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| Thermochemistry Page from my Chemistry-World software |
Thermochemistry:
Thermochemistry primarily deals with the transfer of the heat between a chemical
system and its surroundings when a reaction of a phase change takes place
within the system. The heat transfer is basically due to the conservation of
energy or first law of thermodynamics. Heat transfer can take place under law
of thermodynamics we know that the heat transferred at constant volume changes
the internal energy of the system whereas that at constant pressure changes the
enthalpy of the system, in the laboratory, the majority of chemical reactions
are carried out under the condition of constant pressure, and thus the heat
transferred in such a system is equal to the enthalpy changes in a chemical
reaction. Since the enthalpy of a system can also change due to the variation
of temperature and pressure, it is therefore essential that the reactants and
products in a chemical reaction must have the same temperature and pressure.
Enthalpy
change of a Chemical equation:
Two types
of reactions may be distinguished.
 |
| Nitroglycerine is burst out in presence f air and produces nitrogen, oxygen, Carbon dioxide and water. Heat of the reactant(Nitroglycerine) is much higher than the heat of the products (Nitrogen, oxygen, Carbon dioxide, water), therefore reactant(Nitroglycerine) energy is much higher than the end products(Nitrogen, oxygen, Carbon dioxide, water), energy. |
1)Exothermic
reaction:
For these (^H) is negative which implies
negative qp and hence release of heat when reactants are converted into
products in this case . Example: Nitroglycerine is burst out in presence f air
and produces nitrogen, oxygen, Carbon dioxide and water. Heat of the
reactant(Nitroglycerine) is much higher than the heat of the products
(Nitrogen, oxygen, Carbon dioxide, water), therefore reactant(Nitroglycerine)
energy is much higher than the end products(Nitrogen, oxygen, Carbon dioxide,
water), energy.
Heat of
Product(H) < Heat of Reactant(H) (Initial Reactant heat is greater than the
product heat)
 |
| Iron wool is heated in presence of chlorine gas produces solid iron chloride. Temperature of iron chloride (end product) is much higher than iron wool and chlorine gas(reactant). In this reactions end product`s(Iron Chloride) energy is higher than the reactant energy(Iron wool and chlorine gas) |
2)
Endothermic Reaction:
For These
heat(^H) is positive which implies positive qp and
hence absorption of heat when reactants are converted into products. Example:
Iron wool is heated in presence of chlorine gas produces solid iron chloride.
Temperature of iron chloride (end product) is much higher than iron wool and
chlorine gas(reactant). In this reactions end product`s(Iron Chloride) energy
is higher than the reactant energy(Iron wool and chlorine gas)
Heat of
Product(H) > Heat of reactant(H) (End product heat is greater than the
initial reactant heat)
 |
| Catalysis Page from my Chemistry-World software |
Catalysis:
Catalysis
is the acceleration of a chemical reaction by means of a substance called catalyst,
which is added to the reaction but remains unchanged after the reaction has
occurred. A catalyst speeds up a reaction by lowering the amount of energy
required to initiate the reaction. Why use catalyst? There are some chemical
reactions that can be easily accelerated, for example by increasing the
temperature may result in the destruction of important proteins. Catalysts
provide an alternative means of achieving the same result.
 |
| Catalyst Graph showing "Activation Energy" |
Lowering
the Activation energy:
For a
chemical reaction to occur there must be sufficient energy to initiate it.This
energy threshold is called the "activation energy" . The purpose of
catalyst is to lower the activation energy required to initiate a chemical
reaction, thereby speeding by adding a catalyst can happen in a number of
ways.For example, the catalyst may alter the structure of the reactant,
allowing it to react more readily, or the catalyst might hold the reactant
molecules in a particular orientation, which reduces the amount of energy that
is required for the reaction. Either way, it is important to remember that
catalyst remain unchanged after the chemical reaction occurs.
 |
| Catalyst Graph Showing energy difference |
Yet this
is not to say that catalyst does not participate in the chemical process-- in
fact, there are many catalysts that work by breaking down the reaction process
by creating intermediate compounds. Typically, these intermediate compounds are
unstable, and a second reaction occurs,producing the desired end products, and
returning the catalyst to its original form. For this reason catalyst are
recyclable, and can be used many times, making them incredibly useful for
industrial applications.Ferric or Iron chloride is used widely as a catalyst in
various industrial applications.
Catalytic
Converter:
First
introduced to the automotive industry during the 1970s, the catalytic converter
uses the principle of catalyst to help reduce the toxic emissions that are
produced by car engines.
 |
| Automotive Vehicles catalytic converters |
There are
two types of catalytic converters- Two way and three way catalytic converters.
Each of this converters performs a similar task, and their function can be
explained chemically according to a few simple reduction and oxidation
reactions.
3D animation showing effect of catalytic converter in Automobile which turns black smoke into clear white.
a two way
catalytic converter results in two outcomes,first it performs the oxidation of
carbon monoxide (a highly toxic substance) to carbon dioxide.
2CO + O2 = 2CO2
It as
results in the oxidation of any unburnt hydrocarbons (Left over from the
internal combustion of fuel), resulting in the production of carbon dioxide and
water.
2CxHy + 2(2x +
y/2) O2 = 2xCO2 + yH2O
The Three
way catalytic converter goes no extra step to reduce nitrogen oxides to
nitrogen and oxygen.
2NOx = xO2 + N2
The
catalyst that is used in a automotive catalytic converters is most often a
precious metal.In most cases platinum is used , because of its high level of
activity , however other precious metals can also be used, such as rhodium,
palladium, iron, copper , nickel and manganese.
 |
| Water Properties Page from my Chemistry-World software |
Properties
of Water:
Water is most common compounds on earth, but it
is also one of the most unusual. Water is only compound that naturally exists
in three states of matter n earth`s surface and the only compound to become less
dense when it changes from liquid to solid.
We depend on the unique chemical and physical properties of water for all life as we know it.The molecule of water consist of two hydrogen atoms covalently bonded t an oxygen atom. Water for all life as we know it. The molecule of water consist of two hydrogen atoms covalently bonded to an oxygen atom. Water is a tasteless, colorless. odour less liquid at room temperature and pressure.
Water is found on earth as solid ice and liquid water and water vapour. It will readily change state according to temperature and pressure changes, for example, the ice in glass will melt on a warm day and water droplets from your breath will quickly evaporate. Water can also change directly from a gas to a solid when frost is formed and from a solid to a gas.
 |
| Clear Water |
We depend on the unique chemical and physical properties of water for all life as we know it.The molecule of water consist of two hydrogen atoms covalently bonded t an oxygen atom. Water for all life as we know it. The molecule of water consist of two hydrogen atoms covalently bonded to an oxygen atom. Water is a tasteless, colorless. odour less liquid at room temperature and pressure.
 |
| Liquid and Gas or vapour Form of Water |
Water is found on earth as solid ice and liquid water and water vapour. It will readily change state according to temperature and pressure changes, for example, the ice in glass will melt on a warm day and water droplets from your breath will quickly evaporate. Water can also change directly from a gas to a solid when frost is formed and from a solid to a gas.
The
temperature and pressure at which all three states of water can coexists is knows
as a triple point and occurs almost exactly at 32 degree F (o degree C) at sea
level ( 1 Atmosphere). Under this condition it is possible for water to change
from ice, liquid water or vapour as a result of infinitely small changes in
pressure and temperature.On the other hand, if you increase the pressure,
as in a pressure cooker, water will be at a higher temperature. If the temperature of earth were not as it is, for example if earth were closer t or further from the sun, then we would not have the vast quantities or solid, liquid and gaseous water that we have n our planet.
 |
| As in a pressure cooker, water will be at a higher temperature. |
as in a pressure cooker, water will be at a higher temperature. If the temperature of earth were not as it is, for example if earth were closer t or further from the sun, then we would not have the vast quantities or solid, liquid and gaseous water that we have n our planet.
 |
| When
Water freezes: the
molecule arrange themselves differently so that frozen water become less dense
and also expands by up to o% volume. |
When
Water freezes: the
molecule arrange themselves differently so that frozen water become less dense
and also expands by up to o% volume. This is one of the reasons why ice floats
n top of water. Water freezes at 32 degree F into ice and become less denser
than water. Less dense ice therefore floats above the water of the pond and thus
fishes and other aquatic animals of the pond swim on the lower liquid water of
the pond .For that reason the temperature gradually
increases with the increase of the depth of the pond.
 |
| Water freezes at 32 degree F into ice and become less denser than water. Less dense ice therefore floats above the water of the pond and thus fishes and other aquatic animals of the pond swim on the lower liquid water of the pond |
The Bond
within a water molecule:
The
chemical bonds that hold a water molecule (H2O)
together are important in giving water the shape and structure that makes it s
useful. Oxygen has higher electronegativity than hydrogen, which means that it
will have a stronger attraction for electrons in the O---H bonds than
hydrogen. This difference of electronegativity results in a intramoleculer
charge difference, with the oxygen part of the molecule being negatively
charged and hydrogen is positively charged. The small positive hydrogen nuclei
will be exposed, which allows for the formation of unique intermolecular force,
the hydrogen bond.
 |
| Hydrogen Bond Within Water |
Hydrogen bonds, which give water many of its special properties, form between the negatively charged oxygen atom in one molecule and the small, positive hydrogen atoms in a neighbouring molecule Hydrogen bonds are the cause of the high boiling point, melting point, surface tension, and viscosity f water, and the lower density water compared with liquid water.
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