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GCSE OCR 21st Century Chemistry Chemicals of the natural environment Complete Revision Summary
Chemicals of the natural environment
Ionic Bonding
Covalent Bonding
Metallic Bonding 6
State of Matter
Ionic compounds
Covalent Compounds
Diamond and Graphite
Nanoparticles
Graphene and Fullerene
Hydrocarbons and Crude Oil
Alkanes
Fractional Distillation
Properties of Hydrocarbons
Cracking
Alkenes
Reaction of Alkenes
Alcohols
Carboxylic Acid
Addition Polymerization
Condensation Polymerization
Amino Acids
DNA
BONDINGAtoms bond to gain full outer shell or noble gas electronic configuration Ionic Bonding
transfer of electron between metals and non metals
between metal and non metals
Covalent Bonding
sharing of electron between non metals
between non metals
Metallic Bonding
Electrostatic force of attraction between fixed positive ions and delocalised electrons.
between Metals
Carbon dioxide (CO2) – Covalent Ammonia (NH3) – Covalent Nitrogen (N2) – Covalent Water (H2O) – Covalent Sodium chloride -Ionic BondingCalcium fluoride— Ionic BondingIONIC BONDING: Metals and Non Metals
It is between a metal and a non metal
Metal loses an electron and become positively charged.
Non- Metal gains an electron and becomes negatively charged.
There is a strong electrostatic force of attraction between opposite charged ions resulting in ionic bonding.
Dot and Cross Diagram
Write the symbols
Write electronic configuration
show outer electrons
show transfer
show charges
Example – Aluminium FluorideAl = 2,8,3F = 2,7Example – Magnesium chlorideMg = 2,8,2Cl = 2,8,7PROPERTIES OF IONIC COMPOUNDSIonic Compound Properties
Brittle solids with definite crystal shapes
In Ionic compounds, there is a strong electrostatic force of attraction between the opposite charged ions. This results in the formation of giant ionic lattice.
Good insulators in solid form, but become good conductors in liquid or dissolved form.
In the solid form, the ions are not free to move as they are held together by strong electrostatic force of attraction. In molten or when they are dissolved in water the ions are free to move and conduct electricity.
High melting and boiling point compared to molecular compounds
In Ionic compounds, there is a strong electrostatic force of attraction between the opposite charged ions. This results in the formation of giant ionic lattice. Large amount of energy is required to overcome the strong electrostatic force of attraction. Therefore, ionic compounds have high melting and boiling point.Greater the charge of an ionic lattice, stronger is the electrostatic force of attraction. Greater the melting and bp. For éx – Aluminium chloride > Magnesium chloride > sodium chlorideFORMULAE OF IONIC COMPOUNDS
Write the Symbols
Write the charges
(Upto group the charge is same as the group number. After group 4 it is group number -8)
GCSE OCR 21st Century Chemistry Chemicals of the natural environment Complete Revision Summary
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COVALENT BONDING
It is between two non metals
It involves the sharing of electrons between two non metals.
More than one electron pair can also be shared resulting in the formation of single double and triple bonds.
Properties of Covalent Compounds
Simple Molecule
Eg – O2, CH4
They have weak intermolecular forces in them so have a lower melting and a boiling points
The intermolecular forces increases with increase in size as the surface area between the molecules increases.
Therefore, polymers which have covalent bonding between them have high melting and boiling point due to increase in chain length.
Giant Covalent
Diamond
Graphite
Silicon Dioxide
GIANT COVALENT STRUCTURES
Substances which have huge network of atoms joined together by covalent bonds form giant covalent structures.
DIAMOND
GRAPHITE
It is hard.
It is soft and greasy.
It is an insulator
It is a conductor
It has a high density.
It has a lower density than diamond.
Each carbon atom is covalently bonded to four other carbon atoms giving it a strong rigid structure
Carbon atoms are bonded in the form of layer in the form of hexagons. No covalent bonding between the layers so they can slide past. Each carbon atom is bonded with three other carbon leaving the fourth electron has delocalized
No delocalised electrons present
It has delocalised electrons
Used in cutting or jewellery
It is used in pencil leads.
PROPERTIES OF GRAPHITE
Q1 Why graphite is soft and slippery?
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In graphite, Carbon atoms are bonded in the form of layers in the form of hexagons. No covalent bonding between the layers so they can slide past each other. The layers have only weak intermolecular forces between them. By applying a little pressure then layers can easily slide past each other making Graphite soft and slippery.
Q2 Why graphite conduct electricity ?
In graphite, Carbon atoms are bonded in the form of layer in the form of hexagons. No covalent bonding between the layers so they can slide past. Each carbon atom is bonded with three other carbon leaving the fourth electron has delocalized. These delocalized electrons are mobiles electrons which can move and conduct electricity.
FULLERENE AND GRAPHENE
Fullerene: Hollow shaped molecule having hexagonal rings like a bucky ball.
Also known as bucky ball or buckminsterfullerene.
Carbon can be in the form of pentagon or hexagon rings
Used as catalyst, drug delivery and treating cancer.
Graphene: Layer of interlocking hexagonal rings like single sheet of graphite.
It is a better conductor than graphite, light and have low density.
Used in making computer chips and flexible electronic displays.
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CARBON NANOTUBES
Cylinderical fullerene with the length greater than the diameter.
High tensile strength – Used in making reinforced composite materials
High electronic conductivity – used in electronic industry
METALLIC BONDING
It is between two metals.
There are fixed positive ions present in the sea of delocalised electrons.
There is strong electrostatic force of attraction between fixed positive ions and delocalized electrons resulting in metallic bonding.
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Properties of Metals
Metals are malleable
Malleable means that the metals can be hammered into any shape.
Metals have layered structure and layers can slide past each other by hammering giving metals different shapes.
Metals are ductile
Ductile means that the metals can be drawn into thin wires.
Metals have layered structure and layers can slide past each other by hammering giving metals a wire shape.
Metallic Bonding
Atoms in a metal are arranged in a regular manner and vibrate about fixed positions.
The outermost electrons move freely, forming a ‘sea of electrons’ enveloping the positive metal ions.
Metals are good conductors of electricity
Metals have delocalised electrons.
They are mobile and conduct electricity.
These mobile electrons or delocalised electrons conduct heat and electricity.
Metals have high melting and boiling points
There is strong electrostatic force of attraction between fixed positive ions and delocalized electrons.
Large amount of energy is required to overcome strong electrostatic force of attraction.
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ALLOYS
Alloys are the mixture of metals with another metal or a non metal which make the metal stronger.
In metals the particles are arrranged in layers. There is a regular arrangement of fixed positive ions which can slide past each by applying pressure.
In alloys there is a mixture of metals with another metal or a non metals. Another metal being different in shape and size distort the regular arrangement of the metal lattice.
As a result the layers of the metal can no longer slide past each other making it strong
Example: Steel is the alloy of iron which is more strong and resistant to corrossion.
NANOPARTICLES
Nanoparticles are the particles that deals with the paricles of size 1 to 100 nm.
KIL- Killing MET – Metal MIL -Milo MIC – Mickey NAN – Nano PIC – PicturesConvert 10 nm to
Metre = 10/109m = 10-8m
Micrometer = 10/106m = 10-5m
SURFACE AREA TO VOLUME RATIO
As the size decreases the surface area to volume ratio Increases.
Therefore Nano particles being very small in size have large surface area to volume ratio making them very useful in Science and Medicine.
Surface area = 6 x side x side m2
= 6 x 1000 x 1000
= 6 106 m2
Volume = side x side x side
= 109m3
SA: Volume = 6 x 106/109 = 6 x 103 m
Surface area = 6 x side x side m2
= 6 x 1000 x 1000
= 6 104 m2
Volume = side x side x side
= 106m3
SA: Volume = 6 x 102 m
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APPLICATIONS OF NANOPARTICLES
MEDICINES
To kill cancer and tuomour cells
For drug delievery
CATALYST
They have large surface area to volume ratio.
Used in small quantities so highly effective
COSMETICS
Used in Sunscreen to block sunlight
HOUSEHOLD
Self cleaning window panes
Nano particles breaks dirty in the presence of sunshine which is washed away by water while raining.
RISKS OF NANOPARTICLES
Due to small size can cause difficulty in breathing
They can accumulate in the envrionment and cause air pollution
Due to their large surface area a small spark can result in violent explosion making them risky to use.
They are toxic and cause breathing and respiratory problems.
Due to their small size they can also cause water pollution and risk the aquation life.
STATES OF MATTER
SOLIDS
LIQUIDS
GASES
Particles are close to each other.
Particles are slightly closer to each other.
Particles are far apart.
Have fixed shape
Do not have fixed shape
Do not have fixed shape
Strong forces between the particles
Weak forces between the particles
Very weak forces between the particles.
Have definite volume
Have fixed volume
Do not have fixed volume
cannot be compressed
Can be compressed
Highly compressible
Cannot flow
Can flow
Can flow
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KEY TERMS !!!!
Ions – charged atoms with unequal number of protons and electrons
Ionic Bonding — bond formed between a metal and a non metal which involves complete transfer of electrons from metal to a non metal
Dot and Cross — diagram that show transfer of electron in an ionic bond or sharing of electrons in a covalent bond.
Covalent Bonding— bonding between two non metals which involves sharing of electrons.
Metallic Bonding— bonding in metals which involves strong electrostatic forces of attraction between fixed positive ions and delocalised electrons.
Intermolecular Forces — The forces between the molecules which determines the melting or a boiling point.
Giant Covalent Molecules — Covalently bonded molecules which forms large giant structure
Polymers – Molecules which are made up of many repeating units
Delocalised electrons — Mobile electrons that are free to move as they are not associated with a bond or an atom.
Fullerene— Allotrope of carbon which forms a cage like structure like bucky ball.
Graphene— Allotrope of carbon which is equivalent to single layer of graphite
Alloys— Mixture of metals with another metal or a non metal.
Nanoparticles- particles which are of the size of 1 nm to 100 nm_
Nanoscience—lt is the branch of science that deals with nanoparticles
State Of Matter-Different forms that a matter can take They are solids, liquids and gas
Solids — States of matter with fixed shape and volume.
Liquids— States of matter without fixed shape but fixed volume.
Gases— States of matter with fixed shape and volume.
TEST YOURSELF
Q1 Name the type of bonding in the following compounds :
a) Sodium Chloride – Ionic
b) Magnesium – Metallic
c) Nitrogen – Covalent
d) Carbon Dioxide – Covalent
e) Water – Covalent
f) Ammonia – Covalent
Q2 Draw dot and cross diagram to represent bonding in the following
a) Sodium chloride
b) Water
c) Magnesium
Q3 Differentiate Between Diamond and Graphite
DIAMOND
GRAPHITE
It is hard.
It is soft and greasy.
It is an insulator
It is a conductor
It has a high density.
It has a lower density than diamond.
Each carbon atom is covalently bonded to four other carbon atoms giving it a strong rigid structure
Carbon atoms are bonded in the form of layer in the form of hexagons. No covalent bonding between the layers so they can slide past. Each carbon atom is bonded with three other carbon leaving the fourth electron has delocalized
No delocalised electrons present
It has delocalised electrons
Used in cutting or jewellery
It is used in pencil leads.
Q4 Why Ionic compounds do not conduct electricity in solids ?
In solids, the ions are held together by strong electrostatic force of attraction in the giant ionic lattice. In molten state the ions are free to move therefore conduct electricity
Q5 Why Alloys are stronger than metals
Alloys are the mixture of metals which distors the regular arrangement of metal as a result of which layers are not able to slide past each other making alloys stronger than metals.
Q6 Why alumunium has a stronger melting point than sodium
Aluminium has a greater charge. Due to greater charge of aluminium there is a stronger electrostatic forces of attraction between fixed positive ions and delocalised elecctrons. As a result aluminium has a greater melting point than sodium.
Q7 What are nanoparticles? Write the properties and applications of nanoparticles
Nanoparticles are the particles between the size of 1 to 100 nm_ Due to smaller size they have large surface area to volume ratio making them highly useful in medicine, catalysts, cosmetics and electronic industry.
CRUDE OIL
It is a black thick liquid which takes millions of years to form.
It is the mixture of hydrocarbon.
Hydrocarbon are the compounds made up of carbon and hydrogen only.
The components of the crude oil are important and the crude oil is separated by the process of fractional distillation.
HYDROCARBON PROPERTIES
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FRACTIONAL DISTILLATION OF CRUDE OIL
Separating the mixtures on the basis of boiling points.
It is separated in fractionating column with different substances of similar boiling points
LIQUIFIED GAS
FUEL
GASOLINE/PETROL
CAR FUEL
KEROSENE
AIRCRAFT FUEL
DIESEL OIL
FUEL IN DIESEL ENGINES
RESIDUE
MAKING ROADS
L – LookG – GreatK – KidD – DoingR – RollCRACKING –Thermal decomposition of longer chain hydrocarbon into a shorter chain alkane and alkenes
Thermal CrackingCatalytic Cracking
It is done at a very high temperature It is done using a catalyst
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WHY CRACKING
Shorter chain alkanes are more in demand as they are more efficient fuel which fractional distillation alone cannot meet.
Alkenes are required for polymerization and synthesize other hydrocarbons which fractional distillation cannot meet.
ALKANES – Saturated Hydrocarbon
Carbon-carbon single bond made up of carbon and hydrogen
General Formulae CnH2n+2
Methane – CH4
Ethane – C2H6
Propane – C3H8
Butane – C4H10
Pentane – C5H12
Homologous Series – Members of the same family have similar functional group similar chemical properties and general formulae but different physical property and each members differs from successive by CH2.
COMBUSTION
COMPLETE
INCOMPLETE
FUEL IS COMPLETELY BURNED
FUEL IS PARTIALLY BURNED DUE TO LIMITED SUPPLY OF OXYGEN
PRODUCES CARBON DIOXIDE AND WATER
PRODUCES CARBON MONOXIDE AND WATER
IT IS NOT TOXIC
CARBON MONOXIDE IS TOXIC AS IT DECREASES. THE OXYGEN CARRYING CAPACITY OF RED BLOOD CELLS
PRODUCTS OF COMBUSTIONCarbon Dioxide Test
Limewater Test Carbon Dioxide will turn limewater milky
Water Test
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FUNCTIONAL GROUPSGroups of atoms that give special properties and reactions to the organic molecule
Gentle temperature and pressure. Anaerobic conditions
Nickel catalyst and high temperature and pressure
ADVANTAGES
Uses renewable resources like sugarcane. Less dependent on fossil fuels and due to less energy requirements do not harm the environment.
It is a continuous process. It is rapid more efficient and have 100% atom economy. Produces more pure ethanol
DISADVANTAGES
It is a batch process. The ethanol has to be distilled from time to time as high concentration will kill the yeast. The reaction is slow and produces impure ethanol. Also the atom economy is not 100%
Requires ethene which is dependent on crude oil. Uses non renewable resources.
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REACTIONS OF ALKENES
ALCOHOLS –Have functional Group –OH
General FormulaeCnH2n+1 OH
Formed by replacing hydrogen of alkane with OH group
Used as fuel, solvents, spirits
REACTIONS OF ALCOHOLS
COMBUSTION
It can undergo complete or incomplete combustion. Complete combustion produces carbon dioxide and water.
Ethanol + Oxygen = Carbon dioxide + water
C2H5OH + O2 CO2 + H2O
Incomplete combustion produces carbon dioxide and water.
Ethanol + Oxygen = Carbon monoxide + water
C2H5OH + O2 CO + H2OOXIDATION
Alcohols are oxidised to carboxylic acid in the presence of oxidising agent.
Methanol Methanoic Acid
Ethanol Ethanoic Acid
Oxidising agent used is acidified potassium dichromate solution
METAL
Alcohols react with metals to form salt and hydrogen.
2C2H5OH + 2Ca2C2H5OCa + H2
CARBOXYLIC ACID
Weak Acids Carboxylic Acids are weak acids as they are partially dissociated in water to release H+ ions.
CH3COOH ⇌CH3COO– + H+
Metal oxides and Metal hydroxide
Carboxylic Acid reacts with metal oxides and metal hydroxide to form salt and water.
CH3COOH + NaOHCH3COONa + H2O
Metal carbonate
Carboxylic Acid reacts with metal carbonate to form salt, water and carbon dioxide.
CH3COOH + Li2CO3 CH3COOLi + CO2 + H2O
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ESTERS
Fruity smelling compounds
Used in the manufacture of perfumes, foods and cosmetics.
CARBOXYLIC ACID + ALCOHOLS ESTERS + WATER
Alkyl alkanoate
Methanoic Acid + Methanol Methyl methanoate + Water
ADDITION POLYMERIZATION
The individuals unit that polymerizes to form a polymers is known as a monomers. Eg Ethene
The structure formed by the polymerization of the monomer is a polymers.
Polymers are materials made by linking up smaller repeating chemical units.
Some bend and stretch – rubber and polyester.
Some hard and tough – epoxies and glass.
ADDITION POLYMERS
a) Formed by addition reaction.
b) Require only one monomer generally an alkene
c) Nothing is lost in the reaction.
eg Polyethene, polypropene
CONDENSATION POLYMERS
a) Requires two monomers
b) Requires two functional group
c) Formed by condensation reaction.
d) A small molecule of water is
e) Example: Nylon a polyester
NATURAL POLYMERS
a) They are found naturally
b) All the complex biomolecules are polymers
Monomer
Polymer
Glucose
Starch
Proteins
Amino Acid
Nucleotide
DNA
DNA
a) DNA is polynucleotide
b) Nucleotide = Phosphate + Sugar + Nitrogenous Bases
c) There are four bases present in the DNA
Adenine
Thymine
Guanine
Cytosine
KEY TERMS
Hydrocarbon – Hydrocarbon are the compounds made up of carbon and hydrogen only.
Crude Oil – It is a black thick liquid which takes millions of years to form. It is the mixture of hydrocarbon.
Fractional Distillation – Separating the mixtures on the basis of boiling points.
Alkanes – Saturated Hydrocarbon. Carbon-carbon single bond. Made up of carbon and hydrogen only
Saturated hydrocarbon – Saturated Hydrocarbons have only carbon-carbon single bonds.
Unsaturated hydrocarbon – Unsaturated Hydrocarbons have carbon-carbon double bonds and triple bonds.
General Formula – It applies to families of compounds; provides a way to predict the molecular formula of the molecule, based on the number of carbon atoms it contains.
Viscosity – movement of flow. A fluid with low viscosity flows easily
Flammable – Flammable materials are combustible materials that can easily ignite at room temperature
Complete Combustion – Fuel is completely burned. Produces Carbon dioxide and water.
Incomplete Combustion – Fuel is partially burned due to limited supply of oxygen. Produces Carbon Monoxide and Water.
Cracking – Thermal decomposition of longer chain hydrocarbon into a shorter chain alkane and alkenes
Alkenes – Unsaturated Hydrocarbon. Compounds which have carbon-carbon double bond. Compounds made up of carbon and hydrogen only
Functional Group – Groups of atoms that give special properties and reactions to the organic molecule
Homologous Series – Members of the same family have similar functional group similar chemical properties and general formulae but different physical property and each members differs from successive by CH2Alcohols – Have functional Group –OH. The General Formulae of Alcohols is CnH2n+1 OH. Used as fuel, solvents, spirits
Carboxylic Acid – Carboxylic Acids are weak acids as they are partially dissociated in water to release H+ ions.
Esters – Fruity smelling compounds. Used in the manufacture of perfumes, foods and cosmetics.
Fermentation – Fermentation is a metabolic process that produces chemical changes in organic substrates through the action of enzymes.
Weak Acid – Weak acids are only partially ionized in their solutions.
Monomers – The individuals unit that polymerizes to form a polymers is known as a monomers. Eg Ethene
Polymers – The structure formed by the polymerization of the monomer is a polymers. Polymers are materials made by linking up smaller repeating chemical units.
Some bend and stretch – rubber and polyester.
Some hard and tough – epoxies and glass.
Addition Polymerization – It is the process of repeated addition of monomers with double or triple bonds to form polymers. There is no loss of an atom or a molecule. Ex – PVC, polyethene, Teflon.
Condensation Polymerization – It is a process that involves repeated condensation reactions between two different monomers. There is a loss of a molecule of water, ammonia etc as a by-product. Ex – Nylon, bakelite, silicon.
Monosaccharide – Simplest carbohydrates (single units). They cannot be hydrolyzed into smaller units. Ex – Glucose, fructose.
Polysaccharide – Formed of numerous monosaccharide units. Ex – starch, cellulose
Starch – It is the reserve food material of plant cells. It consists of two components- amylose and amylopectin, both glucose polymers.
Cellulose – Main structural polysaccharide of plants. It is a long, unbranched chain of about 6,000 glucose units with molecular weight between 0.5 to 2.5 million.
Proteins – The proteins are linear unbranched polymers of Amino acids. The proteins are composed of carbon, hydrogen, oxygen, nitrogen, and Sulphur.
DNA – It is a long, double chain of deoxyribonucleotide units. DNA is the genetic material and forms molecular basis of heredity in all organisms.
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References:
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Carbon dioxide (CO2) – Covalent
Ammonia (NH3) – Covalent
Nitrogen (N2) – Covalent
Water (H2O) – Covalent
Sodium chloride -Ionic Bonding
Calcium fluoride— Ionic Bonding
IONIC BONDING: Metals and Non Metals
Example – Magnesium chloride
Mg = 2,8,2
Cl = 2,8,7
PROPERTIES OF IONIC COMPOUNDS
Ionic Compound Properties
Simple Molecule
Q2 Why graphite conduct electricity ?
In graphite, Carbon atoms are bonded in the form of layer in the form of hexagons. No covalent bonding between the layers so they can slide past. Each carbon atom is bonded with three other carbon leaving the fourth electron has delocalized. These delocalized electrons are mobiles electrons which can move and conduct electricity.
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Example: Steel is the alloy of iron which is more strong and resistant to corrossion.
KIL- Killing
MET – Metal
MIL -Milo
MIC – Mickey
NAN – Nano
PIC – Pictures
Convert 10 nm to
Surface area = 6 x side x side m2
= 6 x 1000 x 1000
= 6 106 m2
Volume = side x side x side
= 109m3
SA: Volume = 6 x 106/109 = 6 x 103 m
Surface area = 6 x side x side m2
= 6 x 1000 x 1000
= 6 104 m2
Volume = side x side x side
= 106m3
SA: Volume = 6 x 102 m
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FUNCTIONAL GROUPS
Groups of atoms that give special properties and reactions to the organic molecule
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