Sunday, May 8, 2016

XII - 1.21 Hybridisation - Video Lectures

11 May

Hybridization concept
ExamFearVideos
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XI - 1.14 Stoichiometry of Chemical Equations - Video Lectures



Chemistry Lesson: Reaction Stoichiometry
GetChemistryHelp
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XII - 1.20 Metallic Bond - Video Lectures



XII - 1.20 Metallic Bond - Video Lectures


metallic bonding and metallic properties explained -- the electron sea model
weiner7000
https://www.youtube.com/watch?v=Bjf9gMDP47s


Chemistry: What is a metal? (Metallic Bonds)
Socratica

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XI - 1.13 Percentage Composition and Molecular Formula - Video Lectures



Molecular and Empirical Formulas from Percent Composition
Khan Academy
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XII - 1.19 Bonding in Some Diatomic Molecules - Video Lectures

9 May


What are the Diatomic Elements?
Tyler DeWitt
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Bonding in Homonuclear Diatomic Molecules
Ratliff Chemistry

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Bonding in Heteronuclear Diatomic Molecules
Ratliff Chemistry
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XII - 1.18 Electronic Configurations and Molecular Behavior - Video Lectures

8 May

Electronic Configuration and Molecular Behaviour
Flexiguru
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Thursday, May 5, 2016

XII - 1.11 Molecular Orbital Theory - Video Lectures


1.11 Molecular Orbital Theory

This theory was proposed by Hund and Mulliken in 1932. The basic idea of the theory is that atomic orbitals of individual atoms combine to form molecular orbitals.

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Chemsurvival

XII - 1.10 Review of Valency Bond Theory - Video Lectures



1.10 Review of Valency Bond Theory

Valency bond theory was proposed by Heitler and London in 1927 and it was further developed by Linus Pauling.

The basic idea of the theory are:

1. A covalent bond is formed by the overlap of half-filled atomic orbitals of the different atoms.
2. The overlapping atomic orbitals must have electrons with opposite spins.



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Ben's Chem Videos


Comments welcome. Indicate better videos if you come across any.

XII - 1.9 Chemical Bonding - Video Lectures



1.9 Chemical Bonding

1. Valency bond theory 2. Molecular orbital theory



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ExamFearVideos

XI - 1.12 Mass-Mole Conversions - Video Lectures






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Bozeman science

XII - 1.8 Electronic Configurations of Atoms - Video Lectures



Electronic configuration of atoms using Aufbau, Pauli's principle and Hund's rule - Chemistry
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Elearin




Atomic orbitals are the sub-stationary states or the regions in space where the electrons revolve around the nucleus in an atom.

Electronic configuration of atoms is representation of the occupation of electrons in the orbitals. In other words, electronic configuration of atoms specifies the order in which electrons fill up the orbitals.  The order in which these electrons are filled into the atomic orbitals are controlled by three principles.

1. Aufbau principle
2. Hund's rule and
3. Pauli's exclusion principle


Aufbau Principle.

According to this principle an electron always occupies the lowest energy orbital first before filling the higher level. For example, an electron always occupies 2s, the lower energy orbital, first instead of the higher 3s orbital.

The Aufbau or building-up principle can be explained with the example of Hydrogen Atom. Hydrogen has one electron. This electron enters the 1s orbital which has the lowest energy.
In other words, building-up principle states that the incoming electrons go to an orbital which has the least (n+l) value. However, the orbital having lower 'n' value will be occupied first, in case any two orbitals have the same (n+l) value.

Consider the example of Silicon whose atomic number is 14. Twelve electrons can be accommodated in 1s, 2s, 2p, 3s orbitals. Now, the last two electrons can enter into either 3p or 4s orbital. The (n+ l) values of these orbitals are the same, that is,
3p orbital has a (n+l) value of 3+1=4 and 4s has (n+l) value of 4+0 = 4

This means, both the orbitals have the same (n+l) value. But the 3p orbital has 'n' value, that is 3, which is less than the n value of 4s, which is 4. Therefore thirteenth and fourteenth electrons occupy the 3p orbital first. Thus the electronic configuration of Si is  3s2  3p2.The superscript represents the number of electrons present in the corresponding orbital.

The second important rule to determine the electronic configuration of an atom is the Hund's Rule. It says electron pairing happens only after all the available degenerate orbitals are occupied by one electron each.

Hund's rule  example: . Consider the element Oxygen with Z=8. I has 8 electrons, the first electron goes into the '1s' orbital of the K-Shell. The second electron will be paired up with the first in the same 1s orbital. Similarly the third and fourth electrons will occupy the 2s orbital of L-Shell. The Fifth electron goes into one of the three 2p orbitals of L-Shell. Let that be 2px. Since the three p-orbitals i.e., 2px,2py and 2pz are degenerate , the sixth electron goes into 2py or 2pz but not 2px. Let us say it goes to 2py. Since 2pz is a degenerate orbital, the seventh electron goes to 2pz instead of pairing up with electron in 2px or 2py.

Now, since all the 3 sub-orbitals have one electron each, the eighth electron can pair up with any of the three electrons in 2px, 2py and 2pz orbitals. Thus the electronic configuration of Oxygen can be written as 1s1.2s2. 2px2 .2py1. 2pz1. The arrows indicate electrons with spin +1/2 and -1/2. Let us consider the nitrogen atom. it has 7 electrons. The first six electrons have the same arrangement as that of carbon atom 1s1.2s2. 2px1 .2py1. The seventh electron will enter only in 2pz but can not enter into 2px or 2py orbital. Thus the configuration is 1s1.2s2. 2px1 .2py1 2pz1

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The third important rule for electronic configuration, the Pauli's Exclusion Principle states that no two electrons will have the four quantum numbers same. This means that two electrons can ever have any identical values of n, l, m and s values. Because of this rule a single orbital can have only 2 electrons.

XII - 1.7 Orbital Wave Functions and Shapes of Orbitals - Video Lectures


XII -
1.7 Orbital Wave Functions and Shapes of Orbitals - Video Lectures

1.7 Orbital Wave Functions and Shapes of Orbitals


1. Spherical shape for s.
2. Dumbbell shape for orbitals of p.
3. Four-lobed shape for orbitals of d.
4. Complex shape for all orbitals of higher sublevels


The Wave Behavior of Matter (Part 1 of 2 for Atomic Orbitals)

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dcaulf



Atomic Orbitals Explained (Sequel to Wave Behavior of Matter)

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dcaulf





Shapes of Atomic Orbitals - IIT JEE Main and Advanced Chemistry Video Lecture

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RaoIITAcademy

Wednesday, May 4, 2016

XI - 1.11 Mole Concept - Video Concepts


XI - 1.11 Mole Concept - Video Concepts

Mole concept
A mole is measuring unit like for example dozen.
A mole is a collection of 6.022*1023 particles

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Askiitians


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ExamFearVideos

Tuesday, May 3, 2016

XII - 1.6 Pauli's Exclusion Principle - Video Lectures



XII - 1.6 Pauli's Exclusion Principle - Video Lectures

Pauli's exclusion principle: No two electrons can have all four same quantum numbers

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iProfIndia

XII - 1.5 Quantum Numbers - Video Lectures



XII -

1.5 Quantum Numbers - Video Lectures

According to quantum mechanical model or wave mechanical model of atom, orbitals represent regions in space around the nucleus where the probability of finding electrons is maximum. A large number of orbitals are possible in an atom.

To describe each electron in an atom in different orbitals, four quantum numbers are used. They are designated as n,l,ml, and ms.



1. Principal quantum number (n) This quantum number determines the main energy shell or level in which the electron is present. It can have whole number values starting from 1 in an atom.

The principle quantum number indicates the average distance of the electron from the nucleus. If n = 1, it is closest to the nucleus and has lowest energy.

Eariest practice was to number shells as K,L,M,N etc.
Shell with principal quantum number n = 1 is called K.
Shell with principal quantum number n = 2 is called etc.

2. Azimuthal quantum number or angular quantum number (l): This number determines the angular momentum of the electron.

It can have positive integer values from zero to (n-1) where n is the principal quantum number. For each value of n, there are n possible values of l.

For n =3, l has three values: l = 0,1,2

The earlier practice is to designate l as subshell and refer it by letters s,p,d,f,….

l=0 = s; l=1=p; l=2=d, l=3=f etc.

The energy of subshell increases with increasing value of l.

3. Magnetic quantum number ( ml): Magnetic field acts on moving electrical charges. ( from chapters on magnetism in physics syllabus). On revolving electrons external magnetic field of the earth acts. Therefore, the electrons in a given subshell orient themselves in certain preferred regions space around the nucleus. These are called orbitals. This quantum number gives the number of orbitals for given angular quantum number l or in a given subshell.

The allowed values of ml are –l through 0 to +l.

There are (2l+1) values of ml for each value of l.

If l = 0, ml has only one value. ml = 0.

If l = 3, ml has 7 values.
ml = -3,-2,-1,0,1,2,3

4. Spin quantum number (ms) : It is observed that the electron in an atom is not only revolving around the nucleus but is also spinning around its own axis. This quantum number describes the spin orientation of the electron.

The electron can spin in two ways – clockwise and anticlockwise.
Values of +1/2 and -1/2 are given to this quantum number. Its value is not dependent on other quantum numbers.

The orientations of spin are also designated by up and down arrows ↑ ↓.


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Rao IIT Academy

XII - 1.4 Wave Mechanical Model of Atom and Concept of Atomic Orbital - Video Lectures



XII -

1.4 Wave Mechanical Model of Atom and Concept of Atomic Orbital - Video Lectures


1.4 Wave Mechanical Model of Atom and Concept of Atomic Orbital


Quantum mechanics or wave mechanics is a theoretical science which deals with the study of the motion of the microscopic objects (like electron) which have both observable wave like and particle like properties.

Quantum mechanics was developed indepdendently in 1926 by Werner Heisenberg and Erwin Schrodinger. In 1927, Schrodinger wave equation was published.

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ChemTutor BYU

XI - 1.10 Atomic and Molecular Mass - Video Lectures




XI -

1.10 Atomic and Molecular Mass - Video Lectures

1.9 Atoms and Molecules


Atoms are the smallest particle of an element which may or may not have independent existence, but it takes part in chemical reactions.

Molecule is the smallest particle of a substance (element or compound) capable of independent existence.

There are 112 elements in nature as per the present knowledge. Obviously there are 112 different types of atoms.

Molecules may have two or more atoms. Molecules are divided into two types:

1. Homoatomic molecules

2. Heteroatomic molecules



1.10 Atomic and Molecular Mass


Atomic Mass: An atom is such a small particle that its mass cannot be determined with the help of any available balance.  By an indirect method, the absolute mass of hydrogen atom has been found to be 1.66 X 10 to the power of -24 g.

Chemists have defined the atomic mass of hydrogen as one and expressed the atomic mass of other elements as multiples of hydrogen's atomic mass. The relative atomic masses expressed in terms of hydrogen as termed atomic weights.

Atomic weights of some common elements

Metals

Magnesium  24.3
Aluminium  27.0
Iron              55.8
Zinc             65.4
Tin             118.7

Gram Atomic Mass: Gram atomic mass is the quantity of an element whose mass in grams is numerically equal to its atomic mass.

Molecular Mass: Measuring the mass of a single molecule is not possible. Hence as in the case of atoms,  molecular mass is defined as the average relative mass of its molecule as compared to the mass of an atom of carbon (C12) having mass number 12.


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Teacher's Pet

XI - 1.8 Avogadro's Hypothesis Video Lectures



XI -
1.8 Avogadro's Hypothesis Video Lectures

1.8 Avogadro's Hypothesis


Avogadro's hypothesis or suggestion is that matter consists of two kinds of ultimate particles. These are atoms and molecules.

Atoms are the smallest particle of an element which may or may not have independent existence, but it takes part in chemical reactions.

Molecule is the smallest particle of a substance (element or compound) capable of independent existence.

The actual hypothesis is that under similar conditions of temperature and pressure, equal volumes of all gases contain equal number of molecules.

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Smart Learning

XI - 1.7 Dalton Atomic Theory - Video Lectures




XI -
1.7 Dalton Atomic Theory - Video Lectures


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Exam Fear Videos


1.7. Dalton’s atomic theory

To provide theoretical justification to the laws of chemical combination which are experimentally verified, John Dalton postulated a simple theory of matter. The basic postulates of Dalton’s atomic theory are:

a. Matter is made up of extremely small indivisible and indestructible ultimate particles called atoms.
b. Atoms the same element are identical in all respects ie., in shape, size, mass and chemical properties.
c. Atoms of different elements are different in all respects and have different masses and chemical properties.
d. Atom is the smallest unit that takes part in chemical combinations.
d. Atoms of two or more elements combine in a simpler whole number ratio to form compound atoms (molecules).
e. Atoms can neither be created nor destroyed during any physical or chemical change.
f. Chemical reactions involve only combinations, separation or rearrangement of atoms.

Modern atomic theory


As a result of new discoveries made after Dalton developed his postulates, some modifications were done to atomic theory. They are:

1. Atom is no longer considered to be indivisible: It is found that atom is made up of subatomic particles such as electrons, protons and neutrons. We now state how many electrons are there, protons are there in an atom.

2. Atoms of same element may not be similar in all respects. Atoms of same elements have different atomic masses. These different atoms are called isotopes.

3. Atoms of different elements may have similar one or more properties. Atomic mass of calcium and argon (40 a.m.u.) are same. So the property of atomic mass is same for atoms of different elements. Isobars or elements or atoms having the same atomic mass.

4. Atom is the smallest unit which takes part in chemical reactions. Though electrons and protons are there, it is atom which takes part in chemical reactions and electrons exchange takes place between atoms.

5. The ratio in which the different atoms combine may be fixed and integral but may not always be simple. For example in sugar molecule the ratio of C,H and O atoms is 12:22:11, which is not simple.

6. Atom of one elements may be changed into atoms of other element. Transmutation is the process by which atoms one element can be changed into elements of other elements by subjecting it to alpha rays.



7. The mass of atom can changed into energy. Mass and energy are convertible. The equation give for such conversion is E = mc². Hence we cannot say that mass is not destructible. But in chemical reactions, atom remains unchanged and its mass is not destroyed to liberate energy.

Monday, May 2, 2016

XII - 1.3 Heisenberg's Uncertainty Principle - Video Lectures



XII -

1.3 Heisenberg's Uncertainty Principle - Video Lectures

Heisenberg's Uncertainty principle


In 1927, Heisenberg put forward a principle known as Heisenberg’s uncertainty principle.

According it, “it is not possible to measure simultaneously both the position and momentum (or velocity) of a microscopic particle, with absolute accuracy.”

Mathematically, this principle is expressed as:

∆x * ∆p = h/4 Ï€

Where
∆x = uncertainty in position

∆p = uncertainty in momentum

The constancy of the product of uncertainties means that, if the position of the particle is known with more accuracy, there will be large uncertainty in momentum and vice versa.

This uncertainty arises, as all observations are made by impact of light, the microscopic objects suffer a change in position or velocity as a result of impact of light. So there is a disturbance in them due to the measurement.

The principle does not affect the measurement of large objects as in these cases impact of light does not created any appreciable change in their position or velocity.

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AK Lectures


Heisenberg Uncertainty Principle Example # 1
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AK Lectures

Heisenberg Uncertainty Principle Example #2

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AK Lectures




Heisenberg Uncertainty Principle Example #3

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AK Lectures

XI - 1.6 Laws of Chemical Combination - Video Lectures

Class XI
1.6 Laws of Chemical Combination

1.6. Laws of chemical combination

a. Law of conservation of mass
During any physical or chemical change, the total mass of the products is equal to the total mass of reactants.

b. Law of constant proportions

A pure chemical compound always contains same elements combined together in the same definite proportion by weight.

c. Law of multiple proportions

When two elements combine to form two or more than two compounds, the weights of one of the elements which combine with a fixed weight of the other, bear a simple whole number ratio.

d. Law of reciprocal proportions
When two different elements combine separately with the same weight of a third element, the ratio in which they do so will be the same or some simple multiple of the ratio in which they combine with each other.

e. Gay Lussac’s law of combing volumes
Under similar conditions of temperature and pressure, whenever gases react together, the volumes of the reacting gases as well as products (if gases) bear a simple whole number ratio.
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Askiitians


Part 2
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Askiitians

XI - 1.5 Chemical Classification of Matter - Video Lectures


Class XI -

1.5 Chemical Classification of Matter - Video Lectures


1.5. Chemical classification of matter

1. Element
Further classification: Metals, non-metals, metalloids

2. Compound
Further classification: Inorganic and organic

3. Mixture
Further classification: Homogeneous mixtures - they are called solutions.
Heterogeneous mixtures: They have visible boundaries of separation between the different constituents and they can be easily seen with naked eye.

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Linda Hanson

XII - 1.2 Dual Nature of Matter - de-Broglie Equation - Video Lectures



1.2 Dual Nature of Matter - de-Broglie Equation
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Thomas Harrison

Sunday, May 1, 2016

Video Lectures 1.4 Measurement and Significant Figures


Video Lectures 1.4 Measurement and Significant Figures
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Issacs Teach



Accuracy

Accuracy is a measure of the difference between the true value (the value to be measured) and the value measured by an instrument.

Precision is depends totally on the instrument and it is the difference between measurements of the same dimension made number of times. It is expressed as the difference between one measurement and the arithmetic mean of the number of measurements.

Significant figures: Significant figures in a number are include all the certain digits plus one doubtful digit.

If a number has 4 significant figures or digits, it means 3 of them are certain and fourth one is doubtful.

Rules for determining the number of significant figures

1. All non-zero digits are significant
Decimal place does not determine the number of significant figures.

2. A zero becomes significant in case it comes between two non-zero numbers.
3. The zeros at the beginning of a number are not significant.
For example 0.0004 has only one significant figure.
4. All zeros placed to right of a number are significant. They represent the precision of the measuring scale.
For example 267.000 has six significant figures.
(The precision does not come by writing the number. It comes because the instrument has the ability to read a number certainly up to that level of measurement.)

Rules of calculations involving significant figures

Rule 1. The final result of addition or subtraction should be reported up to the same number of decimal places as are present in the term having the least number of decimal places.
Example- addition of three numbers
6.414
2.3
0.501
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9.215 is the answer but the answer should be reported up to one decimal place only as 2.3 is the term having least number of decimal places.

Hence correct answer is 9.2

Rule 2. In multiplication or division, the final result should be reported up to the same number of significant figures as are present in the term with the least number of significant figures.
Example: 4.2345*1.25 = 5.293125
The final result should be reported up to three significant figures only as 1.25 has three significant figures. Hence the correct answer to be reported is 5.29.

Rounding off figures of retention of significant figures.

i) If the digit coming after the desired number of significant figures happens to be more than 5, the preceding digit or figure is increased by 1.
ii) If that digit is less than 5, it is neglected and hence the preceding significant figure remains unchanged.
iii) If that digit happens to be 5, the preceding digit is increased by one in case it is odd number. If preceding digit is an even number, it remains the same.

If the problem has number of steps, the rounding off is to be done at the final answer level only.

Saturday, April 9, 2016

Video Lectures - 1.1 Dual Nature of Radiation Class XII Chemistry


Class XII

1.1 Dual Nature of Radiation
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Askiitians



IIT JEE Chemistry-12th Portion - Study Guide - 1. Atomic Structure and Chemical Bonding
http://iit-jee-chemistry.blogspot.com/2009/03/jee-study-guide-1-atomic-structure-and.html

Video Lectures 1.3 Dimensional Analysis




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MITOpenCourseware



Dimensional analysis in Physics is a very essential tool.

There are two types of physical quantities -- Fundamental Quantities ( Primary) & Derived Quantities ( Secondary).
Those quantities which are independent completely are called Fundamental Quantities and there are seven fundamental quantities in our universe we have made for easy learning physics -- Mass, length, Time, Current, Intensity of Light, amount of substance & temperature.

There are special symbols for representing these fundamental quantities --
[M] for mass
[L] for length
[T] for time
[A] for current
[Cd] for Candela, unit of intensity of light
[Mol] for amount of substance

To study dimensional analysis we take mass, length and time as fundamental quantities of every other derived physical quantity.

Derived Quantities in physics are those quantities which depend on fundamental quantities. For example velocity is a derived quantity because --

Velocity = distance / time, it involves fundamental quantities like distance (length) and time.

We have a method in physics writing these physical quantities in the form of M, L & T. And the power raised (exponent) to these fundamental quantities are called Dimensions.
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IMA Videos

Solving Dimensional Analysis Problems - Unit Conversion Problems Made Easy!

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Science Post


JEE - Study Guide - 1. Some basic concepts of chemistry
http://iit-jee-chemistry.blogspot.com/2009/03/jee-study-guide-1-some-basic-concepts.html

Video Lectures 1.2 Physical quantities and their S.I. Units




Physical quantities and their S.I. Units


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Chris Gozzard



Physics Unit and Measurement  (dimensions of physical Quantities) Class X1 CBSE
Part 10
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EamFearVideos


What Are  SI units
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PearsonIndia


Understand the modern systems of measurement

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PearsonIndia


JEE - Study Guide - 1. Some basic concepts of chemistry
Chapter 1 of Modern Chemistry for Class XI by Dr. S.P. Jauhar
http://iit-jee-chemistry.blogspot.com/2009/03/jee-study-guide-1-some-basic-concepts.html

Video Lectures 1.1 Importance of Studying Chemistry



1.1 Importance of Studying Chemistry



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Studi School


Major Discoveries in Chemistry
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eHowEducation



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Indian Chemical Council

Friday, January 8, 2016

Class XI - Chemical Bonding and Molecular Structures - Videos





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ExamFear Videos





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Etoos India