General
Combined Science
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GCSE Combined Science -
1.1 Cell Structure -
1.2 Cell Division -
1.3 Transport in Cells -
2.1 Principles of Organisation -
2.2 Animal Tissues, Organs and Organ Systems -
2.3 Plant Tissues, Organs and Systems -
3.1 Communicable Diseases -
4.1 Photosynthesis -
4.2 Respiration -
5.1 Homeostasis -
5.2 The Human Nervous System -
5.3 Hormonal Coordination in Humans -
6.1 Reproduction -
6.2 Variation and Evolution -
6.3 The Development of Understanding of Genetics and Evolution -
6.4 Classification of Living Organisms -
7.1 Adaptations, Interdependence and Competition -
7.2 Organisation of an Ecosystem -
7.3 Biodiversity and the Effect of Human Interaction on Ecosystems -
1.1 A Simple Model of the Atom, Symbols, Relative Atomic Mass, Electronic Charge and Isotopes -
1.2 The Periodic Table -
2.1 Chemical Bonds, Ionic, Covalent and Metallic -
2.2 How Bonding and Structure are Related to the Properties of Substances -
2.3 Structure and Bonding of Carbon -
3.1 Chemical Measurements, Conservation of Mass and the Quantitative Interpretation of Chemical Equations -
3.2 Use of Amount of Substance in Relation to Masses of Pure Substances -
4.1 Reactivity of Metals -
4.2 Reactions of Acids -
4.3 Electrolysis -
5.1 Exothermic and Endothermic Reactions -
6.1 Rate of Reaction -
6.2 Reversible Reactions and Dynamic Equilibrium -
7.1 Carbon Compounds as Fuels and Feedstock -
8.1 Purity, Formulations and Chromatography -
8.2 Identification of Common Gases -
9.1 The Composition and Evolution of the Earth's Atmosphere -
9.2 Carbon Dioxide and Methane as Greenhouse Gases -
9.3 Common Atmospheric Pollutants and Their Sources -
10.1 Using the Earth's Resources and Obtaining Potable Water -
10.2 Life Cycle Assessment and Recycling -
1.1 Energy Changes in a System, and the Ways Energy is Stored Before and After Such Changes -
1.2 Conservation and Dissipation of Energy -
1.3 National and Global Energy Resources -
2.1 Current, Potential Difference and Resistance -
2.2 Series and Parallel Circuits -
2.3 Domestic Uses and Safety -
2.4 Energy Transfers -
3.1 Changes of State and the Particle Model -
3.2 Internal Energy and Energy Transfers -
3.3 Particle Model and Pressure -
4.1 Atoms and Isotopes -
4.2 Atoms and Nuclear Radiation -
5.1 Forces and Their Interactions -
5.2 Work Done and Energy Transfer -
5.3 Forces and Elasticity -
5.4 Forces and Motion -
5.5 Momentum (HT only) -
6.1 Waves in Air, Fluids and Solids -
6.2 Electromagnetic Waves -
7.1 Permanent and Induced Magnetism, Magnetic Forces and Fields -
7.2 The Motor Effect
Biology: 1 Cell Biology
1.1.1 Eukaryotes and Prokaryotes
Plant and animal cells (eukaryotic cells) are complex structures that make up the bodies of plants, animals, fungi, and protists. They possess a nucleus that contains genetic material, along with a cell membrane, cytoplasm, and various organelles that perform specific functions within the cell.
Structure of Eukaryotic Cells
- Cell Membrane: Both plant and animal cells are enveloped by a cell membrane, also known as the plasma membrane. The cell membrane acts as a barrier, regulating the movement of substances in and out of the cell.
- Cytoplasm: The cytoplasm is the gel-like substance that fills the cell, surrounding the organelles. It contains various molecules, enzymes, and organelles necessary for cellular processes.
- Nucleus: The nucleus is the most prominent organelle in eukaryotic cells and is enclosed within a nuclear membrane. It houses the cell’s genetic material, including DNA, which carries instructions for cellular activities.
In our exploration of cellular structures, we now turn our attention to bacterial cells (prokaryotic cells). Unlike eukaryotic cells found in plants and animals, bacterial cells are single-celled organisms that are simpler in structure. They lack a defined nucleus and membrane-bound organelles but possess unique features that allow them to thrive in diverse environments.
Structure of Prokaryotic Cells
- Cell Membrane: The cell membrane, also known as the plasma membrane, is a thin barrier surrounding the bacterial cell. It regulates the movement of substances in and out of the cell.
- Cytoplasm: The cytoplasm is a gel-like substance that fills the bacterial cell and houses various cellular components. It contains enzymes, ribosomes, and other molecules necessary for cellular processes.
- Cell Wall: Bacterial cells have a cell wall outside the cell membrane. The cell wall provides structural support and protection for the cell. Unlike the cellulose-based cell walls of plant cells, bacterial cell walls are composed of peptidoglycan or other materials.
- Genetic Material: The genetic material in bacterial cells consists of a single, circular DNA molecule known as the nucleoid. The nucleoid is not enclosed within a nucleus but is instead found within the cytoplasm. Additionally, bacteria may contain small rings of DNA called plasmids, which can carry extra genes.
Bacterial cells are significantly smaller in size compared to eukaryotic cells. Eukaryotic cells typically range from 10 to 100 micrometres (μm) in diameter. Prokaryotic cells, such as bacteria, are generally smaller, ranging from 1 to 5 micrometres (μm) in length.
The size of cells is measured using units such as centimetres (cm), millimetres (mm), micrometres (μm), nanometers (nm), and picometers (pm).
- A centimetre (cm) is equal to one hundredth of a metre (10-2 m).
- A millimetre (mm) is equal to one thousandth of a metre (10-3 m).
- A micrometre (μm) is equal to one millionth of a metre (10-6 m).
- A nanometer (nm) is equal to one billionth of a metre (10-9 m).
- A picometer (pm) is equal to one trillionth of a metre (10-12 m).
Order of Magnitude Calculations
Orders of magnitude refer to the powers of 10 that indicate the scale or magnitude of a quantity. Moving up or down an order of magnitude means multiplying or dividing the quantity by a factor of 10.
Standard form is a way to express numbers as a product of a decimal number and a power of 10. It is written in the form: a × 10b, where “a” is a number between 1 and 10, and “b” is the power of 10.
Suppose we want to compare the size of a eukaryotic cell (20 μm) and a bacterial cell (2 μm). We can round them to the nearest power of 10: 20 μm ≈ 101 μm and 2 μm ≈ 100 μm. The difference in order of magnitude is 1, indicating that eukaryotic cells are approximately 10 times larger than bacterial cells.
Conclusion
Bacterial cells, as prokaryotes, are smaller and simpler in structure compared to eukaryotic cells. They lack a nucleus and membrane-bound organelles but possess essential components such as a cell membrane, cell wall, cytoplasm, and genetic material.