers are included for easy reference, with timers integrated for efficient lesson pacing.
Included Materials:
PowerPoint Presentation with examples of agricultural system components
Worksheet for case study analysis and farming comparisons
Answer key for all activities and questions
Reflection prompts to encourage student assessment of their understanding
This lesson package provides a thorough look at the components and functioning of agricultural systems, equipping students with foundational knowledge for further studies in agricultural science.
This comprehensive lesson introduces students to the concept of agricultural systems, focusing on open, closed, and isolated systems and how they interact with their surroundings. Through discussions, interactive activities, and real-world examples, students explore how inputs, processes, and subsystems produce outputs in agriculture. This lesson provides a well-rounded understanding of agricultural systems and their complexities, perfect for building foundational knowledge in agricultural science.
Learning Objectives:
Define open, closed, and isolated agricultural systems.
Differentiate between these systems in terms of energy and matter transfer.
Explain how agricultural systems function through inputs, processes, and outputs.
Illustrate agricultural system concepts using a dairy farm example.
Lesson Highlights:
Starter Activity: Students discuss energy and matter transfer in different systems, introducing open, closed, and isolated systems in agriculture.
Class Discussion: Examination of traditional farms as open systems, terrariums as closed systems, and the concept of isolated systems.
Dairy Farm Case Study: Students analyze a dairy farm as a system, identifying inputs, outputs, boundaries, subsystems, and processes through a flow diagram.
Complete Answers and Timed Activities: All answers are provided for teacher facilitation, with timers to help pace activities.
Included Materials:
PowerPoint Presentation with system definitions and agricultural examples
Worksheet for dairy farm system analysis and flow diagram creation
Answer key for discussion questions and system descriptions
Reflection prompts for student self-assessment
This lesson package offers students a clear and structured introduction to agricultural systems, helping them understand the interrelated components that drive agricultural production.
This engaging lesson introduces students to the principles of supply and demand, using agriculture as a real-world context to illustrate key economic concepts. Through interactive discussions, graph analysis, and practical examples, students learn how supply and demand affect agricultural prices and explore the impact of global market trends on local farming. Perfect for developing critical thinking skills and understanding economics in the agricultural sector.
Learning Objectives:
Understand the basic principles of supply and demand in agriculture.
Identify factors that cause changes in supply and demand.
Analyze the effects of supply and demand shifts on market equilibrium using graphs.
Explain the influence of global market trends on local farming economies.
Lesson Highlights:
Starter Activity: Students examine a supply and demand graph, predicting outcomes when supply or demand changes.
Class Discussion: Introduction to core concepts of supply and demand, with agricultural examples (e.g., bumper crops, scarcity).
Graph Analysis Practice: Students practice drawing and interpreting supply and demand curves, exploring how various scenarios affect prices and quantities.
Global Market Trends: Discussion on how international demand and events influence local agricultural prices.
Complete Answers and Timed Activities: Answers are provided for all exercises, and timers are used to maintain a smooth lesson flow.
Included Materials:
PowerPoint Presentation with supply and demand visuals and practical examples
Worksheets for graph analysis and economic scenario exploration
Answer key for activities and discussion prompts
Reflection questions for student self-assessment
This lesson package offers a thorough introduction to supply and demand principles in an agricultural setting, helping students connect economic theory with real-world farming practices.
Please visit my shop to see other complete lessons in the fields of Biology, Chemistry, Physics and Agricultural science!
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This engaging lesson introduces students to Integrated Pest Management (IPM), a sustainable approach combining biological, mechanical, and chemical pest control methods. Through hands-on activities, case studies, and programming exercises with Edison robots, students learn about effective pest management, the significance of pest life cycles, and the benefits of using precision technology to reduce environmental impact. Perfect for understanding sustainable farming and the complexities of pest control.
Learning Objectives:
State the principles of Integrated Pest Management (IPM).
Discuss the roles of natural predators and biopesticides in pest control.
Recognize the importance of pest life cycles for effective pest management.
Analyze the life cycle of the barber’s pole worm to suggest control strategies in livestock management.
Lesson Highlights:
Starter Activity: Students match pest control methods (chemical, biological, mechanical) to examples and discuss their environmental impact.
IPM Exploration: In-depth overview of IPM principles, including examples of natural predators, biopesticides, and mechanical controls.
Programming Challenge with Edison Robots: Students program robots to simulate precision pesticide application, developing skills in automation and sustainable agriculture.
Life Cycle Analysis: Using the barber’s pole worm as a case study, students learn about pest life cycles and how rotational grazing disrupts reinfection.
Complete Answers and Timed Activities: All answers are provided for easy reference, and timers are used to ensure smooth pacing.
Included Materials:
PowerPoint Presentation with IPM explanations and pest life cycle visuals
Edison robot programming guide and challenge mat
Answer key for all activities and discussion questions
Reflection prompts to encourage student self-assessment
This lesson package offers a comprehensive introduction to IPM and the use of technology in pest management, helping students understand sustainable practices in agriculture while developing practical programming skills.
If you like this resource visit my shop for more complete lessons in the fields of Biology, Chemistry, Physics and Agricultural science
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This insightful lesson examines the environmental impact of improper fertilizer use and introduces students to sustainable farming practices. Through engaging discussions, practical activities, and distribution analysis, students learn about the causes and effects of eutrophication and the role of precision agriculture, buffer zones, and crop rotation in reducing environmental harm. This lesson is perfect for developing a practical understanding of sustainable agriculture and ecosystem preservation.
Learning Objectives:
Identify the effects of excessive fertilizer use on soil structure and long-term fertility.
Explain how nutrient runoff leads to eutrophication and its consequences for aquatic life.
Describe sustainable farming practices (precision agriculture, buffer zones, and crop rotation) that reduce environmental impact.
Analyze distribution patterns to identify causes of poor crop growth and suggest improvements.
Lesson Highlights:
Starter Activity: Using before-and-after images, students hypothesize the causes and impacts of eutrophication, linking it to fertilizer use.
Stages of Eutrophication: Students arrange the stages of eutrophication, learning about nutrient runoff, algal blooms, and biodiversity loss.
Best Practices for Sustainability: Exploration of sustainable techniques, including precision agriculture, buffer zones, and crop rotation.
Distribution Analysis Activity: Students match causes with observed crop symptoms, conducting a distribution analysis to diagnose potential issues.
Answers and Timed Activities: Complete answers are provided for easy facilitation, with timers to ensure each activity is well-paced.
Included Materials:
PowerPoint Presentation with visual aids and structured stages of eutrophication
Worksheets for distribution analysis and sustainability techniques
Answer key for discussion and analysis activities
Reflection prompts for student assessment
This comprehensive lesson package equips students with an understanding of the impacts of fertilizer use on ecosystems and sustainable practices for maintaining agricultural productivity and environmental health.
Please see my shop for other complete lessons in the fields of Biology, Chemistry, Physics and Agricultural Science!
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This detailed lesson introduces students to the importance of essential nutrients for plant health and growth. Through interactive activities and real-world examples, students learn to identify the symptoms of nitrogen, phosphorus, and potassium deficiencies and explore effective strategies to prevent and correct these issues in agriculture. Ideal for fostering a deeper understanding of plant nutrition and sustainable agricultural practices.
Learning Objectives:
Identify the roles of nitrogen (N), phosphorus §, and potassium (K) in plant growth and health.
Describe the visual symptoms of deficiencies in nitrogen, phosphorus, and potassium.
Differentiate between the symptoms of each deficiency based on visual cues.
Explain the causes of nutrient deficiencies and recommend strategies to correct them in crop management.
Lesson Highlights:
Starter Activity: Students observe and identify deficiency symptoms (yellowing, purpling, browning) in plants and discuss potential nutrient causes.
Class Discussion: Review of the roles of N, P, and K in plants, focusing on how these nutrients support specific aspects of growth, such as leaves, roots, and resistance.
Deficiency Case Studies: Students analyze specific cases of nutrient deficiencies and discuss practical methods for soil improvement, such as crop rotation, fertilization, and pH management.
Complete Answers and Timed Activities: All correct answers are included for easy facilitation, and timers are integrated to keep activities well-paced and engaging.
Included Materials:
PowerPoint Presentation with nutrient role visuals and deficiency images
Worksheet for identifying and addressing nutrient deficiencies
Answer key for activities and discussions
Reflection prompts to encourage student self-assessment
This engaging lesson package provides students with practical skills to identify and manage nutrient deficiencies in plants, fostering responsible and sustainable approaches to agriculture.
This interactive lesson explores the chemistry behind soil fertility, guiding students through the essential nutrients and testing methods that help farmers optimize crop growth. Using hands-on activities, visual aids, and a structured soil testing practical, students gain insight into how soil health affects agricultural productivity and the vital role of chemistry in sustainable farming.
Learning Objectives:
Understand the role of chemistry in determining soil health.
Describe the importance of essential nutrients: Nitrogen (N), Phosphorus §, and Potassium (K)in plant growth.
Analyze soil samples to assess nutrient levels and soil suitability for crops.
Apply knowledge in an exam-style question to reinforce understanding of soil fertility concepts.
Lesson Highlights:
Starter Activity: Students compare images of crops with varying health, hypothesizing about soil quality and nutrient differences.
Class Discussion: Introduction to essential nutrients (N, P, K) and their specific roles in supporting plant growth, including leaf and stem growth, root development, and disease resistance.
Soil Testing Practical: Students use probes to analyze soil samples, record results, and compare findings to ideal nutrient levels. Conclusion questions help them interpret and apply their observations.
Answer Key and Timed Activities: All answers are provided for easy facilitation, and timers are built into the lesson to keep students on track and engaged.
Whats included:
PowerPoint Presentation with visual aids and step-by-step instructions
Practical worksheet for soil testing and analysis
Literacy exercise
Complete answer key for all activities and discussion points
Reflection prompts to encourage students to assess their learning
This comprehensive lesson package is designed to engage students in understanding the chemical foundations of soil health and its impact on agriculture, providing a well-rounded look at sustainable farming practices.
This dynamic lesson introduces students to the interconnected roles of biology, chemistry, and economics in agricultural science. Through engaging discussions, hands-on activities, and real-world examples, students explore how these core disciplines work together to drive innovation and sustainability in agriculture. Perfect for helping students recognize agriculture as a multidisciplinary field, this lesson provides a holistic view of how science supports farming practices.
Learning Objectives:
Recognize the interdisciplinary nature of agricultural science.
Understand biology’s role in plant growth, animal health, and pest management.
Explore how chemistry aids soil fertility, pesticide formulation, and food preservation.
Discuss economic principles like supply and demand and their impact on farming decisions.
Lesson Highlights:
Starter Activity: A visual guessing game prompts students to identify biology, chemistry, and economics as the three pillars of agricultural science.
Video Case Study: Students watch a video on the Australian farming environment and identify examples of innovation in agriculture.
Interactive Poster Activity: Students visit information stations on each discipline, filling out worksheets to deepen their understanding.
**Timed Activities and Complete Answers Provided: **Built-in timers help pace each activity, keeping students engaged and on track, while all answers are provided within the slides for easy facilitation.
**Reflection & Review: **Students summarize their learning in short responses, reflecting on areas they found easy, challenging, or interesting.
Included Materials:
PowerPoint Presentation with visual aids and timers
Worksheet for video observation and station activities
Complete answer key for all activities
Review and reflection prompts
This lesson is ideal for creating a comprehensive and practical understanding of agricultural science, highlighting how interdisciplinary knowledge enhances sustainable farming practices.
This interactive lesson helps Grade 10 students identify and understand the critical inputs and outputs in various farming systems, including dairy farms, crop farms, and aquaculture. Using real-world examples and a case study from Figtree Farm, students explore how farmers balance these factors to ensure sustainability and profitability in agriculture.
Learning Objectives:
Define the terms inputs and outputs within agricultural systems.
Provide examples of inputs and outputs in different types of farming systems.
Discuss the importance of balancing inputs and outputs for sustainable farming.
Identify inputs and outputs in a specific case study and analyze the system’s sustainability.
Learning Activities:
Starter Activity: Using visual aids, students identify simple inputs and outputs in agricultural systems to begin understanding these fundamental concepts.
Class Discussion and Presentation: Students examine various types of farms (dairy, crop, and aquaculture), discussing the inputs (e.g., seeds, water, feed) and outputs (e.g., milk, crops, fish) essential to each system.
Case Study & Video: Students watch a video about Figtree Farm and complete an observation worksheet where they list and reflect on the inputs and outputs observed in the farming system, focusing on its sustainability.
Review and Kahoot Quiz: Students consolidate their knowledge through a structured review session and a fun Kahoot quiz, reinforcing key concepts.
Additional Features:
Included Answers: All correct answers are provided within the slides, ensuring seamless teaching and easy reference for students.
Timed Activities: Built-in timers help pace the lesson and keep students on track, promoting active participation and timely completion of tasks.
Video Integration: The lesson includes a video case study, giving students a practical look at farming systems in action and enabling hands-on observation.
This lesson package includes a PowerPoint presentation, the Figtree Farm observation worksheet, and an answer sheet. It is designed to engage students while providing a clear and structured exploration of agricultural inputs and outputs.
This engaging and comprehensive lesson introduces Grade 10 students to the concept of farming systems, focusing on three main types: subsistence, commercial, and mixed farming. Set within the context of North Queensland agriculture, the lesson provides students with practical and relevant examples from their local environment, helping them to connect theory with real-world applications.
Learning Objectives:
Define the term farming systems and understand the interconnected processes within agricultural production.
Identify and describe the three key processes involved in farming systems: crop cultivation, livestock raising, and resource management.
Compare the features of subsistence, commercial, and mixed farming systems, highlighting their unique characteristics and sustainability practices.
Learning Activities:
Starter Discussion: Students explore local North Queensland businesses, identifying inputs, processes, and outputs to introduce the concept of farming systems.
Class Discussions and Presentations: Covering crop cultivation, livestock raising, and resource management, with interactive questions encouraging critical thinking on topics like cattle breeds suited to tropical environments and sustainable farming practices.
Knowledge Check and Review: A worksheet featuring true/false, multiple-choice, and short-answer questions that assess understanding of key concepts such as farming types and the importance of resource management in sustainability.
Group Challenge: A fun “Beat the Question Grid” activity reinforces learning through quickfire questions on farming systems, encouraging collaborative learning and knowledge consolidation.
**
Additional Features:**
Included Answers: All correct answers are provided within the slides, ensuring easy reference and smooth transitions between activities.
Timed Activities: Built-in timers are used throughout the lesson to maintain pace and keep students engaged, promoting focused and efficient learning.
This lesson is designed for ease of use, providing clear explanations and activities that align with the curriculum while fostering students’ critical thinking and understanding of agriculture.
A full differentiated lesson covering ‘Ecosystems and interaction between organisms’ form the Edexcel GCSE specification but can be used for others.
The lesson covers key definitions, interdependence, abiotic vs biotic factors and touches on energy transfer in ecosystems. Differentiated tasks included throughout with answers included for ease of use.
A revision lesson tailored to the OCR-A specification, covering the following topics:
DNA structure
DNA replication
Translation and the interrelation of organelles
Epistasis
Hardy-Weinberg
A full differentiated lesson based on the Edexcel SOW but can be used for others. The lesson covers the stages of each cycle, the levels of oestrogen, FSH, LH and progesterone during each stage as well as the function of each hormone. A worksheet exercise and a differentiated question grid are used to check student understanding at separate stages within the lesson. A reflective plenary is included. All answers are incorporated into the slides and timers are used to promote pace.
No planning required.
I would probably spread this over 2 lessons, lots of information with a range of activities and all answers included. I have made use of some free content from other authors in this hence share and share alike! Hope it saves you time.
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A full lesson covering the topics noted above, I hope it saves you some time.
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