Wednesday, January 23, 2013

Learn the list of chemical formulas Online

Chemical Formula exist for both organic and inorganic compounds.  Inorganic compounds are normally compounds without carbon hydrogen bond where as organic compound contains carbon. 
The naming for organic compound has been given by the International Union of Pure and Applied Chemistry (IUPAC).
But some of the organic compounds are still known by their  common names:

Formulas List of Inorganic Compounds

Chemical formulas List:
Chemical Formula exist for both organic and inorganic compounds.  Inorganic compounds are normally compounds without carbon hydrogen bond where as organic compound contains carbon. 
The naming for organic compound has been given by the International Union of Pure and Applied Chemistry IUPAC names.

But some of the organic compounds are still known by their  common names
Inorganic compounds except for few rules they are called by common name.  Names can also be broadly classified according to the nature of bonding.  For example ionic compounds are name differently than covalent compounds.

Inorganic compound (ionic) generally follow a general convention in naming.  Except for water all other inorganic compound follow the convention.  The convention is that the cation is name the first like metal and then the anion.
Normally cation whether it is metal or nonmetal is name as such like Sodium,  Potassium, Calcium etc.

Chemical Formulas and Names

Table I:
FormulaName
HNO3 Nitric acid
H2SO4 Sulfuric acid
NaCl Sodium chloride
SnCl2 Tin(II) Chloride
KBr Potassium Bromide
CsI Cesium Iodide
CaCl2 Calcium chloride
H3PO4 Phosphoric acid
Na2Cr2O7 Sodium dichromate
PCl3 Phosphorous trichloride
IF5 Iodine hexaflouride
CO2 carbon dioxide
SO3 Sulfur trioxide
NaNO3 Sodium nitrate
ZnBr2 Zinc bromide
NaCN Sodium cyanide
AgBr Silver Bromide
FeCl2 Iron(II) chloride
FeCl3 Iron(III) chloride
PbSO4 Lead(II) sulfate
Hg2Cl2 Mercury(I) chloride
NaI Sodium Iodide
 HIO3 Iodic acid
 XeF2 Xenondiflouri
Inorganic names may contain Roman numericals when the metal can exist in  more than one oxidation states. Some examples are
Coper(I) and Copper(II) i.e., Cu+ and Cu2+
Table II:
FormulaName
CH3COOHAcetic acid
CH4Methane
CH3COCH3Acetone
HCHOFormaldehyde
C6H6Benzene
C6H5NH2Aniline
C6H5N2ClBenzenediazonium chloride
C2H5OC2H5diethyl ether
 HCOOH Formic acid
 C5H10 Pente








Wednesday, January 16, 2013

Molar Volume of a Gas


The molar volume of a gas is equal to the volume occupied by the 1 mole of a gas at given conditions of temperature and pressure. The molar volume can be obtained by dividing the molar mass by the density of the gas at given temperature.
                              Molar volume = molar mass / density
The unit of molar volume is M3 / mole or dm3/mole

Introduction to molar volume of a gas :

The volume of an ideal gas can be obtained by the ideal gas equation
                                                                 PV = nRT
V/n = RT/P plug in the values of R = 8.31 joule / mole / Kelvin, let the temperature = 273 Kelvin and the pressure as 1 Pascal = 1.01*105 N/m2. These are the STP conditions.
VMOLAR   = (8.31*273/1.01* 10 5)=22.4 liters approximately.

So the molar volume of an ideal gas at ST P is equal to 22.4 liters

 The molar volume of a real gas can be obtained by using the vanderwaal’s equation:
                                                         (P+a/V2) (V-b)  = nRT  
 The a and b are the constant and different for a gas specific.

By approximation and Avogadro’s’ law the volume of 1 mole of a gas at STP is 22.4 liter invariably with the nature and type of a gas. Then applying the gas equation we can find the volume of the gas at any temperature.

Molar Volume of a Gas Ilustration

Example: find the molar volume of CO2 at 2 atm pressure and 27 degree C.
 SOLUTION:
   The molar volume of CO2 at STP is 22.4 liters therefore applying the followings
   P1=1 atm             P2 =2 atm
     V1= 22.4L           V2=??
      T1= 273 K          T2= (27+273) = 300 K
APPLYING THE EQAUITON
      P1V1/T1 =P2V2/T2
      V2  =  P1T2V1/P2T1
       =  1*300*22.4 /(2*273) = 12.30 liters

Tuesday, January 15, 2013

Fuel Cell Electrochemistry

Introduction :
What is fuel cell in electrochemistry:

Fuel cells are galvanic cells in which chemical energy of fuels is directly converted into electrical energy.(In the conventional electricity generators, the fuel is burn and the heat energy produced is used to boil water. The steam produced is made to spin the turbines connected with the electricity generators)
Hydrogen - oxygen fuel cell is a common type of fuel cell based on the combustion of hydrogen to form water.
                    2H2(g) + O2(g)  `rarr` 2H2O(l)

Construction of Fuel Cell of Electrochemistry:

It consists of two porous  graphite electrodes impregnated with a catalyst namely silver, platinum or a metal oxide. The electrodes are kept in an electrolyte ie an aqueous solution of NaOH or KOH. Oxygen  and hydrogen are continuously fed into the cell under a pressure of about 50 atmospheres and the cell is maintained at a temperature above 1000C. The gases as well as the electrolyte diffuse into the pores of the electrodes.

Working and Uses of Fuel Cell Electrochemistry:

The following electrode reactions taking place in fuel cell electrochemistry:
  • Oxidation electrode reaction:
            2H2(g) + 4OH-(aq) `rarr` 4H2O(l) + 4e-
  • Reduction electrode reaction:
   O2(g) +2H2O(l) +4e- `rarr` 4OH-
The overall fuel cell reaction is the sum of the above two equations .
              2H2(g) + O2(g) `rarr` 2H2O (l)
The emf of the cell is found to be 1 Volt. Since the temperature of the cell is more than 1000C, water produced vaporizes and leaves the cell along with the unused hydrogen
Advantages of fuel cell electrochemistry:
  • When compared with the conventional electical energy generators the fuel cells are more efficient.The efficiency is about 75%.
  • Since the product of combustion of the two fuel gases is water, it proves to be pollution-free source of power.

  • The fuel cell can be made a perennial source of electrical energy by maintaining a continuous supply of fuel.

  • The fuel cells are employed in spacecrafts.

  • They seem to be the promising substitute for the internal combustion engines in automobiles in the very near future, reducing pollution and enhancing efficiency. Unlike the heavy lead-acid batteries used in vehicles at present , the fuel cells are very light in weight and so many individual cells can be arranged in series connection to generate very high voltages.

Wednesday, January 9, 2013

Periodic Table Properties

Introduction :
According to modern periodic law, the properties of the elements are the periodic functions of elements.

The properties of the elements which are dependent of the electronic configuration of elements are called the periodic properties.  These are called periodic because these are repeated as the element of similar electronic configuration is turn up.  The physical properties of the elements can be divided in to two categories:

properties in the Periodic table of which are characteristics of an individual atom are written with their general trends across a period and down the group respectively

Electro negativity: Increase across the period and decreases down the group.

Ionization Potential: Increases across the period and decreases down the group.

Electron Affinity: Increase across the period and decreases down the group.

Atomic Radius: decrease across a period and increases down a group

Ionic Radius: decrease across a period and increases down a group. 

Effective Nuclear Charge : Increase across the period and remains almost same in the subgroup of normal elements down the group.

Valency: Valency of the atom with respect to oxygen increases increase fromm1 to 7 across a period. Down a group it remains almost same

Screening Effect: Increase across the period and increases down the group. Electropositive or Metallic: character decrease across a period and increases down a group.
Electronegative or non metallic character: Increase across the period and decreases down the group.

Properties which are the characteristics of group of atoms are like:-     
  • Melting point : the  melting point of  the element first increase and becomes somewhat maximum at the middle and then decreases ,  down the group the melting point there is regular change but it is different for different groups, for example in case of the Alkali metals the melting points decrease down the groups in case of Halogen it increases
  • Boiling point: the  melting point of  the element first increase and becomes somewhat maximum at the middle and then decreases ,  down the group the melting point there is regular change but it is different for different groups, for example in case of Alkali metals the melting points decrease down the groups in case of Halogen it increases
Let us see some properties of periodic table.

Properties of Periodic Table

Similarly there is periodicity in the following properties of the groups of the atoms of the elements.
Heat of fusion, Heat of vaporization, Density,  Atomic volume, Nature of oxide .Nature of hydride. 
Since electronic configuration of the elements is the periodic table functions of atomic number of the elements therefore these atomic properties are also the periodic functions of atomic numbers of the elements and hence they are called the periodic properties. The general trends of some of the some periodic properties are as:-
Atomic and ionic radii  decrease in a period from left to right and increases in a group from top to bottom.
Electron gain enthalpy increases from left to right and decreases from top to bottom in a group.
Ionization potential increases from left to right in a period and decreases from top to bottom in a group.
Nature of oxide the acidic character of oxide increases from left to right in a period. 
Electro negativity increases from left to right in a periodic table and decreases from top to bottom in a group.

Periodic Table Nitrogen

Nitrogen belongs to the p-block of the periodic table. It comes under group 15 and the second period.

Introduction to periodic table nitrogen

It is represented as N. Its atomic number is 7 and its mass number is 14. It comes under the main group of elements otherwise known as representative elements or the normal elements of the periodic table. Nitrogen is the first member of the nitrogen family. Its electronic configuration is 2, 5. It is one of the most electro negative elements of the periodic table. It was discovered by Rutherford in 1772. It exists as a diatomic gas (N2) in the elemental state, therefore, it is also called dinitrogen. 
Anomalous properties of nitrogen:
1)       it is highly electro negative
2)       it exists in both liquid and gaseous forms
3)       it forms electrovalent as well as covalent compounds with non metals
4)       It is not metallic in nature
5)       It is a poor conductor of heat and electricity
6)       Exceptionally small atomic size
7)      Absence of d-orbitals in its valence shell
Some important properties of Nitrogen
1)      N2 molecules are held together by weak van der Waals forces of attraction which can be easily broken by the collisions of the molecules at room temperature. Therefore, N2 is a gas at room temperature.
2)      Catenation: Nitrogen can form chains containing upto 3 N atoms. Example, hydrazoic acid (N3H) or azide ion, N3^- ion.
3)      nitrogen forms a triple bond between its two atoms.
4)      Nitrogen cannot expand its covalency beyond 4. So, it does not form pentahalides
5)      The hydride of nitrogen (NH3) is stable while the hydrides of other elements are not stable. 
6)      Nitrogen forms five oxides - N2O, NO, N2O3, NO2 or N2O4 and N2O5 which are monomeric
7)    It has two stable isotopses N14 and N15. 
8)    it is neutral towards litmus
9)     it is neither combustible nor a supporter of combustion.
10)   when a mixture of dinitrogen and dihydrogen is heated to about 700K under a pressure of 200 atms., in the presence of iron catalyst and molybdenum as promoter, ammonia is formed.  
         N2 + 3H2 (g) ----------- 2NH3 (g)                reversible reaction
11)   N2 + O2 --------------2 NO (nitric oxide)       reversible reaction

Periodic Table Nitrogen: Uses


1)    it is used in the manufacture of nitric acid, ammonia, calcium cyanamide, etc.
2)    it acts as an inert diluent in reactive chemicals
3)    it is used in filling electric bulbs to reduce the rate of volatilisation of the tungsten filament
4)     nitrogen gas -filled thermometers are used for measuring high temperatures
5)     liquid nitrogen is used as a refrigerant to preserve biological materials, food items and in cryosurgery

Wednesday, January 2, 2013

Corrosion

As the metals like steel, ceremic, iron etc are greatly affected by environmental chemical reaction or by natural process, this cause the degrdation of metals or metal destruction. This degradation is known as corrosion. The corrosion of metals result destroys metals and their properties.

Corrosion Materials are the main reason for this degradation process and they are toxic in nature. They can easily attack on metal surface and alter their strength. For example the corrosion of steel is done by seawater. Similar rusting of iron is also due to corrosion because in this degradation process, the iron gets oxidized into ferric oxide Fe2O3 and the color of iron surface changes from black to yellow to orange. The process of rusting of iron takes place in some steps. First the iron gets oxidized into ferrous ions and then these ferrous ions again undergo loss of electrons and oxidize into ferric ions [Fe (III)]. This oxidation occurs due to the presence of water and oxygen. The ferric ions then react with oxygen atom and produce ferric oxide which again reacts with water and hydration reaction takes place. The whole process can be represented by a simple chemical reaction that is mentioned below;
4Fe+2 (aq) + 3O2 (g) + 2 H2O  ?  2Fe2O3.H2O

The rusting process is greatly affected by some salts and also enhanced with moisture environment. The rate of the degradation increases with increasing the moisture level.

So if we discuss that what is Corrosion then we can easily explained this process by taking the above example of iron rusting. The corrosion is classified in various categories that depend on the environmental conditions of metals, the chemical changes, and also with material type. It can be like uniform, galvanic, pitting corrosion, stress corrosion, fatigue, inter-granular corrosion, crevice corrosion, fili-form corrosion, erosion corrosion, fretting corrosion etc.

The methods that are used to control the corrosion are known as corrosion control process. For controlling this process some methods like cathodic protection in which impressed current and sacrificial anode are used. Similar Corrosion inhibitors are used to control corrosion. These are chemicals that are used to control environmental conditions and thus reduce the corrosives. Some chemicals like hexylamine, sodium benzoate, oxidising agents like chromate, lead, nitrite, amines, and thio-urea are worked as corrosion inhibitors. Today’s the manufacturing process is done in such a way to increase the inherent capacity of any material for preventing the harmful effect of corrosion. All of the other methods of corrosion control should be considered in the design process. Protective coating on materials is also used to prevent corrosion.

Atomic mass unit

The analysis of water shows that a water molecule contains 11.19% of hydrogen and 88.89% of oxygen. So the ratio of both components masses is 11.19:88.89 or 1:8. Or we can say that the ratio of both hydrogen and oxygen is 2:1. Mass of oxygen is 16 times the mass of an atom of hydrogen. Therefore relative mass of an atom of oxygen is 16 units if we take mass of an atom of hydrogen as one unit. 

Similarly relative atomic mass of other elements is determined by taking hydrogen atom mass as standard. But that is old approach. Then it was preferred to take oxygen atomic mass as standard. But the international union of chemist selected the most stable isotope of carbon and that is C-12 isotope. This is taken as standard for comparison of atomic mass of various elements. 

The mass of C-12 isotope was taken as 12 atomic mass units.

So the definition of atomic mass of any element can be defined as the average relative atomic mass of an atom of element as compared with the mass of an atom of carbon isotope C-12 as 12 unit. A scale is used to express the relative atomic mass unit. So the Atomic mass unit definition can be stated as the unit which is used to express the relative atomic mass is known as atomic mass unit. It is denoted as a.m.u. It can also defined as atomic mass unit or as unified mass as 1/12th of the actual mass of an atom of carbon isotope C-12. The atomic mass of any element shows that how many times as atom of the element is heavier than 1/12 of an atom of carbon isotope C-12.
So the Atomic Mass Formula can be written as;

Atomic mass= mass of an atom of an element / 1/12 x mass of an atom of carbon isotope C-12

This formula is useful in calculating Atomic Mass. For example, atomic mass of magnesium is 24 u. This shows that an atom of magnesium is 24 times heaviour than 1/12 of an atom of carbon isotope C-12.

But there are many cases when different atoms of the same elements possess different relative masses. Such atoms of the same elements are called isotopes. So in these cases, atomic mass of the elements is calculated as average atomic mass.

The Average atomic mass formulaΣ (mass of isotope × relative abundance)
For example, chlorine has two isotopes having relative masses 35u and 37u with relative abundance in nature is 3:1. Thus the atomic masses chlorine is the average of these different relative masses as mentioned below;

Atomic mass of chlorine = 35x 3 + 37x1 / 4 = 35.5 u.