Check out my other resources at: www.tes.com/teaching-resources/shop/mr_science Designed for the new specification AQA GCSE(Spec point 4.5.1.1) course but can be modified for other exam boards. 16 slides covering Plant specialisation. By the end of the powerpoint students would have covered: -Define the key words, vector, displacement and scalar; -Be able to represent Vector quantities; -Determine the direction of a vector and magnitude from a scale diagram.

Check out my other resources at www.tes.com/teaching-resources/shop/mr_science Designed for the new specification AQA GCSE course (covers spec point 4.1.1.3) but can be modified for other exam boards. 13 slides covering Plant specialisation. By the end of the powerpoint students would have covered: -Describe how specialised cells in a plant carry out a particular function -Identify different parts of specialised plant cells and relate these identified parts to their function.

A simple sheet for students to tick off as students complete their required practical’s. Goes into the front of their practical books. Check out my other resources at www.tes.com/teaching-resources/shop/mr_science

A simple sheet for students to tick off as students complete their required practical’s. Goes into the front of their practical books. Check out my other resources at www.tes.com/teaching-resources/shop/mr_science

A simple sheet for students to tick off as students complete their required practicals. Goes into the front of their practical books. Check out my other resources at www.tes.com/teaching-resources/shop/mr_science

Check out my other resources at: www.tes.com/teaching-resources/shop/mr_science Designed for the new specification AQA GCSE course (covers spec point 4.1.1.3) but can be modified for other exam boards. 10 slides covering Animal cell specialisation . By the end of the powerpoint students would have covered: -Explain how cells become specialised through differentiation. -Why are animal cells specialised -Be able to link structure to function of different animal cells.

Designed for the new specification AQA GCSE course but can be modified for other exam boards. 15 slides covering Eukaryotic and prokaryotic cells . By the end of the powerpoint students would have covered: **4.1.1.1 Eukaryotes and prokaryotes ** Plant and animal cells (eukaryotic cells) have a cell membrane, cytoplasm and genetic material enclosed in a nucleus. Bacterial cells (prokaryotic cells) are much smaller in comparison. They have cytoplasm and a cell membrane surrounded by a cell wall. The genetic material is not enclosed in a nucleus. It is a single DNA loop and there may be one or more small rings of DNA called plasmids. Students should be able to demonstrate an understanding of the scale and size of cells and be able to make order of magnitude calculations, including the use of standard form.

Designed for the new specification AQA GCSE course but can be modified for other exam boards. 15 slides covering animal and plant cells. By the end of the powerpoint students would have covered: **4.1.1.2 Animal and plant cells ** Students should be able to explain how the main sub-cellular structures, including the nucleus, cell membranes, mitochondria, chloroplasts in plant cells and plasmids in bacterial cells are related to their functions. Most animal cells have the following parts: -a nucleus -cytoplasm -a cell membrane -mitochondria -ribosomes. In addition to the parts found in animal cells, plant cells often have: -chloroplasts -a permanent vacuole filled with cell sap. Plant and algal cells also have a cell wall made of cellulose, which strengthens the cell. Students should be able to use estimations and explain when they should be used to judge the relative size or area of sub-cellular structures.

Designed for the new specification AQA GCSE course but can be modified for other exam boards. 22 slides covering Microscopy: By the end of the powerpoint students would have covered (includes a required practical): Students should be able to: understand how microscopy techniques have developed over time explain how electron microscopy has increased understanding of sub-cellular structures. Limited to the differences in magnification and resolution. An electron microscope has much higher magnification and resolving power than a light microscope. This means that it can be used to study cells in much finer detail. This has enabled biologists to see and understand many more sub-cellular structures. Students should be able to carry out calculations involving magnification, real size and image size using the formula: magnification = size of image size of real object Students should be able to express answers in standard form if appropriate. Required practical activity 1: use a light microscope to observe, draw and label a selection of plant and animal cells. A magnification scale must be included.

Check out my other resources at: www.tes.com/teaching-resources/shop/mr_science 7 practice exam questions suitable for the new GCSE AQA specification. Great revision tool or could be used as a end of topic test.

A great simple resource to teach lipids, powerpoint contains exam questions and when I taught this lesson I used slides 6 and 12 for group activities. www.tes.com/teaching-resources/shop/mr_science

Lesson for lower ability class. Main worksheet can be found: https://www.tes.com/teaching-resource/leblanc-process-storyboard-ocr-c3-6329723

Designed for the new specification AQA GCSE course but can be modified for other exam boards. 32 slides covering Diffusion. (contains a optional practical) By the end of the powerpoint students would have covered: Substances may move into and out of cells across the cell membranes via diffusion. Diffusion is the spreading out of the particles of any substance in solution, or particles of a gas, resulting in a net movement from an area of higher concentration to an area of lower concentration. Some of the substances transported in and out of cells by diffusion are oxygen and carbon dioxide in gas exchange, and of the waste product urea from cells into the blood plasma for excretion in the kidney. Students should be able to explain how different factors affect the rate of diffusion. Factors which affect the rate of diffusion are: the difference in concentrations (concentration gradient) the temperature the surface area of the membrane. A single-celled organism has a relatively large surface area to volume ratio. This allows sufficient transport of molecules into and out of the cell to meet the needs of the organism. Students should be able to calculate and compare surface area to volume ratios. Students should be able to explain the need for exchange surfaces and a transport system in multicellular organisms in terms of surface area to volume ratio. Students should be able to explain how the small intestine and lungs in mammals, gills in fish, and the roots and leaves in plants, are adapted for exchanging materials. In multicellular organisms, surfaces and organ systems are specialised for exchanging materials. This is to allow sufficient molecules tobe transported into and out of cells for the organism’s needs. The effectiveness of an exchange surface is increased by: having a large surface area a membrane that is thin, to provide a short diffusion path (in animals) having an efficient blood supply (in animals, for gaseous exchange) being ventilated.