Difference between revisions of "PhET/C3/Rutherford-Scattering/English-timed"
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|| 02:19 | || 02:19 | ||
− | ||It shows a single atom with 3 into 10 to the power of -10 meter atomic scale. | + | ||It shows a single atom with '''3 into 10 to the power of -10 meter atomic scale'''. |
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|| 02:26 | || 02:26 | ||
− | || In the atom, red portion represents the positive charge which is uniformly distributed. | + | || In the atom, red portion represents the positive '''charge''' which is uniformly distributed. |
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|| 02:44 | || 02:44 | ||
− | || Screen on the right side shows 2 boxes, '''Legend''' and '''Alpha particle'''. | + | || '''Screen''' on the right side shows 2 boxes, '''Legend''' and '''Alpha particle'''. |
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|| 03:53 | || 03:53 | ||
− | ||This gives the most stable electrostatic arrangement. | + | ||This gives the most stable '''electrostatic''' arrangement. |
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|| 04:07 | || 04:07 | ||
− | || '''Plum Pudding''' model of an atom failed to explain | + | || '''Plum Pudding''' model of an atom failed to explain: |
− | + | the stability of an atom, | |
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|| 04:15 | || 04:15 | ||
− | || | + | || position of the nucleus in an atom. |
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|| 04:24 | || 04:24 | ||
− | ||But it provided the base | + | ||But it provided the base for the development of other atomic structure models. |
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|| 04:51 | || 04:51 | ||
− | ||Additionally there is an '''Atom''' box below '''Alpha Particle''' box. | + | ||Additionally, there is an '''Atom''' box below '''Alpha Particle''' box. |
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||04:56 | ||04:56 | ||
− | || '''Atom''' box consists of | + | || '''Atom''' box consists of '''Protons''' and '''Neutrons''' sliders to change the composition of the nucleus. |
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|| 05:04 | || 05:04 | ||
− | ||Here number of '''protons''' and '''neutrons''' is equal to that of gold atom. | + | ||Here, number of '''protons''' and '''neutrons''' is equal to that of gold atom. |
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|| 05:13 | || 05:13 | ||
− | ||It represents a zoom in view of different atoms in the gold foil. | + | ||It represents a '''zoom in''' view of different atoms in the gold foil. |
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|| 05:27 | || 05:27 | ||
− | || By default '''atomic view''' is selected. | + | || By default, '''atomic view''' is selected. |
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|| 05:31 | || 05:31 | ||
− | ||'''Atomic view''' gives an idea about | + | ||'''Atomic view''' gives an idea about the behavior of '''alpha''' particles as they travel through the atom. |
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||06:00 | ||06:00 | ||
− | || Now pause the '''simulation''' and click on '''Step''' button. | + | || Now, pause the '''simulation''' and click on '''Step''' button. |
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|| 06:15 | || 06:15 | ||
− | ||A very few '''alpha''' particles bounce back, that is deflected by nearly 180°. | + | ||A very few '''alpha''' particles bounce back, that is, deflected by nearly 180°. |
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|| 07:03 | || 07:03 | ||
− | ||Observe that | + | ||Observe that angles of deflection increases with the decrease in energy. |
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|| 07:09 | || 07:09 | ||
− | || Next we will see, how change in composition of nucleus | + | || Next we will see, how change in composition of nucleus affects scattering of '''alpha''' particles. |
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|| 07:16 | || 07:16 | ||
− | || | + | || Let's start with small nucleus with few number of '''protons''' and '''neutrons'''. |
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|| 07:50 | || 07:50 | ||
− | || Observe that | + | || Observe that '''alpha''' particles far from the nucleus have almost no detectable deflection. |
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|| 08:02 | || 08:02 | ||
− | || As an assignment, | + | || As an assignment, try various combinations of protons and neutrons and check the deflections. |
− | + | ||
− | + | ||
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|| 08:19 | || 08:19 | ||
− | || In this tutorial we have demonstrated | + | || In this tutorial, we have demonstrated how to use '''Rutherford Scattering''',''' PhET simulation'''. |
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|| 08:28 | || 08:28 | ||
− | || Using this '''simulation''' we have learnt | + | || Using this '''simulation''', we have learnt: about '''Plum pudding''' and '''Rutherford''' atomic models, |
− | + | ||
|- | |- | ||
|| 08:37 | || 08:37 | ||
− | || | + | ||to visualize the Rutherford gold foil experiment, |
|- | |- | ||
|| 08:41 | || 08:41 | ||
− | || | + | ||about behavior of '''alpha''' particles, |
|- | |- | ||
|| 08:45 | || 08:45 | ||
− | || | + | ||to identify the factors that affect the deflection of '''alpha''' particles. |
|- | |- | ||
|| 08:51 | || 08:51 | ||
− | || The video at the following link summarizes the Spoken Tutorial project. Please download and watch it. | + | || The video at the following link summarizes the '''Spoken Tutorial''' project. Please download and watch it. |
|- | |- | ||
|| 09:00 | || 09:00 | ||
− | || The '''Spoken Tutorial Project '''team | + | || The '''Spoken Tutorial Project '''team conducts workshops using spoken tutorials and gives certificates on passing online tests. |
− | + | ||
− | gives certificates on passing online tests. | + | |
|- | |- | ||
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|| 09:25 | || 09:25 | ||
− | || Spoken Tutorial Project is funded by NMEICT, MHRD, Government of India. | + | || Spoken Tutorial Project is funded by '''NMEICT, MHRD,''' Government of India. |
More information on this mission is available at this link. | More information on this mission is available at this link. |
Latest revision as of 23:38, 13 August 2018
Time | Narration |
00:01 | Welcome to this tutorial on Rutherford Scattering simulation. |
00:06 | In this tutorial, we will demonstrate Rutherford Scattering, PhET simulation. |
00:13 | Here I am using-
Ubuntu Linux OS version 14.04, |
00:20 | Java version 1.7.0, |
00:25 | Firefox Web Browser version 53.02.2 |
00:31 | To follow this tutorial, learner should be familiar with topics in high school science. |
00:39 | Using this simulation, we will learn: about Plum pudding and Rutherford atomic models, |
00:48 | to visualize the Rutherford gold foil experiment, |
00:52 | about behavior of alpha particles, |
00:56 | to identify the factors that affect the deflection of alpha particles. |
01:02 | Now let us start the demonstration. |
01:06 | Use the given link to download the simulation. |
01:11 | I have already downloaded Rutherford Scattering simulation to my Downloads folder. |
01:18 | To open the simulation, right click on Rutherford Scattering html file. |
01:26 | Select Open with Firefox Web Browser option. |
01:30 | File opens in the browser. |
01:33 | This is the interface of Rutherford Scattering simulation. |
01:38 | The interface has 2 screens- Rutherford Atom, Plum Pudding Atom. |
01:45 | Let's begin with Plum Pudding Atom screen. |
01:49 | J. J. Thomson proposed Plum Pudding atomic model. |
01:53 | This model was proposed before Rutherford's atomic model. |
01:58 | Click on Plum Pudding Atom screen to open it. |
02:02 | Left side of the screen has experimental set up for Plum Pudding atomic model. |
02:09 | It consists of thin sheet of a metal above the Alpha Particles source. |
02:15 | Center of the screen has view box. |
02:19 | It shows a single atom with 3 into 10 to the power of -10 meter atomic scale. |
02:26 | In the atom, red portion represents the positive charge which is uniformly distributed. |
02:33 | Small blue spheres represent electrons which are embedded in the atom. |
02:39 | There is no separation between positive charge and electrons in the atom. |
02:44 | Screen on the right side shows 2 boxes, Legend and Alpha particle. |
02:53 | Legend box helps to identify the key components of the atom. |
02:58 | Alpha Particle box consists of- an Energy slider to change the energy of incoming alpha particles, |
03:06 | Traces check-box to show an alpha particle's trajectory. |
03:11 | Check the Traces check-box. |
03:14 | Bottom of the screen we have, Play/Pause button, |
03:19 | Step button and Reset button. |
03:23 | To turn on the Alpha Particles source, click on the blue button. |
03:28 | Notice that alpha particles beam strikes the thin metal foil. |
03:33 | Observe the path of alpha particles inside the atom. |
03:37 | All the alpha particles pass through the atom un-deflected. |
03:42 | This is because electrons are distributed evenly throughout the atom. |
03:47 | The magnitude of negative and positive charges inside the atom is equal. |
03:53 | This gives the most stable electrostatic arrangement. |
03:57 | Therefore it makes an atom electrically neutral. |
04:01 | Plum Pudding model was able to explain overall neutrality of the atom. |
04:07 | Plum Pudding model of an atom failed to explain:
the stability of an atom, |
04:15 | position of the nucleus in an atom. |
04:19 | Plum Pudding model could not account for the atomic structure. |
04:24 | But it provided the base for the development of other atomic structure models. |
04:31 | Let's move on to Rutherford Atom screen. |
04:35 | Click on Rutherford Atom screen to open it. |
04:39 | Rutherford Atom screen helps to visualise the rutherford's gold foil experiment. |
04:45 | Rutherford Atom screen has same tools as that of Plum Pudding atom screen. |
04:51 | Additionally, there is an Atom box below Alpha Particle box. |
04:56 | Atom box consists of Protons and Neutrons sliders to change the composition of the nucleus. |
05:04 | Here, number of protons and neutrons is equal to that of gold atom. |
05:09 | At the centre of the screen, you will see a box. |
05:13 | It represents a zoom in view of different atoms in the gold foil. |
05:19 | Left side of the screen has 2 model views. |
05:23 | They are atomic view and nuclear view. |
05:27 | By default, atomic view is selected. |
05:31 | Atomic view gives an idea about the behavior of alpha particles as they travel through the atom. |
05:38 | Click on blue button to turn on the Alpha particles source. |
05:43 | Notice that alpha particles beam strikes the thin gold foil. |
05:48 | Check the Traces check-box to see the trajectories of alpha particles. |
05:54 | Observe the traces of alpha particles as they approach the nuclei of the atoms. |
06:00 | Now, pause the simulation and click on Step button. |
06:06 | Here, Most alpha particles are undeflected. |
06:11 | Some of the alpha particles are slightly deflected. |
06:15 | A very few alpha particles bounce back, that is, deflected by nearly 180°. |
06:22 | Let's see the behaviour of alpha particles in nuclear view. |
06:27 | Click on nuclear view. |
06:29 | Notice that in zoom in view, atoms are replaced by a single nucleus. |
06:35 | Now play the simulation. |
06:38 | Observe the deflections of alpha particles as they approach the nucleus. |
06:44 | Here n/p ratio for the gold atom is 1.5. Therefore alpha particles show a large deflection. |
06:53 | Let's study the factors that affect the scattering of alpha particles. |
06:59 | Drag the Energy slider towards minimum. |
07:03 | Observe that angles of deflection increases with the decrease in energy. |
07:09 | Next we will see, how change in composition of nucleus affects scattering of alpha particles. |
07:16 | Let's start with small nucleus with few number of protons and neutrons. |
07:22 | Drag the Energy slider back to its default position. |
07:27 | Then drag the Protons and Neutrons sliders towards 20. |
07:32 | Size of the nucleus becomes small. |
07:35 | Observe the angles of deflection of alpha particles. |
07:39 | Angle of deflection decreases with the decrease in protons and neutrons number. |
07:45 | Here atom is stable as n /p ratio is 1. |
07:50 | Observe that alpha particles far from the nucleus have almost no detectable deflection. |
07:57 | While the alpha particles that are close to the nucleus are deflected. |
08:02 | As an assignment, try various combinations of protons and neutrons and check the deflections. |
08:10 | Give an explanation for the change in the behaviour of the alpha particles. |
08:16 | Let us summarise. |
08:19 | In this tutorial, we have demonstrated how to use Rutherford Scattering, PhET simulation. |
08:28 | Using this simulation, we have learnt: about Plum pudding and Rutherford atomic models, |
08:37 | to visualize the Rutherford gold foil experiment, |
08:41 | about behavior of alpha particles, |
08:45 | to identify the factors that affect the deflection of alpha particles. |
08:51 | The video at the following link summarizes the Spoken Tutorial project. Please download and watch it. |
09:00 | The Spoken Tutorial Project team conducts workshops using spoken tutorials and gives certificates on passing online tests. |
09:09 | For more details, please write to us. |
09:13 | Please post your timed queries on this forum. |
09:17 | This project is partially funded by Pandit Madan Mohan Malaviya National Mission on Teachers and Teaching. |
09:25 | Spoken Tutorial Project is funded by NMEICT, MHRD, Government of India.
More information on this mission is available at this link. |
09:38 | This is Meenal Ghoderao from IIT Bombay.
Thank you for joining. |