CHAPTER 9 : MANUFACTURED SUBSTANCES IN INDUSTRY
NAME: NUR INSYIRAH BTE. AB HAMED
CLASS: 4 SAINS GUNAAN (SG)
SCHOOL: SMK SERI INDAH
CONTENT Content Introduction 9.1 Sulphuric acid 9.1.1 Properties of sulphuric acid 9.1.2 The uses of sulphuric acid 9.1.3 The industrial process in manufacture of sulphuric acid 9.1.4 Environmental pollution by sulphuric acid 9.2 Ammonia and its salt 9.2.1 Properties of ammonia 9.2.2 The uses of ammonia 9.2.3 The industrial process in manufacture of ammonia 9.3 Alloys 9.3.1 Physical properties of pure metals 9.3.2 Meaning and purpose of making alloys 9.4 Synthetic polymers 9.4.1 The meaning and types of polymers 9.4.2 Advantages of synthetic polymers 9.4.3 Environmental pollution caused by synthetic polymers 9.4.4 Methods to overcome the environmental pollution caused by synthetic polymers 9.5 Glass and ceramics 9.6 Composite material Conclusion References
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INTRODUCTION All the objects that exist around us are made up of chemical substances. These objects exist an element, compound or mixture. All these objects contribute benefit to humankind. As time goes on, human has done many researches to ensure all these chemical substances will be enough for the use of themselves.
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Chapter 9 of Form 4 syllabus introduces the students with manufactured substances in industry. This is important for the students to appreciate the knowledge of chemistry that is still new for themselves. Personally, I think that this chapter is an interesting chapter as it revealed the way of scientist produces the material around me. It also gives me new knowledge of the uses of chemical substances that I usually found in the laboratories. I hope, by learning this chapter, I will be more interested in learning chemistry as it will help me in the future. All the equations from this chapter make me more understand of the previous chapters.
9.1 SULPHURIC ACID 9.1.1 Properties of sulphuric acid
1. Sulphuric acid is a strong mineral acid. 2. Its molecular formula is H2SO4. 3. It is soluble in water.
Figure 9.1 A molecule of sulphuric acid.
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4. Sulphuric acid is a non-volatile diprotic acid. 5. It is a highly corrosive, dense and oily liquid. 6. Concentrated sulphuric acid is a viscous colourless liquid.
Soluble in water Non-volatile acid
Diprotic acid
Properties of sulphuric acid
Highly corrosive
Oily liquid
Dense
Viscous colourless liquid
Figure 9.2 Properties of sulphuric acid
9.1.2 The uses of sulphuric acid 1) To manufacture fertilizers There are many fertilizers that can be made of sulphuric acid. Some of them are: a)
Calcium dihydrogen phosphate (superphosphate) 2 H2SO4 + Ca3(PO4) 2 → Ca(H2 PO4) 2 + 2CaSO4 sulphuric acid + tricalcium phosphate → calcium dihydrogen phosphate 4
b)
Ammonium sulphate +2NH3 → (NH4) 2 SO4 H2SO4 sulphuric acid + aqueous ammonia → ammonium sulphate
c)
Potassium sulphate +2NH3 → (NH4) 2 SO4 H2SO4 sulphuric acid + aqueous ammonia → ammonium sulphate
2) To manufacture detergents Sulphuric acid reacts with hydrocarbon to produce sulphonic acid. Sulphonic acid is then neutralized with sodium hydroxide to produce detergents. Examples of hydrocarbon 3) To manufacture synthetic fibres Synthetic fibres are polymers ( long chain molecules). Rayon is an example of a synthetic fibre that is produced from the action of sulphuric acid on cellulose. 4) To manufacture paint pigments The white pigment in paint is usually barium sulphate, BaSO4. The neutralization of sulphuric acid and barium hydroxide produces barium sulphate. 5) As an electrolyte in lead-acid accumulators 6) To remove metal oxides from metal surfaces before electroplating 7) To manufacture pesticides 8) The uses of sulphuric acid in school laboratories are: a. As a strong acid
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b. As a drying or dehydrating agent c. As an oxidizing agent d. As a sulphonating agent e. As a catalyst
Remove metal oxides from metal surfaces before electroplating
As an electrolyte in lead-acid accumulators
Manufacture pesticides
Uses of sulphuric acid Manufacture paint pigments
Manufacture fertilizers
Manufacture detergents
Manufacture synthetic fibres
Figure 9.3 Uses of sulphuric acid
Synthetic fibres 9% As an electrolyte 10%
Metal cleaning 2% Dyes 2% As an acid 2% Fertilisers 32%
Detergents 12% Paint pigment 15%
Other chemicals 16%
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Figure 9.4 Uses of sulphuric acid in industry
9.1.3 The industrial process in manufacture sulphuric acid 1. Sulphuric acid is manufactured by the Contact process. 2. Sulphuric acid is produced from sulfur, oxygen and water via the contact process. 3. The Contact process involves three stages. Sulphur acid
→ Sulphur dioxide → Sulphur trioxide → I
II
Sulphuric
III
4. Stage I: Production of sulphur dioxide gas, SO2. This can be done by two methods, a)
Burning of sulphur in dry air. + O2 → S SO2
b)
Burning of metal sulphide such as zinc sulphide in dry air. 2ZnS + 3O2 → 2SO2 + 2ZnO
5. Stage II: Conversion of sulphur dioxide to sulphur trioxide SO3. 7
This is then oxidised to sulfur trioxide under the following conditions: a) The presence of a vanadium(V) oxide as a catalyst. b) A temperature of between 450°C to 550°C. c) A pressure of one atmosphere 2 SO2 + O2 → 2 SO3 6. Stage III: Production of sulphuric acid a) Sulphur trioxide is dissolved in concentrated sulphuric acid, H2SO4 to produce oleum, H2S2O7
H2SO4+ SO3 →
b) Oleum is reacted with water to form concentrated H2SO4. H2S2O7+ H2O → 2 H2SO4 7. In stage II, sulphur dioxide is dried first before being added to dry air to produce sulphur trioxide. This is: a) To remove water vapour b) To remove contaminants
8.
In stage III, sulphur trioxide is not dissolved directly in water to produce
sulphuric acid. This is because: a)
sulphur trioxide has low solubility in water
b)
sulphur trioxide reacts violently and mists are formed instead of a liquid
Sulphur or metal sulphide burned in air
Sulphur dioxide, SO2 8
a) the presence of a vanadium(V) oxide as a catalyst. b) a temperature of between 450°C to 550°C. c)
a pressure of one atmosphere
Sulphur trioxide, SO3 dissolved in sulphuric acid, H2SO4
Oleum, H2S2O7
diluted with equal volume of water H2O
Concentrated sulphuric acid H2SO4 Figure 9.5 Flowchart of Contact process
9.1.4 Environmental pollution by sulphuric acid 1.
Sulphur dioxide is the main byproduct produced when sulfur-containing fuels such as coal or oil are burned.
2.
Sulphuric acid is formed by atmospheric oxidation of sulphur dioxide in the presence of water. It also produces sulphurous acid.
3.
Sulphuric acid and sulphurous acid are constituents of acid rain.
4.
Acid rain can cause many effects such as: i.
Corrodes concrete buildings and metal structure
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ii.
Destroys trees and plants
iii.
Decrease the pH of th soil and make it become acidic
iv.
Acid rain flows into the rivers and increases the acidity of water and kill aquatic living things.
5.
Hence, we must reduce the sulphur dioxide from the atmosphere by: i.
Use low sulphur fuels to reduce the emission of sulphur dioxide in exhaust gases
ii.
Remove sulphur dioxide from waste air by treating it with calcium carbonated before it is released.
9.2 AMMONIA AND ITS SALT 9.2.1 Properties of ammonia 1.
A colorless, pungent gas.
2.
Its molecular formula is NH3 3.
It is extremely soluble in water.
4.
It is a weak alkali.
5.
It is about one half as dense as air
Figure 9.6 A molecule of ammonia.
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6.
It reacts with hydrogen chloride gas to produce
white fumes of ammonium chloride. NH3 + HCl → NH4Cl
7.
Ammonia is alkaline in property and reacts with dilute acids in
neutralization to produce salts. For examples: NH3 + HNO 3 → NH4NO 3 2NH3 + H2SO4 → (NH4) 2 SO4
8. Aqueous solutions of ammonia produces OH − ions (except Na+ ion, K+ ion, and Ca 32+ ion) forming metal hydroxides precipitate. Fe + + 3OH− → Fe(OH) 3 Brownprecipitate
Mg2+ + 2OH− → Mg(OH) 2 Whiteprecipitate
9. Some metal hydroxides such as zinc hydroxide and copper (II) hydroxide dissolves in excess aqueous ammonia to form complexes. Zn(OH)2 + 4NH3→ [Zn(NH3)4] 2+ + 2OH −
Cu(OH)2 + 4NH3→ [Cu(NH3)4] 2+ + 2OH −
Extremely soluble in water
Weak alkali Properties of ammonia
Colorless
Pungent smell
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Figure 9.7 Properties of ammonia
9.2.2 The uses of ammonia 1.
The major use of ammonia and its compounds is as fertilizers.
2.
Ammonia is also used for the synthesis of nitric acid.
3.
Ammonium fertilizers contain ammonium ions, NH4+, that can be
converted into nitrate ions by bacteria living in the soil. 4.
Nitrogen is absorbed by plants to produce protein in the form of nitrates,
NO3−, which are soluble in water. 5.
The effectiveness of ammonium fertilizers is determined by the percentage
of nitrogen by mass in them. The fertilizer with a higher percentage of nitrogen is more effective. 6.
The percentage of nitrogen by mass can be calculated using this formula: Mass of nitrogen X 100%
Molar mass of fertilizers
9.2.3 The industrial process in manufacture of ammonia 1. Haber process is the industrial method of producing ammonia. 2. It needs direct combination of nitrogen and hydrogen under high pressure in the presence of a catalyst, often iron. 3. Nitrogen gas used in Haber process is obtained from the frictional distillation of liquid air. 12
4. Hydrogen gas used in Haber process can be obtained by two methods: C + H2O → CO + a) The reaction between steam and heated coke (carbon) H2
b) The reaction between steam and natural gas ( consisting mainly of CH4 + 2H2O → CO2 + methane) 4H2
5. In the Haber process: a) A mixture consisting of one volume of nitrogen gas and three volume of hydrogen gas is compressed to a pressure between 200 – 500 atmospheres. b) The gas mixture is passed through a catalyst of powdered iron at a temperature of 450 - 550°C. c) At this optimum temperature and pressure, ammonia gas is produced. N2+ 3H2 → 2NH3
9.3 ALLOYS 9.3.1 Physical properties of pure metals 1. Pure metals have the following physical properties a)Good conductor of electricity b)Malleable c) Ductile d)High melting and boiling point e)High density 2. Pure metals are weak and soft because the arrangement of atoms in pyre metals make them ductile and malleable. a)
A pure metal contains atoms of the same size arranged in a
regular and organized closed-packed structure. 13
b)
Pure metals are soft because the orderly arrangement of atoms
enables the layers of atoms to slide over each other easily when an external force is applied on them. This makes the matels ductile and metals can be drawn to form long wires. c)
There are imperfections in the natural arrangements of metal
atoms. Empty space exist in the structures of pure metals. When hammered or pressed, groups of metal atoms may slide into new positions in the empty spaces. This makes metals malleable, able to be made into different shapes or pressed into thin sheets. 3. The strong forces of attraction between metal atoms requires high energy to overcome it. Hence, most metals have high melting points. 4. high density of
The close-packed arrangement of metal atoms results in the metals.
Good conductor of electricity High melting and boiling point High density
Properties of metals
Malleable Ductile
Figure 9.8 Properties of metals
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9.3.2 Meaning and purpose of making alloys 1. An alloy is a mixture of two or more elements with a certain composition in which the major component is a metal. 2. in the process of alloying, one or more foreign elements are added to a molten metal. When the alloy hardens, the positions of some of the metal atoms are replaced by the atoms of foreign elements, which size may be bigger or smaller than the original metal atoms. 3. In an alloy, these atoms of foreign elements disrupt the orderly arrangement of the metal atoms and also fill up any empty space in the metal crystal structure. 4. Hence, the layers of metal atoms are prevented from sliding over each other easily. This makes the alloy harder and stronger, less ductile and less malleable than its pure metals.
5. The properties of a pure metal are thus improved by making them into alloys. There are three aims of alloying a pure metal: a)
To increase the hardness and strength of a metal
b)
To prevent corrosion or rusting
c)
To improve the appearance of the metal surface
9.4 SYNTHETIC POLYMERS 9.4.1 The meaning of polymers 1. Polymers can be defined as large molecules composed of numerous smaller, repeating units known as monomers which are joined by covalent bonds.
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2. Polymerisation is the chemical process by which the monomers are joined together to form the big molecule known as the polymers. 3. There are two types of polymerization process: a) Addition polymerization b) Condensation polymerization 4. A polymer is a very big molecule (macromolecule). Hence, the relative molecular mass of a polymer is large. 5.
The properties of polymer are different from its monomers. 6. Polymers can be divided into two types: a) Naturally occurring polymers 1.
This type of polymer exists in living things in nature like the plants
and animals. 2. a)
Protein
b)
Carbohydrate
c)
Natural rubber 3.
Examples of naturally occuring polymers are:
Naturally occuring polymers are formed by the joining of
monomers by polymerization. 4.
Protein is formed by the joining of monomers known as amino acid.
5.
Carbohydrate is formed by the joining of monomers known as glucose.
6.
Natural rubber is formed by the joining of monomers known as isoprene. b)
Synthetic polymers 1.
This type of polymer are man-made by chemical process in
the laboratories. 2.
The raw material for synthetic polymers are obtained frompetroleum.
3.
The types of synthetic polymers include: a)
Plastics
b)
Fibres
c)
Elastomers
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4.
Examples of plastics are
polythene(polyethylene),polyvinylchloride(PVC), polypropene (polypropylene), polystyrene , Perspex and bakelite. 5.
Polythene and PVC are produced by addition
polymerization 6.
Examples of synthetics fibres are nylon and terylene. They
are produced by condensation polymerization. 9.4.2 Advantages of synthetic polymers Strong and light Cheap Able to resist corrosion Inert to chemical reactions Easily moulded or shaped and be coloured Can be made to have special properties 9.4.3 Environmental pollution caused by synthetic polymers a)
As most of polymers are non-biodegradable, they will not
decay like other organic garbage. b)
Burning of polymers release harmful and poisonous gases.
9.4.4 Methods to overcome the environmental pollution caused by synthetic polymers a)
Reduce, reuse and recycle synthetic polymers
b)
Develop biodegradable polymers
9.5 GLASS AND CERAMICS 1.
The main component of both glass and ceramic is silica or silicon dioxide, SiO2.
2.
Both glass and ceramic have the same properties as follow a)
Hard and brittle
b)
Inert to chemical reactions
c)
Insulators or poor conductors of heat and electricity 17
d)
Withstand compression but not stretching
e)
Can be easily cleaned
f)
Low cost of production 3.
Differences between glass and cerement are, glass is transparent, while
ceramic is opaque. Ceramic can withstand a higher temperature than normal glass. 4. a)
Types of glass are
Fused glass
b)
•It
is consist mainly of silica or silicon dioxide
•It
has high heat resistance
Soda lime glass •It
c)
cannot withstand high temperatures
Borosilicate glass •It
d)
can withstand high temperature
Lead glass •
5.
High refractive index Uses of improved glass for specific purpose a) Photochromic glass
•
It is sensitive to light intensity b) Conducting glass
•
It conducts electricity 6.
Ceramic is a manufactured substances made from clay, with the
main constituent of aluminosilicate with small quantity of sand and feldspar. 7.
Superconductor is one improved ceramics for specific purposes.
Glass 1. Glass is made up from sand. 2. The major component of glass is SiO2. 3. There are four types of glass which are as follows: • Fused glass • Soda-lime glass • Borosilicate glass 18
• Lead crystal glass
Name of glass
Properties
Chemical composition
Examples of uses
Very high softening point (1700 °C) hence, highly heat resistant Transparent to ultraviolet and infrared light Fused glass
SiO2 (99%) Ba2 O 3 (1%)
Telescope mirrors, Lenses
Difficult to be made
Optical fibres
into different shapes
Laboratory glass
Does not crack when
wares
temperature changes (very low thermal expansion coefficient) Very resistant to chemical reactions Soda lime glass
Low softening point (700 °C), hence, does not withstand heating Breaks easily Cracks easily with
SiO2 (70%) Na2O (15%) CaO
(3%)
Others (5%)
Bottles Windowpanes Light bulbs Mirrors Bowls
sudden temperature
( The most widely
changes (high
used type of glass)
coefficient of expansion) Less resistant to chemical reactions Easy to be made into 19
different shapes
High softening point (800°C). Thus it is heat resistant Does not crack easily with sudden Borosilicate glass
temperature changes Transparent to
SiO2 (80%) Ba2 O 3 (15%)
Laboratory apparatus
Na2O (3%)
Cooking utensils
Al 2 O 3
Electrical tubes Glass pipelines
ultraviolet light More resistant to chemical reactions Does not break easily
Low softening point (600 °C) Lead crystal glass
High density High refractive index Reflects light rays and appears spar
SiO2 (55%) PbO( 30%) K2O (10%) Na2O ( 3%) Al2 O 3 ( 2%)
Decorative items Crystal glasswares Lens Prisms Chandeliers
kling
Ceramics 1. Ceramic is a manufactured substance made from clay that is dried and then
baked in a kiln at high temperature. 2. The main constituent of clay is aluminosilicate, (which consist of aluminium oxide and silicon dioxide) with small quantities of sand and feldspar. 3. Kaolinite is an example of high
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4. Red clay contains iron (III) oxide which gives the red colour . 5. General uses ceramics are as follows of : • very hard and strong but brittle • inert to chemical reaction • has a very high melting point • good electric and heat insulator • able to withstand compression
9.6 COMPOSITE MATERIAL 1.
A composite material is a structural material formed by
combining two or more materials with different physical properties, producing a complex mixture. 2.
The composite material produced will have different properties
far more superior to the original materials. 3.
The composite material produced are harder, stronger, lighter,
more resistant to heat and corrosion and also for specific purposes. 4.
When composite material is formed, the weakness of the
components will not exist anymore.
Composite material
Reinforced concrete
Component
Properties of
Properties of composite
Concrete
component Hard but brittle,
Stronger, higher tensile
With low tensile
strength, not so brittle,
strength Hard with high tensile
does not corrode easily,
Steel
strength but expensive and can corrode
Fibre optics
Glass of low
Transparent, does not
refractive index Glass of high
reflect light rays. Heavy, strong but
can withstand higher applied forces and loads, relatively cheaper Reflect light rays and allow light rays to travel along the fibre 21
refractive index
brittle and non-
Glass
flexible Heavy, strong but
Light, strong, tough,
brittle and non-
resilient and flexible,
flexible Light, flexible, elastic
with high tensile strength
Fibreglass Polyester plastic
and not flammable
but weak and
Photochromic glass
Glass
inflammable Transparent and not
Silver chloride, or
sensitive to light Sensitive to light
silver bromide
Sensitive to light: darkness when light intensity is high, becomes clear when light intensity is low
Figure 9.9 Composite material and their new properties
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CONCLUSION We must appreciate these various synthetic industrial materials. One of the way is by doing continuous research and development ( R & D ) to produce better materials used to improve our standard of living. As we live in a changing world, our society is getting more complex. New materials are required to overcome new challenges and problems we face in our daily lives. Synthetic material are developed constantly due to the limitation and shortage of natural materials. New technological developments are used by scientists to make new discoveries. New materials for clothing, shelter, tools and communication to improve our daily life are developed continuously for the well-being of mankind. New needs and new problem will stimulate the development of new synthetic materials. For example, the new use of plastic composite material will replace metal in the making of a stronger and lighter car body. This will save fuel and improve speed. Plastic composite materials may one day used to make organs for organ transplant in human bodies. This will become necessity with the shortage of human organ donors. The understanding of the interaction between different chemicals is important for both the development of new synthetic materials and the disposal of such synthetic materials as waste. A responsible and systemic method of handling the waste of synthetic materials and their by-product is important to prevent environmental pollution. The
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recycling and development of environmental friendly synthetic material should be enforced.
REFERENCES 1.
Tan Yin Toon, Loh Wai Leng, Tan On Tin, 2008, SUCCESS
Chemistry SPM, Oxford Fajar Sdn.Bhd. 2.
Website http://www.answers.com
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