Structure: refers to the nature of matter from simple to more complex forms
Structure 1. Models of the particulate nature of matter
Structure 1.1—Introduction to the particulate nature of matter
Guiding question |
How can we model the particulate nature of matter? |
Learning outcomes
After studying this topic you should be able to:
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IB Clarification Notes |
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Structure 1.2—The nuclear atom
Guiding question |
How do the nuclei of atoms differ? |
Learning outcomes
After studying this topic students should be able to:
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AHL |
AHL |
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IB Clarification Notes |
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Structure 1.3—Electron configurations
Guiding question |
How can we model the energy states of electrons in atoms? |
Learning outcomes
After studying this topic students should be able to:
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AHL |
AHL |
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IB Clarification Notes |
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Structure 1.4—Counting particles by mass: The mole.
Guiding question |
How do we quantify matter on the atomic scale? |
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Learning outcomes
After studying this topic, students should be able to
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temperature and pressure contain equal numbers of molecules.
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Structure 1.5—Ideal gases
Guiding question |
How does the model of ideal gas behaviour help us to predict the behaviour of real gases? |
Learning outcomes
After studying this topic, students should be able to
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IB Clarification Notes |
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Structure 2. Models of bonding and structure
Structure 2.1—The ionic model
Guiding question |
What determines the ionic nature and properties of a compound? |
Learning outcomes
After studying this topic students should be able to:
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IB Clarification Notes |
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Structure 2.2—The covalent model
Guiding question |
What determines the covalent nature and properties of a substance? |
Learning outcomes
After studying this topic students should be able to:
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AHL |
AHL |
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IB Clarification Notes |
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AHL
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Structure 2.3—The metallic model
Guiding question |
What determines the metallic nature and properties of an element |
Learning outcomes
After studying this topic students should be able to:
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AHL |
AHL |
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IB Clarification Notes |
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Structure 2.4—From models to materials
Guiding question |
What role do bonding and structure have in the design of materials? |
Learning outcomes
After studying this topic students should be able to:
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AHL |
AHL |
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IB Clarification Notes |
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Structure 3. Classification of matter
Structure 3.1 – The Periodic Table
Guiding question |
How does the periodic table help us to predict patterns and trends in the properties of the elements? |
Learning outcomes
After studying this topic students should be able to:
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AHL |
AHL |
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Structure 3.2 – Functional groups – classification of organic compounds
Guiding Question |
How does the classification of organic molecules help you to predict their properties? |
Learning Outcomes
After studying this topic you should be able to:
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AHL |
AHL |
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Reactivity: refers to how and why chemical reactions occur
Reactivity 1. What drives chemical reactions?
Reactivity 1.1—Measuring enthalpy changes.
Guiding Question |
What can be deduced from the temperature change that accompanies chemical or physical change? |
Learning outcomes.
After studying this topic students should be able to:
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IB Clarification Notes |
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Reactivity 1.2—Energy cycles in reactions
Guiding Question |
How does application of the law of conservation of energy help us to predict energy changes during reactions? |
Learning outcomes.
After studying this topic students should be able to:
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AHL |
AHL |
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ΔH⦵ = Σ ΔHf⦵products − Σ ΔHf⦵reactants
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IB Clarification Notes |
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ΔH⦵ = Σ ΔHf⦵products − Σ ΔHf ⦵reactants
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Reactivity 1.3—Energy from fuels
Guiding question |
What are the challenges of using chemical energy to address our energy needs? |
Learning outcomes
After studying this topic students should be able to:
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IB Clarification Notes |
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Reactivity 1.4—Entropy and spontaneity (AHL)
Guiding Question |
What determines the direction of chemical change? |
Learning outcomes
After studying this topic students should be able to:
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IB Clarification Notes |
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Reactivity 2. How much, how fast and how far?
Reactivity 2.1—How much? The amount of chemical change
Guiding Question |
How are chemical equations used to calculate reacting ratios? |
Learning outcomes
After studying this topic students should be able to:
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IB Clarification Notes |
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Reactivity 2.2—How fast? The rate of chemical change
Guiding question |
How can the rate of a reaction be controlled? |
Learning outcomes
After studying this topic students should be able to:
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AHL |
AHL |
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IB Clarification notes |
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AHL
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Reactivity 2.3—How far? The extent of chemical reaction
Guiding question |
How can the extent of a reversible reaction be influenced? |
Learning outcomes
After studying this topic students should be able to:
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AHL |
AHL |
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IB Clarification Notes |
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Reactivity 3 What are the mechanisms of chemical change?
Reactivity 3.1—Proton transfer reactions
Guiding question |
What happens when protons are transferred? |
Learning outcomes
After studying this topic you should be able to:
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AHL |
AHL |
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Reactivity 3.2— Electron transfer reactions
Guiding Question |
What happens when electrons are transferred? |
Learning outcomes
After studying this topic you should be able to:
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AHL |
AHL |
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Reactivity 3.3— Electron sharing reactions
Guiding question |
What happens when a species has an unpaired electron? |
Learning outcomes
After studying this topic you should be able to
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Reactivity 3.4— Electron-Pair Sharing Reactions
Guiding Question |
What happens when reactants share their electron pairs with others? |
Learning outcomes
After studying this topic you should be able to
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Apply your knowledge to |
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AHL |
AHL |
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