The lesson plan is presented in three sections: Gravity on Earth, Big Telescopes and Gravity in Space. Depending on the length of lessons in your school, these could be delivered as a single lesson or split into a series of two or three separate lessons.
Download all the relevant documents of the lesson plan. Start with the ‘Gravity PowerPoint Presentation’ and carry out the following three parts (or a specific part) after each section of the presentation.
PART 1: GRAVITY ON EARTH
Within the first section of this lesson/series of lessons, your students will first learn about the classical force of gravity, put forward by Newton. They will learn the difference between ‘mass’ and ‘weight’, the equation that links the two and investigate the strength of gravity on Earth.
This investigation can be performed in two ways. The first is to directly measure the acceleration due to gravity, by measuring the acceleration of an object in free fall. The other is to measure the strength of gravity on Earth by taking measurements of masses hanging from Newton meters.
Option 1: Free fall (Data logging)
The strength of gravity is also defined as the ‘acceleration due to gravity’. It is possible to directly measure the strength of gravity by measuring the acceleration of an object as it drops to the ground. For an experiment of this nature, we recommend a group size of three or four.
If you choose to run a free fall experiment, you may need to consider the following: - We recommend the following equipment set-up for this experiment: data logging equipment, using two light gates (option A below). However, it is also possible to work with a single light gate and a stopwatch (option B below). - Light gates are pieces of hardware. The data logging can be done with an additional piece of hardware (a data logger), or a piece of software running on a computer (to which the light gates are connected). - The author recommends uLog as a relatively economical and straightforward option to use, though many more are available. uLog light gates can be connected to a laptop or PC via USB, and they come with easy-to-use software. - Your light gate(s) will need to be mounted onto a clamp stand. Most light gates come with an attachment to do this. - Choose suitable objects to drop: smaller, denser objects work best as they are less affected by air resistance. Also, the objects will likely need to be a regular shape, e.g. a square. Please check what your data logging software recommends. - The data logging software will help your students to collect a high number of results. However, many of these results may be highly inaccurate, e.g. if the dropped object only falls through one light gate and misses the second, or falls at an awkward angle. To enable students to record successful and unsuccessful readings, we have provided a Data validity worksheet. By referring to this sheet for analysing their results, students can ignore their unsuccessful readings from the calculation of the average. - It may be possible to demonstrate that acceleration due to gravity is independent of the weight of the object being dropped (i.e. heavy objects do not fall quicker than light objects). This depends on students collecting good quality results in terms of accuracy. Provide students with a variety of objects of different weights, but similar sizes (exactly the same size if possible). For example, small blocks made out of wood or metal. However, ensure that the lightest objects are not light enough to be affected by air resistance. There should not be a correlation between weight and acceleration.
Depending on the equipment available in your school, it is possible to run a free fall experiment with one or two light gates. See more information on these options below.
A. Using data logging equipment with two connected light gates
Computer/laptop running data logging software
A pair of connected light gates
Regular shaped object to drop
The easiest way to complete a free fall experiment is with data logging equipment that uses two connected light gates. Attach the light gates to your clamp stand, one above the other. Drop an object through the light gates, making sure the object breaks the beams of both light gates. Most data logging software will directly calculate the acceleration of the object, provided the size of the object and the distance between the light gates are known. Please refer to your data logging software instructions on how to do this. Students can then copy their results to an Excel spreadsheet, where they can delete unsuccessful readings and/or anomalous data before calculating the average.
B. Using data logging equipment with a single light gate
If you do not have access to connected pairs of light gates, another option is to use a single light gate and a stopwatch.
Computer/laptop running data logging software
A light gate Clamp stand Stopwatch
Regular shaped object to drop
Attach your light gate to a clamp stand. Drop an object from a suitable height above the light gate. Use the stopwatch, and time how long it takes from the start of the drop to the object passing through the light gate. The height of the drop does not need to be known. The light gate should be used to take a measurement of the final speed of the object. Most data logging software will directly calculate the speed, provided the size of the object is known. The acceleration can then be calculated from the equation acceleration = (final speed - initial speed) ÷ time. Since the initial speed = zero (provided the object is dropped, not thrown), this simplifies to acceleration = final speed ÷ time.Students could enter their results into an Excel spreadsheet that calculates the acceleration for them, using this equation. Students can also delete unsuccessful readings and/or anomalous data before calculating their average.
If you do not have access to the required data logging equipment for the above, students could also measure the acceleration due to gravity by measuring, using a Newton meter, the amount of downward force (weight) on masses of different sizes.
Option 2: Newton meters
If light gates and data loggers are not available to you, students can measure the strength of gravity on Earth by taking measurements from masses hanging from Newton metres.
Variety of masses
By hanging different masses from Newton meters and reading off the weight, it is possible to calculate the strength of gravity in N/Kg, from the equation strength of gravity = weight ÷ mass. Students may get a variety of readings from different Newton meters. They may also get different readings if the masses attached are too low to stretch the spring, or if they are so large that they overstretch the spring. This will give students the opportunity to identify anomalous results and calculate a class average. For a Newton meter experiment, we recommend a group size of two.
PART 2: BIG TELESCOPES
In the second section of the lesson, students are briefly introduced to some of the big telescopes around the world (and in space). They are also presented with some of the astronomical questions relating to gravity that are still being investigated by astronomers.
Image 4: Bird’s Eye View of the Very Large Telescope. Credit: J.L. Dauvergne & G. Hüdepohl (atacamaphoto.com)/ESO
PART 3: GRAVITY IN SPACE
In the final section, students consider how gravity acts in space. They use a 3D model of gravity, similar to the model of general relativity put forward by Einstein, to better imagine the force of gravity and its effects.
Equipment needed Hula hoop Approx. 1m 2 (depends on size of hula hoop) of stretchy lycra material Bulldog clips Weights of different sizes and masses Small balls (e.g. marbles)
- Cut a section of stretchy lycra material so that it can be stretched taut over a hula hoop and secure it with bulldog clips or safety pins around the edge. This is now a 2D representation of spacetime, as developed by Einstein’s theory of general relativity.
- Hold up the hula hoop above the ground and place a mass on the lycra surface. A suitably heavy mass (e.g. 100 g to 500 g) will sink into the lycra, creating a curved surface around it.
- The mass represents a star or planet in space, and the curved lycra represents the gravity field around it. By rolling small balls (like marbles) around the weight, you will see that they follow a curved path – they are orbiting!
Image 5: Part 3 being demonstrated. Credit: Howard Barlow
Students should draw an analogy between the stretched lycra and an object’s gravity extending outwards into space and gradually getting weaker as the distance increases. This will hopefully work towards dispelling the misconception that gravity is binary, i.e. that it is ‘on’ at the surface of the Earth and ‘off’ when in space. This model actually represents the curved ‘spacetime’ of Einstein's theory of general relativity, published in 1916. In this theory, Einstein proposed that mass bends the spacetime around it, curving and stretching space and time (as opposed to the perfectly flat space in classical physics). Objects, e.g. planets or particles or rays of light, travelling near massive objects such as stars and other planets follow the curvature of space, so their path bends around these objects. We perceive this change of direction as the force of gravity pulling them. For this activity, we recommend a group size of three or four. An excellent (if very large scale!) demonstration of this activity can be found at: https://www.youtube.com/watch?v=MTY1Kje0yLg.
Examples of things to try:
These are listed on slide 25 of the accompanying PowerPoint, but more information is given below. 1. Place a second weight onto the lycra. The two weights will be attracted together, if they come too close to one another. 2. Experiment with the strength of the ‘gravity fields’ around weights of different masses. 3. Try to get a planet (a smaller, lighter ball such as a marble) to orbit around a star (a larger, heavier weight): a) By rolling the planet around the star. It’s possible to get one or two good orbits, but not many more. The planet will lose energy quickly and start spiralling into the star because of the friction of the fabric (there is no friction in space, so this does not occur). b) By applying small rotations. First, apply a bit of pressure to the star to hold it in place. Now those holding the hula hoop can rotate it in small circles. This will provide the force necessary to overcome the friction of the lycra and cause the planet to roll around (in real space there is no friction, so no constant driving force is required). The gravity of the star will constrain the planet and keep it in orbit. If the driving force is too strong, the planet will overcome gravity and fly off out into space. 4. Try to get a planet to orbit two stars in the shape of the figure eight (you may have to hold the stars in place to stop them attracting together). Many stars exist in binary systems. The figure of eight also represents the path the Apollo missions took to get to and from the Moon. 5. Consider the similarities and differences between this model and real life (for higher-achieving students). This model excellently demonstrates the pull of gravity in one plane; however, in reality gravity acts in three dimensions. Also, this model has a lot of friction, so objects lose energy quickly.