Difference between revisions of "GChemPaint/C3/Features-and-Color-Schemes/English"

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Author: '''Madhuri Ganapathi'''
 
Author: '''Madhuri Ganapathi'''
  
Key words: '''Periodic table of the element buttons, Elemental window, Color Schemes ,Video tutorial, Video tutorial'''
+
Key words: '''Periodic table of the element buttons, Elemental window, Color Schemes, Video tutorial'''
 +
 
  
 
<font size="2">
 
<font size="2">
Line 25: Line 26:
 
* GChemTable
 
* GChemTable
  
* Elemental window
+
* Elemental window and
  
 
* Color schemes.
 
* Color schemes.
Line 32: Line 33:
  
 
'''System Requirement'''
 
'''System Requirement'''
||Here I am using
+
||For this tutorial  I am using,
  
 
'''Ubuntu Linux''' OS version 12.04.
 
'''Ubuntu Linux''' OS version 12.04.
  
'''GChemPaint''' version 0.12.10.
+
'''GChemPaint''' version 0.12.10.and
  
'''GChemTable version 0.12.10'''
+
'''GChemTable''' version 0.12.10.
  
 
|-
 
|-
Line 48: Line 49:
 
* '''Periodic table of elements''' and
 
* '''Periodic table of elements''' and
  
* '''GChemPaint'''
+
* '''GChemPaint'''.
  
For relevant  '''GChemPaint''' tutorials, please visit our website.  
+
If not, for relevant  '''GChemPaint''' tutorials, please visit our website.  
 
|-
 
|-
 
||
 
||
||Now let's learn about GChemTable application.
+
||Let's now learn about '''GChemTable''' application.
 
|-
 
|-
||Slide Number 5
+
||'''Slide Number 5'''
Installation
+
||GChemTable
+
  
can be installed as a utility software of GChemPaint
+
'''Installation'''
 +
||'''GChemTable'''
  
using Synaptic Package Manager.
+
* can be installed as a utility software of '''GChemPaint'''
 +
 
 +
* using '''Synaptic Package Manager'''.
 
|-
 
|-
||Slide Number 6
+
||'''Slide Number 6'''
  
About GChemTable
+
''About GChemTable'''
||GChemTable is a chemical elements Periodic table application.  
+
||'''GChemTable''' is a chemical elements '''Periodic table''' application.  
  
It provides scientific information about elements
+
It provides scientific information about elements.
  
It shows Periodic table with different Color schemes.
+
It shows '''Periodic table''' with different '''Color schemes'''.
 
|-
 
|-
||Click on Dash Home type GChem3D in the search bar>>
+
||Click on '''Dash Home''' type '''GChem3D''' in the search bar>>
  
Click on Periodic table of the elements icon.
+
Click on '''Periodic table of the elements''' icon.
||To open GchemTable, click on Dash Home.
+
||To open '''GChemTable''', click on '''Dash Home'''.
  
In the search bar that appears type “gchemtable”.  
+
In the search bar that appears type '''"gchemtable"'''.  
  
Click on Periodic table of the elements icon.
+
Click on '''Periodic table of the elements''' icon.
 
|-
 
|-
||Point to Periodic table of the elements window.
+
||Move the cursor on  '''Periodic table of the elements''' window.
 +
||'''Periodic table of the elements''' window opens.
 +
|-
 +
||Point to Menubar
 +
||'''GChemTable''' window has '''Menubar''' like all window based applications.  
  
Point to Menubar
+
'''Menubar''' contains all the commands you need to work with '''GChemTable'''.
||
+
GChemTable window has Menubar like all window based programs.
+
Menubar contains all the commands you need to work with GChemTable.
+
 
|-
 
|-
 
||Point to the table
 
||Point to the table
 +
 
point to element buttons
 
point to element buttons
||This is the Periodic table.
+
||This is a '''Periodic table of elements''', here you can see element buttons.  
Here you can see element buttons.  
+
 
|-
 
|-
 
||Place the cursor on the element button.
 
||Place the cursor on the element button.
||To get the name of the element, place the cursor on the element button.
+
||To get the name of the element, place the cursor on the element.
 
|-
 
|-
 
||Point to the buttons.
 
||Point to the buttons.
 +
 
Point to the table.
 
Point to the table.
 
||Colors used for buttons in the table are conventional colors of the elements.
 
||Colors used for buttons in the table are conventional colors of the elements.
This table is a replica of Modern Periodic table.
+
 
 +
This table is a replica of '''Modern Periodic table'''.
 
|-
 
|-
 
||
 
||
||Now let's learn about Elemental window.
+
||Now let's learn about '''Elemental window'''.
 
|-
 
|-
||Click on any element button on the periodic table.  
+
||Click on any element button on the periodic table.  
 
||To display it, click on any element button on the periodic table.  
 
||To display it, click on any element button on the periodic table.  
I will click on Carbon(C)
+
 
Elemental window of Carbon opens.
+
I will click on '''Carbon(C)'''
 +
 
 +
'''Elemental window''' of '''Carbon''' opens.
 
|-
 
|-
 
||Point to the sides
 
||Point to the sides
||Elemental Window contains four side tabs  
+
||'''Elemental Window''' contains four side tabs  
  
 
* Main,  
 
* Main,  
Line 123: Line 130:
 
|-
 
|-
 
||Point to the Main tab
 
||Point to the Main tab
 +
 
point to all the components one by one.
 
point to all the components one by one.
||By default Main tab is selected.
+
||By default '''Main''' tab is selected.
  
It has Symbol of the element,  
+
* It has Symbol of the element,  
  
Atomic number,  
+
* Atomic number,  
  
Atomic weight and
+
* Atomic weight and
  
Electronic configuration.
+
* Electronic configuration.
 
|-
 
|-
 
||Point to the headings
 
||Point to the headings
||It has a table with headings Lang and Name
+
||It has a table with headings '''Lang''' and '''Name'''
  
Table shows Carbon's name in various languages.  
+
Table shows '''Carbon's''' name in various languages.  
 
|-
 
|-
||
+
||Click on '''Electronic properties''' tab
||Next click on Electronic properties tab
+
||Next click on '''Electronic properties''' tab
 
|-
 
|-
||Point to  electronegativity value
+
||Point to  '''electronegativity''' value
Ionisation energies
+
 
Electronic affinities
+
'''Ionization energies'''
 +
 
 +
'''Electronic affinities'''
 
||This tab shows details about  
 
||This tab shows details about  
Pauling electronegativity value
+
 
Ionisation energies  in- MJ per mol.
+
'''Pauling electro-negativity''' value.
first, second and third ionisation energies.  
+
 
Electronic affinities in KJ per mol.
+
'''Ionization energies''',  
 +
 
 +
first, second and third '''Ionization energies''' in '''MJ per mol'''.  
 +
 
 +
'''Electronic affinities''' in '''KJ per mol'''.
 
|-
 
|-
 
||Point to the buttons
 
||Point to the buttons
 +
 
Click on the buttons.
 
Click on the buttons.
 +
 
Point to the displayed chart.
 
Point to the displayed chart.
||On the rightside corresponding Show curve buttons are seen.
+
||On the rightside corresponding '''Show curve''' buttons are seen.
Click on Show curve button to view the Chart.   
+
 
 +
Click on '''Show curve''' button to view the Chart.   
 
|-
 
|-
||Point to close button.
+
||Point to the chart.
 +
||This is the chart of ''' Electronegativity''' versus '''Atomic number(Z)'''.
 +
|-
 +
||Point to '''Close''' button.
 
||I will close the chart.
 
||I will close the chart.
 
|-
 
|-
||Click on Radii tab
+
||Click on '''Radii''' tab
 +
 
 
Point to the values
 
Point to the values
||Next click on Radii tab
+
||Click on '''Radii''' tab
 +
 
 
This tab shows  
 
This tab shows  
Covalent,  
+
 
Vander waals and  
+
* Covalent,  
Metallic radii values in pm.
+
 
'pm' is pico metre= 10-12m.
+
* Van der Waals and  
Since Carbon is non-metal it does not have metallic radii value.
+
 
 +
* Metallic radii values all in 'pm'.
 +
 
 +
'pm' is '''pico metre= 10<sup>-12</sup>m'''
 +
 
 +
(10 to the power of minus 12 metres).
 +
 
 +
Since '''Carbon''' is a non-metal it does not have '''Metallic radius''' value.
 
|-
 
|-
||Point to close button.
+
||Point to '''Close''' button.
||I will close the Carbon window.
+
||I will close the '''Carbon''' window.
 
|-
 
|-
||Click on Sodium(Na) button>>Click on Radii tab.
+
||Point to '''Periodic table of the elements''' window.
||Let's click on Sodium(Na) button.
+
||Let's go back to the '''Periodic table of the elements''' window.
Click on Radii tab.
+
Metallic radii value is shown here.
+
 
|-
 
|-
||Point to the table columns.
+
||Click on '''Sodium(Na)''' button>>Click on '''Radii''' tab.
||Radii tab shows a table of Ionic radii.
+
||Let's click on '''Sodium(Na)''' button.
Table contains Ion, C.N,  Value as columns
+
 
Let's scroll down the table.
+
Click on '''Radii''' tab.
|-
+
 
||Point to close button.
+
'''Metallic radii''' value is shown here.
||I will close the Carbon window.
+
|-
+
||Click on Sodium(Na) button>>Click on Radii tab.
+
||Let's click on Sodium(Na) button.
+
Click on Radii tab.
+
Metallic radii value is shown here.
+
 
|-
 
|-
 
||Point to the table columns.
 
||Point to the table columns.
||Radii tab shows a table of Ionic radii.
+
||'''Radii''' tab shows a table of '''Ionic radii'''.
Table contains Ion, C.N, Value as columns
+
 
 +
This table contains '''Ion, C.N''', and '''Value''' as columns
 +
 
 
Let's scroll down the table.
 
Let's scroll down the table.
 
|-
 
|-
||Point to CN and Value columns.
+
||Point to '''Ion CN''' and '''Value''' columns.
 
||This table gives information about  
 
||This table gives information about  
different Ionic states that Sodium exists in.
+
 
Its coordination number(CN) and  
+
* different Ionic states '''Sodium''' exists in.
Ionic radii value in pm.
+
 
 +
* Its '''Coordination number(CN)''' and
 +
 
 +
* '''Ionic radii''' value in 'pm'.
 
|-
 
|-
||Point to close button.
+
||Point to the Element buttons.
||Let's close Sodium elemental window.
+
||Elements '''Chromium, Manganese, Iron, Cobalt, Nickel''' and '''Copper''' have a tendency to form a large complexes.  
 
|-
 
|-
||Point to the element buttons.
+
||Click on '''Iron''' button.
||Elements Chromium, Manganese, Iron, Cobalt, Nickel and Copper have a tendency to form a large complexes.
+
 
|-
+
Point to the Elemental window.
||Click on Iron button.
+
||Let's click on '''Iron(Fe)''' button.
Point to the elemental window.
+
 
||Let's click on Iron(Fe} button.
+
 
Its elemental window opens
 
Its elemental window opens
 
|-
 
|-
||Click on Radii tab.
+
||Click on '''Radii''' tab.
||Ionic radii table has an extra column named Spin.Click on Radii tab
+
||Click on the '''Radii''' tab.
 +
 
 +
'''Ionic radii''' table has an extra column named '''Spin.'''
 
|-
 
|-
||Point to Spin column
+
||Point to '''Spin''' column
||Spin column gives idea about complex formation tendency of Iron.
+
||'''Spin''' column gives idea about complex formation tendency of Iron.
 
|-
 
|-
 
||Point to High and Low
 
||Point to High and Low
||Here High means spin free complexes where electrons are unpaired.↑ ↑ ↑ ↑
+
||Here '''High''' means spin free complexes where electrons are unpaired.↑ ↑ ↑ ↑
  
Low means spin paired complexes where electrons are paired up. ⇅ ⇅ ⇅ ⇅
+
'''Low''' means spin paired complexes where electrons are paired up. ⇅ ⇅ ⇅ ⇅
 
|-
 
|-
||Point to close button.
+
||Point to '''Close''' button.
||I will close the elemental window of Iron(Fe}
+
||I will close '''Iron(Fe)''' elemental window.
 +
 
 
|-
 
|-
||Point to the link.
+
||'''Slide Number 7'''
||More details about complex formation are available at this link
+
 
 +
'''Complex Formation'''
 +
 
 +
Point to the link.
 +
||More details about complex formation are available at this link
  
 
'''http://en.wikipedia.org/wiki/Spin_states_d_electrons'''.
 
'''http://en.wikipedia.org/wiki/Spin_states_d_electrons'''.
 
|-
 
|-
||Click again on the elemental window of Carbon.
+
||Click again on the '''Elemental window''' of '''Carbon'''.
||Let's click again on the elemental window of Carbon.
+
||Click again on the '''Elemental window''' of '''Carbon'''.
 
|-
 
|-
||Click on Thermodynamics tab
+
||Click on '''Thermodynamics''' tab
Point to  Melting Point and Boiling point
+
 
||Click on Thermodynamics tab
+
Point to  '''Melting Point''' and '''Boiling point'''
This shows Melting Point and Boiling point of Carbon.
+
||Click on '''Thermodynamics''' tab
 +
 
 +
This tab shows '''Melting Point''' and '''Boiling point''' of '''Carbon'''.
 
|-
 
|-
||Assignment
+
||'''Assignment'''
||Explore Show curve button on your own.
+
||Explore '''Show curve''' button on your own.
 
|-
 
|-
||Point to Close button.
+
||Point to '''Close''' button.
||Let's close the window.
+
||I will close the '''Carbon''' elemental window.
 
|-
 
|-
 
||
 
||
||Now let's move on to Color schemes.
+
||Now let's move on to '''Color schemes'''.
 
|-
 
|-
||Go View menu and select Color scheme.
+
||Go '''View''' menu and select '''Color scheme'''.
||Go View menu, select Color scheme.
+
||Go '''View''' menu and select '''Color schemes'''.
 
|-
 
|-
||Click on No colors.
+
||Point to the submenu.
 +
||A submenu opens with a list of '''Color schemes'''.
 +
|-
 +
||Click on '''No colors'''.
 +
 
 
Point to element buttons.
 
Point to element buttons.
||Click on No colors
+
||Click on '''No colors'''
All element buttons turn to grey.
+
 
 +
All element buttons turn to '''grey'''.
 
|-
 
|-
||Click on  Color Schemes.
+
||Click on  '''Color Scheme'''.
Select Physical states.
+
 
||
+
Select '''Physical states'''.
Click on  Color Schemes.
+
||Click on  '''Color Schemes''' and select '''Physical states'''.
Select Physical states.
+
 
|-
 
|-
 
||Move the cursor on the table.
 
||Move the cursor on the table.
||A new periodic table opens with elements buttons in Blue color.
+
||A new '''Periodic table''' opens with elements buttons in "Blue" color.
Except for some in Black.
+
 
 +
Except for some in "Black".
 
|-
 
|-
 
||Point to the scale slider
 
||Point to the scale slider
||On the top you can see a Temperature(K): scale slider with zero(0) as minimum value.
+
||On the top you can see '''Temperature(K):''' scale slider with "zero(0)" as minimum value.
 
|-
 
|-
 
||Point to colors of solid, liquid and gas.
 
||Point to colors of solid, liquid and gas.
||Below you can see colors of Solid- Blue, Liquid- Green and Gas-Red.
+
||Below you can see colors of "Solid-Blue", "Liquid-Green" and "Gas-Red".
 
|-
 
|-
||Point to 0K
+
||Point to 0K>>point to color.
point to color.
+
||At '''zero degree Kelvin''' all the elements are in solid state.
||At zero degree Kelvin all the elements are in solid state.
+
 
So they appear in blue color.
+
So they appear in 'blue' color.
 
|-
 
|-
 
||Drag the slider.
 
||Drag the slider.
Line 282: Line 321:
 
Point to the colors
 
Point to the colors
 
||Let's drag the slider to increase the temperature.  
 
||Let's drag the slider to increase the temperature.  
Notice that elements change their physical state.
 
  
Blue color is replaced by Green(liquid) and Red(Gas) colors.
+
Notice that elements change their '''Physical state'''.
 +
 
 +
"Blue" color is replaced by '''Green(liquid)''' and '''Red(Gas)''' colors.
 
|-
 
|-
||Point to 6010K
+
||Point to 6010K>>point to color.
point to color.
+
||At '''6010 degree Kelvin'''(six thousand ten) all the elements change to gaseous state.
||At 6010 Kelvin all the elements change to gaseous state.
+
 
All the buttons change to Red color.
+
All the buttons change to "Red" color.
 
|-
 
|-
 
||Point to color.
 
||Point to color.
||Some elements are shown with black background.
+
||Some elements are shown in "black" background.
Their state is unknown at that temperature.
+
 
 +
Their state is unknown at that '''Temperature'''.
 
|-
 
|-
||
+
||Select '''Family'''
||Next let's select Family.
+
||Next let's select '''Family'''.
 
|-
 
|-
||Point to Selected Family drop down button.
+
||Point to '''Selected Family''' drop down button.
||Selected Family drop down button appears.
+
||'''Selected Family''' drop down button appears.
 
|-
 
|-
 
||Scroll down the list.
 
||Scroll down the list.
 
||Drop down list has various families with their corresponding colors.
 
||Drop down list has various families with their corresponding colors.
 
|-
 
|-
||Point to All.
+
||Point to '''All'''>>Point to different family colors.
Point to different family colors.
+
||By default '''All''' is selected.  
||By default All is selected.  
+
  
Each Family of elements appear in specific Family colors.
+
Each '''Family''' of elements appear in a specific '''Family''' color.
 
|-
 
|-
||Click on the drop down list and select Metalloids.
+
||Click on the drop down list and select '''Metalloids'''.
||Click on the drop down list and select Metalloids.
+
||Click on the drop down list and select '''Metalloids'''.
 
|-
 
|-
||Point to Metalloids color.
+
||Point to '''Metalloids''' color.
  
 
Move the cursor over rest all elements.
 
Move the cursor over rest all elements.
||Metalloids  appear in Green family background color.
+
||Metalloids  appear in '''Green''' family background color.
Rest all elements appear in black background.
+
 
 +
Rest all elements appear in "black" background.
 
|-
 
|-
||Select Electronegativity Color scheme.
+
||Select '''Electronegativity Color scheme.'''
||Go back to Color Schemes, select Electronegativity.
+
||Go back to '''Color Scheme''', select '''Electronegativity''' color scheme.
 
|-
 
|-
 
||Point red colored buttons.
 
||Point red colored buttons.
  
 
Point to blue colored buttons.
 
Point to blue colored buttons.
||Elements with red color have lowest  electronegativity values.
+
||Elements with 'red' color have lowest  '''Electronegativity''' values.
  
Elements with blue color have highest electronegativity values.
+
Elements with 'blue' color have highest '''Electronegativity''' values.
 
|-
 
|-
||
+
||Move the cursor over rest all elements
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
 
+
  
 +
Point to 'pink' colored buttons.
 +
||There is gradual change in the color from 'red' to 'blue'.
  
 +
Elements with 'pink' color have in between '''Electronegativity''' values.
 +
|-
 +
||Point to black colored buttons.
 +
||If no data is available in the database, the element will have a "black" background.
 +
|-
 +
||Point to the '''Blocks'''>>move the cursor on all the '''Blocks'''
 +
||Let's select '''Block'''.
  
 +
Elements of each '''Block''' appear with alloted block color.
  
 +
* 's' block – blue
  
 +
* 'p' block –  reddish brown
  
 +
* 'd' block – green and
 +
* 'f' block – Purple. <pause>
 
|-
 
|-
 
||
 
||
 
||Let's summarize what we have learnt.
 
||Let's summarize what we have learnt.
 
|-
 
|-
||'''Slide Number 11'''
+
||'''Slide Number 8'''
  
 
'''Summary'''
 
'''Summary'''
||In this tutorial we have learnt,
+
||In this tutorial we have learnt.
 +
 
 +
* Details about elemental windows.
 +
 
 +
* Color Schemes of-
  
* About different types of '''orbitals'''
+
1.Physical State
  
* End-on and side-wise overlaps
+
2.Family
  
* Rotation and resize of orbitals
+
3.Electronegativity and
  
* Positive, negative and zero overlap.
+
4.Block
 
|-
 
|-
||'''Slide Number 12'''
+
||'''Slide Number 9'''
  
 
'''Assignment'''
 
'''Assignment'''
||Here is an assignment.
+
||As an assignment,
  
* Draw  's-p' end-on overlap with Hydrogen chloride(H-Cl) molecule
+
Explore
  
* Draw side-wise overlap of 'dxy-dxy' orbitals
+
* Elemental windows of '''Cobalt, Nickel, Copper''' and others.
  
* Draw other negative and zero overlaps.
+
* Different '''Family Color schemes'''
  
* Hint: Rotate and resize the orbitals for proper overlap.
+
* '''Atomic radius Color scheme'''
 
+
Your completed assignment should look like this.
+
 
|-
 
|-
||'''Slide Number 13'''
+
||'''Slide Number 10'''
  
 
'''Acknowledgement'''  
 
'''Acknowledgement'''  
||Watch the video available at this link.
+
||Watch the video available at this URL.
  
 
'''http://spoken-tutorial.org/What_is_a_Spoken_Tutorial'''
 
'''http://spoken-tutorial.org/What_is_a_Spoken_Tutorial'''
Line 393: Line 436:
 
If you do not have good bandwidth, you can download and watch it  
 
If you do not have good bandwidth, you can download and watch it  
 
|-
 
|-
||'''Slide Number 14'''
+
||'''Slide Number 11'''
 
||The Spoken Tutorial Project Team:  
 
||The Spoken Tutorial Project Team:  
  
Line 402: Line 445:
 
For more details, please write to '''contact@spoken-tutorial.org'''  
 
For more details, please write to '''contact@spoken-tutorial.org'''  
 
|-
 
|-
||'''Slide number 15'''
+
||'''Slide number 12'''
 
||Spoken Tutorial Project is a part of the Talk to a Teacher project  
 
||Spoken Tutorial Project is a part of the Talk to a Teacher project  
  
Line 412: Line 455:
 
|-
 
|-
 
||
 
||
||Drawings are contributed by '''Arathi'''
+
||This is '''Madhuri Ganapathi''' from '''IIT Bombay''' signing off. Thank you for joining.  
 
+
This is '''Madhuri Ganapathi''' from '''IIT Bombay''' signing off. Thank you for joining.  
+
 
|}
 
|}

Latest revision as of 21:43, 4 April 2014

Title of the tutorial: Features and Color Schemes

Author: Madhuri Ganapathi

Key words: Periodic table of the element buttons, Elemental window, Color Schemes, Video tutorial


Visual Cue Narration

Slide Number 1

Title Slide

Hello everyone.

Welcome to this tutorial on Features and Color Schemes in GChemTable.

Slide Number 2

Learning Objectives

In this tutorial, we will learn about
  • GChemTable
  • Elemental window and
  • Color schemes.
Slide Number 3

System Requirement

For this tutorial I am using,

Ubuntu Linux OS version 12.04.

GChemPaint version 0.12.10.and

GChemTable version 0.12.10.

Slide Number 4

Pre-requisites

To follow this tutorial, you should be familiar with
  • Periodic table of elements and
  • GChemPaint.

If not, for relevant GChemPaint tutorials, please visit our website.

Let's now learn about GChemTable application.
Slide Number 5

Installation

GChemTable
  • can be installed as a utility software of GChemPaint
  • using Synaptic Package Manager.
Slide Number 6

About GChemTable'

GChemTable is a chemical elements Periodic table application.

It provides scientific information about elements.

It shows Periodic table with different Color schemes.

Click on Dash Home type GChem3D in the search bar>>

Click on Periodic table of the elements icon.

To open GChemTable, click on Dash Home.

In the search bar that appears type "gchemtable".

Click on Periodic table of the elements icon.

Move the cursor on Periodic table of the elements window. Periodic table of the elements window opens.
Point to Menubar GChemTable window has Menubar like all window based applications.

Menubar contains all the commands you need to work with GChemTable.

Point to the table

point to element buttons

This is a Periodic table of elements, here you can see element buttons.
Place the cursor on the element button. To get the name of the element, place the cursor on the element.
Point to the buttons.

Point to the table.

Colors used for buttons in the table are conventional colors of the elements.

This table is a replica of Modern Periodic table.

Now let's learn about Elemental window.
Click on any element button on the periodic table. To display it, click on any element button on the periodic table.

I will click on Carbon(C)

Elemental window of Carbon opens.

Point to the sides Elemental Window contains four side tabs
  • Main,
  • Electronic Properties,
  • Radii and
  • Thermodynamics

I will explain about each tab one by one

Point to the Main tab

point to all the components one by one.

By default Main tab is selected.
  • It has Symbol of the element,
  • Atomic number,
  • Atomic weight and
  • Electronic configuration.
Point to the headings It has a table with headings Lang and Name

Table shows Carbon's name in various languages.

Click on Electronic properties tab Next click on Electronic properties tab
Point to electronegativity value

Ionization energies

Electronic affinities

This tab shows details about

Pauling electro-negativity value.

Ionization energies,

first, second and third Ionization energies in MJ per mol.

Electronic affinities in KJ per mol.

Point to the buttons

Click on the buttons.

Point to the displayed chart.

On the rightside corresponding Show curve buttons are seen.

Click on Show curve button to view the Chart.

Point to the chart. This is the chart of Electronegativity versus Atomic number(Z).
Point to Close button. I will close the chart.
Click on Radii tab

Point to the values

Click on Radii tab

This tab shows

  • Covalent,
  • Van der Waals and
  • Metallic radii values all in 'pm'.

'pm' is pico metre= 10-12m

(10 to the power of minus 12 metres).

Since Carbon is a non-metal it does not have Metallic radius value.

Point to Close button. I will close the Carbon window.
Point to Periodic table of the elements window. Let's go back to the Periodic table of the elements window.
Click on Sodium(Na) button>>Click on Radii tab. Let's click on Sodium(Na) button.

Click on Radii tab.

Metallic radii value is shown here.

Point to the table columns. Radii tab shows a table of Ionic radii.

This table contains Ion, C.N, and Value as columns

Let's scroll down the table.

Point to Ion CN and Value columns. This table gives information about
  • different Ionic states Sodium exists in.
  • Its Coordination number(CN) and
  • Ionic radii value in 'pm'.
Point to the Element buttons. Elements Chromium, Manganese, Iron, Cobalt, Nickel and Copper have a tendency to form a large complexes.
Click on Iron button.

Point to the Elemental window.

Let's click on Iron(Fe) button.

Its elemental window opens

Click on Radii tab. Click on the Radii tab.

Ionic radii table has an extra column named Spin.

Point to Spin column Spin column gives idea about complex formation tendency of Iron.
Point to High and Low Here High means spin free complexes where electrons are unpaired.↑ ↑ ↑ ↑

Low means spin paired complexes where electrons are paired up. ⇅ ⇅ ⇅ ⇅

Point to Close button. I will close Iron(Fe) elemental window.
Slide Number 7

Complex Formation

Point to the link.

More details about complex formation are available at this link

http://en.wikipedia.org/wiki/Spin_states_d_electrons.

Click again on the Elemental window of Carbon. Click again on the Elemental window of Carbon.
Click on Thermodynamics tab

Point to Melting Point and Boiling point

Click on Thermodynamics tab

This tab shows Melting Point and Boiling point of Carbon.

Assignment Explore Show curve button on your own.
Point to Close button. I will close the Carbon elemental window.
Now let's move on to Color schemes.
Go View menu and select Color scheme. Go View menu and select Color schemes.
Point to the submenu. A submenu opens with a list of Color schemes.
Click on No colors.

Point to element buttons.

Click on No colors

All element buttons turn to grey.

Click on Color Scheme.

Select Physical states.

Click on Color Schemes and select Physical states.
Move the cursor on the table. A new Periodic table opens with elements buttons in "Blue" color.

Except for some in "Black".

Point to the scale slider On the top you can see Temperature(K): scale slider with "zero(0)" as minimum value.
Point to colors of solid, liquid and gas. Below you can see colors of "Solid-Blue", "Liquid-Green" and "Gas-Red".
Point to 0K>>point to color. At zero degree Kelvin all the elements are in solid state.

So they appear in 'blue' color.

Drag the slider.

Point to the colors

Let's drag the slider to increase the temperature.

Notice that elements change their Physical state.

"Blue" color is replaced by Green(liquid) and Red(Gas) colors.

Point to 6010K>>point to color. At 6010 degree Kelvin(six thousand ten) all the elements change to gaseous state.

All the buttons change to "Red" color.

Point to color. Some elements are shown in "black" background.

Their state is unknown at that Temperature.

Select Family Next let's select Family.
Point to Selected Family drop down button. Selected Family drop down button appears.
Scroll down the list. Drop down list has various families with their corresponding colors.
Point to All>>Point to different family colors. By default All is selected.

Each Family of elements appear in a specific Family color.

Click on the drop down list and select Metalloids. Click on the drop down list and select Metalloids.
Point to Metalloids color.

Move the cursor over rest all elements.

Metalloids appear in Green family background color.

Rest all elements appear in "black" background.

Select Electronegativity Color scheme. Go back to Color Scheme, select Electronegativity color scheme.
Point red colored buttons.

Point to blue colored buttons.

Elements with 'red' color have lowest Electronegativity values.

Elements with 'blue' color have highest Electronegativity values.

Move the cursor over rest all elements

Point to 'pink' colored buttons.

There is gradual change in the color from 'red' to 'blue'.

Elements with 'pink' color have in between Electronegativity values.

Point to black colored buttons. If no data is available in the database, the element will have a "black" background.
Point to the Blocks>>move the cursor on all the Blocks Let's select Block.

Elements of each Block appear with alloted block color.

  • 's' block – blue
  • 'p' block – reddish brown
  • 'd' block – green and
  • 'f' block – Purple. <pause>
Let's summarize what we have learnt.
Slide Number 8

Summary

In this tutorial we have learnt.
  • Details about elemental windows.
  • Color Schemes of-

1.Physical State

2.Family

3.Electronegativity and

4.Block

Slide Number 9

Assignment

As an assignment,

Explore

  • Elemental windows of Cobalt, Nickel, Copper and others.
  • Different Family Color schemes
  • Atomic radius Color scheme
Slide Number 10

Acknowledgement

Watch the video available at this URL.

http://spoken-tutorial.org/What_is_a_Spoken_Tutorial

It summarizes the Spoken Tutorial project

If you do not have good bandwidth, you can download and watch it

Slide Number 11 The Spoken Tutorial Project Team:

Conducts workshops using spoken tutorials

Gives certificates to those who pass an on-line test

For more details, please write to contact@spoken-tutorial.org

Slide number 12 Spoken Tutorial Project is a part of the Talk to a Teacher project

It is supported by the National Mission on Education through ICT, MHRD, Government of India.

More information on this Mission is available at this link

http://spoken-tutorial.org/NMEICT-Intro

This is Madhuri Ganapathi from IIT Bombay signing off. Thank you for joining.

Contributors and Content Editors

Madhurig