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Materials and their uses. Structure of Materials. The specification states;. Materials behave as they do because of their structure; the way their atoms and molecules fit together You need to know; - how the internal structure of a material influences the way it behaves
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Materials and their uses Structure of Materials
The specification states; Materials behave as they do because of their structure; the way their atoms and molecules fit together You need to know; - how the internal structure of a material influences the way it behaves - ways in which properties materials can be modified by altering the structure of the material
Materials Salt -ionic Copper - metallic Diamond - covalent
Why choose the three materials? • salt • copper • diamond Materials behave as they do because of their structure; the way their atoms and molecules fit together
Properties of Materials We have known many of the properties of materials for thousands of years • Metals are shiny, they have a high melting point, they are malleable, ductile, they are insoluble and they conduct electricity* • Salt is an ionic compound. It is crystalline, it is soluble in water, has a high melting point and it conducts electricity in solution* • Diamonds are covalent. They are crystalline, they have a high melting point, they are insoluble and they do not conduct electricity* *All later discoveries
Why? • We know how materials behave – their properties • The next question is why? • An important development in our scientific knowledge pointed to the answer i.e. The understanding that electricity is a flow of charged particles The flow of charge is called the current and it is the rate at which electric charges pass though a conductor. The charged particle can be either positive or negative.
Conducting electricity Two types of materials that we know conduct electricity are • Metals • Salt (in solution or molten) The search to find their ‘charged particles’ eventually led to an understanding of the structure and properties of materials
Structure of the Atom The bigger the orbit – the higher the energy Electrons can move between energy levels. To move up they must take in energy (incoming radiation) / when moving down they give out energy as electromagnetic radiation
Metals Metals conduct electricity • They have charged particles which are free to move The understanding that electricity is a flow of charged particles
Metallic Bonding Each atom loses control of its outer shell electron resulting in a lattice of positive ions surrounded by a ‘sea’ of electrons
Metallic bonding is the result of strong electrostatic attraction between the positive core and the negative ‘sea’ of electrons The strength of the bond gives metals their high melting point The melting point of gold is 1064oC
Crystals in metals Metals have a crystalline structure which is not usually visible When the metal first solidified from the molten state, millions of tiny crystals grow The longer the metals takes to cool, the larger the crystals
Grains • When the molten metal solidifies, different regions crystallise at the same time • The crystalline areas are known as ‘grains’ • Eventually growing grains meet at grain boundaries • At these boundaries there are can be atoms which do not fit into the crystal structure dislocation
Metals objects are formed by casting • Molten metal is pored into a mould and allowed to cool • As the metal cools small crystals (grains) appear • The crystals grow until they form a solid mass of small crystals • The objects formed from the casting process have dislocations
Properties of metals • Hard but malleable and ductile – metals can be hammered into sheets or drawn into wires because blocks of atoms or grains can slip or roll over one another. • This movement is helped by the • presence of dislocations
If a small stress is put onto the metal, the layers of atoms will start to roll over each other. If the stress is released again, they will fall back to their original positions. Under these circumstances, the metal is said to be elastic. • If a larger stress is put on, the atoms roll over each other into a new position, and the metal is permanently changed.
Conduct electricity because the delocalised electrons are free to move to move around the structure • Are shiny because as light shines on the metal the electrons absorb energy and jump temporarily to a higher energy. When the electron falls back to its lower level the extra energy is emitted
The energy is emitted as light and as different metal elements have different separations in the electron orbits they emit different quantities of energy
Flame tests Lithium Red Sodium Yellow Potassium Lilac Calcium Brick red Barium Green
Flame tests Aurora Borealis
Cold Working Metals can be ‘cold –worked’ – forced into new shapes at a low temperature This creates more dislocations in the crystals The more dislocations a metal has, the more they get in the way of each other The metal becomes stronger but less ductile – more brittle
Annealing • Annealing is a treatment used to restore softness and ductility to metals • The metal is put in a furnace to soften the metal • It is then allowed to cool slowly so that new crystals form and there are fewer dislocations
Alloying – mixing elements one of which is a metals • a. Prevent rust(corrosion) Chromium and nickel are added to iron to form stainless steel. The chromium can form an oxide layer that can prevent iron from oxidising (rust). Suitable for make cutlery, sinks etc.b. To make it harder Carbon is added to Iron to form steel. Steel is very hard, however brittle also. Suitable for making bridges, car bodies, pipes etc.
Aluminium is very light but very malleable. When it is added to copper and magnesium, it forms duralumin which is very hard, withstands corrosion and lightweight. It is strong but light enough to make an airplane body. c. To improve the appearance A normal metal usually gets dull when it exposed to air, water and uv light over a long time. To create an attractive surface and look, metals such as nickel and chromium are added. Nickel is added to copper to form an alloy used to make coins attractive and shiny
Salt Salt conducts electricity when it is dissolved in water Chlorine 35Cl 17 The understanding that electricity is a flow of charged particles There must be charged particles which are free to move
An atom has no charge: number of positive protons = number of negative electrons When sodium loses an electron it becomes a charged particle/ a positive ion When chlorine gains an electron it becomes a charged particle/ a negative ion
Ionic Bonding As with metals the strong electrostatic attraction between the positive and negative ions results in ionic compounds having a high melting point (salt melts at 808oC) Ionic compounds conduct because when they are dissolved in water they separate into positive and negative ions (the charged particles) which move to the positive and negative terminals
Carbon • Carbon is all around us • It’s in proteins, fats, carbohydrates • It makes up 20% of the human body • We use it to symbolise love and commitment and to write on paper • It is the main component in fossil fuels • It is a key ingredient in the emerging field of nanotechnology
Diamond • Diamond does not conduct electricity Diamond consists of atoms of carbon bonded together to form a material with a very high melting point It has no free charged particles An uncut diamond
Bonding in diamond Carbon atoms are bonded by sharing electrons in a covalent bond • Covalent bonds form when outer shell electrons are attracted to the nuclei of more than one atom • Both nuclei attract the electrons equally so keeping them held tightly together
Giant Covalent Bonding Repeating crystal lattice High melting point due to strength of covalent bonds (3550oC) Cannot conduct electricity as it has no free charged particles
Graphite Like diamond graphite has strong covalent carbon to carbon bonds and a high melting point (3720OC) Graphite conducts electricity The bonds between the covalently bonded sheets of carbon are weak bonds and the electrons are easily attracted to a positive terminal
Fullerenes C60 Buckyball ‘Buckyball’ Carbon nanotube Discovered in 1985 Fullerenes are a type of carbon made up of ‘cages’ or tubes of at least 60 atoms of carbon
Fullerenes are highly stable chemically and have a variety of unusual properties. • Chemists have been able to add branches of other molecules to them, place atoms inside of them, and stretch them into rods and tubes. Fullerenes can be made to be magnetic, act as superconductors, serve as a lubricant, or absorb light. Current work on the fullerene is largely theoretical and experimental. Recent research has suggested many uses for fullerenes, including medical applications, superconductors, and fibre-optics.
Polymers The largest group of covalent compounds are polymers Polymers are long carbon chains sometimes with different functional groups added and all held together by covalent bonds The bonding in a polymer chain is strong covalent bonding The bonding between chains can create either thermsoftening plastics or thermosetting plastics
Polymer Monomer polyester polytetrafluorethylene polyvinylchloride
Thermoplastics • In thermosoftening plastics like poly(ethene) the bonding is like ethane except there are lots of carbon atoms linked together to form long chains. They are moderately strong materials but tend to soften on heating and are not usually very soluble in solvents. Can be recycled A thermosoftening plastic (thermoplastic) Weak bonds between chains
Thermoplastics Polyethene, polypropene,polyvinylchloride, polytetrafluoroethylene
These can be heated enough to be reshaped. This stretches the cross links. When cooled in the stretched state they stay stretched and retain the new shape • If reheated the • chains are free • to slide back to their • original shape
Fibres nylon Hydrogen Bonding Hydrogen bonding is a result of the electrostatic attraction between hydrogen and oxygen due their different electronegativities
Thermoset plastics • Thermosetting plastic structures like melamine have strong 3D covalent bond network they do not dissolve in any solvents and do not soften on heating and are much stronger than thermoplastics They do not lend themselves to recycling like thermosoftening plastics which can be melted and re-moulded. A thermosetting plastic Covalent bonds between chains)
Thermosets Bakelite, melamine resin, epoxy, urea formaldehyde
Both thermoplastics and thermoset plastics can be strong, tough, rigid and stable towards chemical attack • Bonds between atoms are strong covalent bonds so they do not conduct electricity • Bonds between chains are weak intermolecular bonds • When plastics melt or dissolve it is the intermolecular forces that are broken so the different parts can slide past one another