Difference between revisions of "ExpEYES/C2/Conductivity-of-ionic-solutions/English-timed"
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(Created page with "{| border=1 ||'''Time''' ||'''Narration''' |- |00:01 | Hello everyone.Welcome to this tutorial on '''Conductivity of ionic solutions'''. |- |00:07 |In this tutorial we will...") |
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|00:01 | |00:01 | ||
− | | Hello everyone.Welcome to this tutorial on '''Conductivity of ionic solutions'''. | + | | Hello everyone. Welcome to this tutorial on '''Conductivity of ionic solutions'''. |
|- | |- | ||
|00:07 | |00:07 | ||
− | |In this tutorial we will learnt to: | + | |In this tutorial, we will learnt to: |
− | + | Measure '''Conductivity''' and | |
− | + | Calculate the '''resistance''' of ionic solutions. | |
− | + | ||
|- | |- | ||
|00:15 | |00:15 | ||
− | |Here I am using | + | |Here, I am using: |
− | + | '''ExpEYES''' version 3.1.0 | |
− | + | '''Ubuntu Linux OS''' version 14.04 | |
|- | |- | ||
|00:23 | |00:23 | ||
− | |To follow this tutorial, you should be familiar with | + | |To follow this tutorial, you should be familiar with '''ExpEYES Junior''' interface. |
− | + | ||
− | '''ExpEYES''' | + | |
If not, for relevant tutorials, please visit our website. | If not, for relevant tutorials, please visit our website. | ||
|- | |- | ||
|00:35 | |00:35 | ||
− | |Let's first define conductivity of a solution. | + | |Let's first define '''conductivity''' of a solution. |
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|00:56 | |00:56 | ||
− | |I will explain the circuit connections.'''A1''' is connected to '''SINE'''. | + | |I will explain the '''circuit''' connections. '''A1''' is connected to '''SINE'''. |
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|01:08 | |01:08 | ||
− | |'''10K''' | + | |A '''10K resistor''' is connected between '''A2''' and '''GND'''. This is the circuit diagram. |
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|01:20 | |01:20 | ||
− | |On the '''Plot window''', click on '''A1''' and drag to '''CH1'''.'''A1''' is assigned to '''CH1'''. | + | |On the '''Plot window''', click on '''A1''' and drag to '''CH1'''. '''A1''' is assigned to '''CH1'''. |
|- | |- | ||
|01:28 | |01:28 | ||
− | |Click on '''A2''' | + | |Click on '''A2''' and drag to '''CH2'''. |
'''A2''' is assigned to '''CH2'''. | '''A2''' is assigned to '''CH2'''. | ||
|- | |- | ||
|01:35 | |01:35 | ||
− | |Move the '''mSec/div''' slider to adjust the waves.Two sine waves are generated. | + | |Move the '''mSec/div''' slider to adjust the waves. Two '''sine''' waves are generated. |
|- | |- | ||
|01:43 | |01:43 | ||
− | |Black trace is the original sine wave.Red trace is conductivity of tap water. | + | |Black trace is the original '''sine''' wave. Red trace is '''conductivity''' of tap water. |
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|01:50 | |01:50 | ||
− | |Click on '''CH1''' and drag to '''FIT'''.Click on '''CH2''' and drag to '''FIT'''. | + | |Click on '''CH1''' and drag to '''FIT'''. Click on '''CH2''' and drag to '''FIT'''. |
|- | |- | ||
|01:56 | |01:56 | ||
− | |Observe the voltage and frequency values on the right side of the window.Notice that voltage of tap water is very less compared to the input voltage. | + | |Observe the voltage and frequency values on the right side of the window. Notice that voltage of tap water is very less compared to the '''input voltage'''. |
|- | |- | ||
|02:08 | |02:08 | ||
− | |Right click on '''CH1''' to see voltages and Phase difference in degree. | + | |Right click on '''CH1''' to see voltages and '''Phase''' difference in degree. |
|- | |- | ||
|02:15 | |02:15 | ||
− | |Now we will | + | |Now we will measure conductivity of '''copper sulphate''' solution. To make the solution, one spatula of copper sulphate is dissolved in 100 ml of water. |
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|02:34 | |02:34 | ||
− | |On the '''Plot window''' we can see the conductivity curve. | + | |On the '''Plot window''' we can see the '''conductivity curve'''. |
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|02:42 | |02:42 | ||
− | |Increased conductivity | + | |Increased conductivity is due to '''copper''' and '''sulphate''' ions present in the solution. |
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|02:48 | |02:48 | ||
− | |Observe the voltage and frequency values on the right. | + | |Observe the '''voltage''' and '''frequency''' values on the right. |
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|02:59 | |02:59 | ||
− | |Now we will measure conductivity of dilute sulphuric acid solution.A few drops of dilute sulphuric acid are added to water. | + | |Now, we will measure conductivity of dilute sulphuric acid solution. A few drops of dilute sulphuric acid are added to water. |
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|03:09 | |03:09 | ||
− | |Wires are dipped in sulphuric acid solution.Let's see the result on the Plot window. | + | |Wires are dipped in sulphuric acid solution. Let's see the result on the '''Plot window.''' |
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|03:23 | |03:23 | ||
− | |Conductivity of tap water has increased | + | |Conductivity of tap water has increased on adding a few drops of dilute sulphuric acid. |
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|03:41 | |03:41 | ||
− | |We will measure conductivity of dilute Potassium hydroxide solution.A few drops of dilute Potassium hydroxide solution are added to tap water. | + | |We will measure conductivity of dilute '''Potassium hydroxide''' solution. A few drops of dilute Potassium hydroxide solution are added to tap water. |
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|03:58 | |03:58 | ||
− | |Notice the increased conductivity of | + | |Notice the increased conductivity of tap water on adding a few drops of Potassium hydroxide solution. |
− | tap water on adding a few drops of Potassium hydroxide solution. | + | |
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|04:18 | |04:18 | ||
− | |Using the voltage values we have calculated the resistance of ionic solutions and tabulated the results. | + | |Using the voltage values we have calculated the resistance of '''ionic''' solutions and tabulated the results. |
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|04:27 | |04:27 | ||
− | |Resistance value for tap water is '''7.7 KOhm''' | + | |Resistance value for tap water is '''7.7 KOhm''' (kilo ohm). |
− | Resistance value for | + | Resistance value for copper sulphate solution is '''1.2 KOhm'''. |
− | + | ||
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|04:38 | |04:38 | ||
− | | | + | | Sulphuric acid solution is '''0.17 KOhm''' and potassium hydroxide solution is '''0.14 KOhm'''. |
Notice that resistance values decreased with the increase in ionic concentration. | Notice that resistance values decreased with the increase in ionic concentration. | ||
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|04:57 | |04:57 | ||
− | |In this tutorial we have learnt to: | + | |In this tutorial, we have learnt to: |
− | + | Measure Conductivity and Calculate the '''resistance''' of '''ionic''' solutions. | |
− | + | ||
|- | |- | ||
|05:06 | |05:06 | ||
− | |As an assignment, | + | |As an assignment,Using sodium hydroxide, acetic acid and sodium chloride solutions measure conductivity and calculate the resistance of ionic solutions. |
− | + | ||
− | + | ||
− | + | ||
|- | |- | ||
|05:18 | |05:18 | ||
− | |This video | + | |This video summarizes the Spoken Tutorial project. If you do not have good bandwidth, you can download and watch it. |
|- | |- | ||
|05:26 | |05:26 | ||
− | |We conduct workshops using Spoken Tutorials and give certificates. Please contact us. | + | |We conduct workshops using '''Spoken Tutorials''' and give certificates. Please contact us. |
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|05:39 | |05:39 | ||
− | |This tutorial is contributed by Kaushik Datta and Madhuri Ganapathi. Thank you for joining. | + | |This tutorial is contributed by Kaushik Datta and Madhuri Ganapathi.Thank you for joining. |
|} | |} |
Latest revision as of 17:06, 27 March 2017
Time | Narration |
00:01 | Hello everyone. Welcome to this tutorial on Conductivity of ionic solutions. |
00:07 | In this tutorial, we will learnt to:
Measure Conductivity and Calculate the resistance of ionic solutions. |
00:15 | Here, I am using:
ExpEYES version 3.1.0 Ubuntu Linux OS version 14.04 |
00:23 | To follow this tutorial, you should be familiar with ExpEYES Junior interface.
If not, for relevant tutorials, please visit our website. |
00:35 | Let's first define conductivity of a solution. |
00:38 | Conductivity of a solution is a measure of its ability to conduct electricity. |
00:44 | Conductivity of water is directly related to the concentration of ions dissolved in it. |
00:51 | Now we will demonstrate conductivity of tap water. |
00:56 | I will explain the circuit connections. A1 is connected to SINE. |
01:02 | Wires from SINE and A2 are dipped in glass tumbler containing tap water. |
01:08 | A 10K resistor is connected between A2 and GND. This is the circuit diagram. |
01:16 | Let's see the result on the Plot window. |
01:20 | On the Plot window, click on A1 and drag to CH1. A1 is assigned to CH1. |
01:28 | Click on A2 and drag to CH2.
A2 is assigned to CH2. |
01:35 | Move the mSec/div slider to adjust the waves. Two sine waves are generated. |
01:43 | Black trace is the original sine wave. Red trace is conductivity of tap water. |
01:50 | Click on CH1 and drag to FIT. Click on CH2 and drag to FIT. |
01:56 | Observe the voltage and frequency values on the right side of the window. Notice that voltage of tap water is very less compared to the input voltage. |
02:08 | Right click on CH1 to see voltages and Phase difference in degree. |
02:15 | Now we will measure conductivity of copper sulphate solution. To make the solution, one spatula of copper sulphate is dissolved in 100 ml of water. |
02:27 | In the same connection, wires from SINE and A2 are dipped in copper sulphate solution. |
02:34 | On the Plot window we can see the conductivity curve. |
02:38 | Red trace is conductivity of copper sulphate solution. |
02:42 | Increased conductivity is due to copper and sulphate ions present in the solution. |
02:48 | Observe the voltage and frequency values on the right. |
02:52 | Right click on CH1 to see voltages and Phase difference values. |
02:59 | Now, we will measure conductivity of dilute sulphuric acid solution. A few drops of dilute sulphuric acid are added to water. |
03:09 | Wires are dipped in sulphuric acid solution. Let's see the result on the Plot window. |
03:17 | Observe that black and red traces are almost coinciding with each other. |
03:23 | Conductivity of tap water has increased on adding a few drops of dilute sulphuric acid. |
03:30 | Observe the voltage and frequency values on the right. |
03:34 | Right click on CH1 to see voltages and Phase difference in degree. |
03:41 | We will measure conductivity of dilute Potassium hydroxide solution. A few drops of dilute Potassium hydroxide solution are added to tap water. |
03:52 | We can see that black and red traces are almost coinciding with each other. |
03:58 | Notice the increased conductivity of tap water on adding a few drops of Potassium hydroxide solution. |
04:05 | Observe the voltage and frequency values on the right side of the window. |
04:11 | Right click on CH1 to see voltages and Phase difference in degree. |
04:18 | Using the voltage values we have calculated the resistance of ionic solutions and tabulated the results. |
04:27 | Resistance value for tap water is 7.7 KOhm (kilo ohm).
Resistance value for copper sulphate solution is 1.2 KOhm. |
04:38 | Sulphuric acid solution is 0.17 KOhm and potassium hydroxide solution is 0.14 KOhm.
Notice that resistance values decreased with the increase in ionic concentration. |
04:55 | Let's summarize. |
04:57 | In this tutorial, we have learnt to:
Measure Conductivity and Calculate the resistance of ionic solutions. |
05:06 | As an assignment,Using sodium hydroxide, acetic acid and sodium chloride solutions measure conductivity and calculate the resistance of ionic solutions. |
05:18 | This video summarizes the Spoken Tutorial project. If you do not have good bandwidth, you can download and watch it. |
05:26 | We conduct workshops using Spoken Tutorials and give certificates. Please contact us. |
05:32 | The Spoken Tutorial Project is funded by NMEICT, MHRD Government of India. |
05:39 | This tutorial is contributed by Kaushik Datta and Madhuri Ganapathi.Thank you for joining. |