Zusammenfassung der Ressource
1_Chemistry (C2)
- C2.1 - Structure and bonding
- Chemical bonding
Anmerkungen:
- Elements react to form compounds by gaining, sharing or losing electrons.
- Elements react to form compounds by gaining, sharing or losing electrons.
- The element is ALWAYS trying to get to a noble gas configuration.
- Atoms involved in chemical bonding are in the OUTER SHELL.
- Ionic bonding
Anmerkungen:
- Held together by strong forces between the oppositely charged ions.
- -Gaining or losing electrons.
-When a non-metal and metal react.
- Characteristics
Anmerkungen:
- -Giant structure (or latice)
-High melting and boiling point.
-Hard and Brittle.
-Conduct electricity in water.
- High melting and
boiling points
Anmerkungen:
- High temperature required to break the positive and negative attraction.
- Conductors
Anmerkungen:
- In water, dissociated ions are free to conduct an electric charge.
- MOLTEN ionic compounds (salts) also conduct electricity.
- Representation
Anmerkungen:
- Ionic bonding can be shown by: dot and cross diagrams.
- Example
- Formulae of ionic compounds
Anmerkungen:
- The charges on the ions in an ionic compound always cancel each other out.
- Brackets
Anmerkungen:
- Used when we need to multiply ions. An example of this is:
Ca(OH)₂ - Need two hydroxide ions.
- Covalent bonding
Anmerkungen:
- Sharing electrons
- -Sharing electrons
-When two non-metals react.
- Substances containing covalent bonds consist of simple molecules, but some have giant covalent structures.
- Characteristics
Anmerkungen:
- -Low melting and boiling points.
-Don't conduct electricity well.
- Low melting and
boiling points
Anmerkungen:
- Weak intermolecular forces break down easily.
- Conductors
Anmerkungen:
- They do not have free electrons or an overall electrical charge.
- Representation
Anmerkungen:
- We can use dots and crosses to show where the electrons are shared, on each atom.
- Example
- Metals
Anmerkungen:
- The atoms in metals are:
-CLOSELY packed together.
-Arranged in REGULAR layers.
- Higher tier
Anmerkungen:
- -Electrons in the highest energy level are delocalized.
-They can move FREELY.
-Produces a lattice of positive ions in a 'sea' of moving electrons
-The DELOCALISED ELECTRONS strongly attract the positive ions and hold the giant structure together.
- Characteristics
Anmerkungen:
- -Good conductors of heat and electricity.
-Malleable
-Ductile
- Conductors
Anmerkungen:
- Free electrons carry heat or carry a charge throughout the metal.
- Malleable and
ductile
Anmerkungen:
- Free electrons allow metal atoms to slide over each other.
- C2.2 - Structure and properties
- Giant ionic structures
Anmerkungen:
- -Strong electrostatic forces hold ions together.
-Solids at room temperature.
-High melting and boiling points
- Melting
Anmerkungen:
- -MELTING = free electrons/ions
-Allows them to carry electrical charge.
-Therefore conduct electricity.
- Dissolving
Anmerkungen:
- -Some ionic structures dissolve in water.
-Water molecules can split up the lattice.
-Ions are free to move therefore conduct electricity.
- Simple molecules
Anmerkungen:
- -Held together by strong covalent bonds.
-ONLY act between atoms of molecule.
-Low melting and boiling points.
-No electricity conduction.
- Intermolecular forces (H)
Anmerkungen:
- -Intermolecular forces are the forces of ATTRACTION.
-Broken when boiled or melted.
-Small molecules (H₂, CH₄) have weakest intermolecular forces, thus they are gases at RT.
-Larger molecules (Br₂) have stronger attractions, so may be liquids at room temperature.
-I₂ is a solid at room temperature.
- Giant covalent structures
Anmerkungen:
- -Atoms of some elements can form several covalent bonds.
-Atoms can join together to make GCS's (macromolecules).
-Every atom joined to several other atoms (STRONG bonds).
-Therefore, VERY high melting point.
- Diamond
Anmerkungen:
- -Form of carbon that has a regular 3-D giant structure.
-Each carbon atom covalently bonded to four others.
-Makes diamond hard and transparent.
-Silicon dioxide IS SIMILAR.
- Graphite
Anmerkungen:
- -Form of carbon (2-D layers)
-One carbon atom is covalently bonded to three others.
-No covalent bonds between layers, so they slide over each other.
-Graphite is slippery and grey.
- -One electron from each carbon atom is delocalised.
-Allows graphite to conduct heat and electricity.
-Weak intermolecular forces between layers in graphite, meaning layers can slide over each other easily.
- Fullerenes
Anmerkungen:
- -Large molecules from hexagonal rings of carbon.
-Rings join together to form cage-like shapes with different numbers of carbon atoms (some are NANO-SIZED).
- Giant metallic structures
Anmerkungen:
- When we bend and shape metals, the layers of atoms in the giant metallic structure slide over each other.
- Alloys
Anmerkungen:
- -Mixtures of metals or metals mixed with other elements.
-Different sized atoms distort layers in metal structure therefore difficult for them to slide.
-Alloys are harder than pure metals.
- Shape memory alloys
Anmerkungen:
- -Bent or deformed into a different shape.
-When heated, they return to original shape.
-Used for many things: e.g. dental braces.
- Metal structures
Anmerkungen:
- -Delocalised electrons (move throughout the giant metallic lattice and transfer energy quickly).
-Good conductors of heat and electricity.
- Properties of polymers
Anmerkungen:
- Depends on the monomers used to make them.
Could also depend on the reaction conditions.
- Poly(ethene)
Anmerkungen:
- Low density (LD) poly(ethene) and high density (HD) poly(ethene) are made using different catalysists and different reaction conditions.
- Changing reaction conditions can also change the properties of the polymer that is produced.
- Thermosoftening
polymers
Anmerkungen:
- -Poly(ethene) is an example.
-Made up of individual polymer chains that are tangled together.
-Heated - soft.
-Cooled - hard.
-Can be heated to mould into shapes and remoulded through heating again.
- -Forces between polymer chains are weak.
-When heated, these weak intermolecular forces are broken and polymer becomes soft.
-When cooling down, intermolecular forces bring polymer molecules back together, thus hardening polymer.
- Thermosetting
polymers
Anmerkungen:
- -Do not melt or soften when heated.
-Polymers set hard when first moulded.
-Due to strong covalent bonds forming cross-links between their polymer chains.
-Strong bonds hold polymer chains in position.
- Nanoscience
Anmerkungen:
- The study of small particles that are between 1 and 100 nanometres in size.
- Nanoparticles
Anmerkungen:
- -1 nanometre is 10−⁹m.
-Very small sizes give them:
--BIG surface area.
--New properties which make them very useful materials.
- Nantechnology
Anmerkungen:
- Uses nanoparticles to:
--Highly selective sensors.
--Very efficient catalysts.
--New coatings.
--New cosmetics.
--Improvement in construction materials.
- The Future
Anmerkungen:
- -VERY EXCITING.
-Unpredictable consequences for our health and the environment.
-MORE research needed to find out effects.
- C2.3 - How much?
- The mass of atoms
Anmerkungen:
- Protons - 1
Neutrons - 1
Electrons - 0
- Mass number
Anmerkungen:
- Total number of protons and neutrons.
- Atomic number
Anmerkungen:
- (Or the proton number)
The number of protons and electrons in an atom.
- Isotopes
Anmerkungen:
- Atoms of the same element with DIFFERENT numbers of NEUTRONS.
- Masses of atoms and moles
Anmerkungen:
- We use relative atomic masses to compare the masses of atoms.
- Relative atomic mass
Anmerkungen:
- Relative atomic mass (Ar) is an average value that depends on the isotopes the element contains.
- Relative formula mass
Anmerkungen:
- (Mr) Adding up all the relative atomic masses of the atoms in its formula.
- Moles
Anmerkungen:
- One mole of a substance is its relative formula mass in grams.
- Percentages
- Percentage
composition
Anmerkungen:
- Divide the relative atomic mass of the element by the relative formula mass of the compound then multiply by 100.
- Example
Anmerkungen:
- Percentage of C in CO₂:
C = 12 , O = 16
Mr of CO₂ is: 12 + 32 = 44
So:
12/44 x 100 = 27.3%
- Empirical formula
Anmerkungen:
- Simplest ratio of atoms or ions in a compound.
- To work out:
-Mass in 100g
-Mass / Ar
-Divide by smallest (mass/Ar)
-Convert to Empirical formula
-REMEMBER: You can't have a decimal of an atom, so convert to integers.
- Example
Anmerkungen:
- Empirical formula of the hydrocarbon that contains 80% C
-Mass in 100g (C=80 , H=20)
-Mass/Ar (C=80/12=6.67 , H=20/1=20)
-Smallest ratio (C=6.67/6.67 = 1 , H=20/6.67=3)
-Empirical formula is CH₃
- Molecular formula
Anmerkungen:
- -Empirical formula not always the same as molecular formula in covalent compounds.
-e.g. Ethane's molecular formula is: C₂H₆ BUT its empirical formula is CH₃
- Masses from
chemical equations
Anmerkungen:
- To work out:
-Calculate Mr for all compounds.
-Work out how much the product weighs.
-(The amount you have / mole amount) x Mr of thing you are trying to work out
- Yield
Anmerkungen:
- The yield of a chemical reaction describes how much product is made.
- The percentage yield tells us how much product is made compared with the maximum amount that could be made.
- Formula
Anmerkungen:
- Formula for Percentage Yield:
(amount of product collected / maximum amount of product possible) x 100
- Why?
Anmerkungen:
- It isn't possible to collect the amounts calculated from the chemical equation because:
-Incomplete reaction
-Other reactions may happen.
-Product may be lost when it is seperated or collected from the apparatus.
- High yields
Anmerkungen:
- Good for industry as it:
-Conserves resources
-Reduces waste.
- Chemical processes should also waste as little energy as possible so that:
-There is a reduction in pollution.
-It makes production more sustainable.
- Reversible reactions
Anmerkungen:
- In a reversible reaction, the products of the reaction can react to make the original reactants.
- Reversible reactions are shown by this sign: ⇌
- Example
Anmerkungen:
- Ammonium chloride ⇌ ammonia + hydrogen chloride
- Chromotography
Anmerkungen:
- The process whereby small amounts of dissolved substances are separated by running a solvent along a material such as absorbent paper.
- Paper
Chromotography
Anmerkungen:
- Used to identify food additives, such as artificial colours.
- The process:
-A spot of colour is put onto paper and a solvent can move through it.
-The colours move different distances depending on their solubility.
- Gas
Chromotography
Anmerkungen:
- Used to separate mixtures so that compounds can be identified.
- The process:
-Mixture is carried by a gas through a long column packed with particles of a solid.
-Individual compounds travel at different speeds and come out at different times.
-Amount of substance leaving column at different times is recorded against time and shows:
--Number of compounds
--Retention times
- Mass spectrometer
Anmerkungen:
- This is connected to the gas chromatography column to give further data.
- Relative molecular masses
Anmerkungen:
- A GC-MS can give the relative molecular mass of a compound. It can do this by reading off the molecular ion peak, which is furthest to the right on the mass spectrum.
- C2.4 - Rates and energy
- Rate of reaction
Anmerkungen:
- Measures the speed of a reaction or how fast it is.
- Equation
Anmerkungen:
- Rate of reaction = amount of reactant used / time
- Rate of reaction = amount of product formed / time
- Gradient
Anmerkungen:
- The gradient of the line on a graph of amount of reactant or product against time tells us the reaction at that time. The steeper the gradient. the faster the reaction.
- The faster the rate, the shorter the time it takes for the reaction to finish. So rate is INVERSELY PROPORTIONAL to time.
- Collision theory
Anmerkungen:
- -Reactions can only happen if particles collide.
-Particles must collide with enough energy to create new substances.
-This minimum energy is called the activation energy.
- IMPORTANT to learn each node word by word.
- The effect of temperature
Anmerkungen:
- Increasing the temperature increases the kinetic energy of particles therefore they will collide more frequently with enough activation energy and so the rate of reaction will increase.
- A rise of 10°C will roughly double the rate of many reactions, so they go twice as fast.
- The effect of surface area
Anmerkungen:
- The rate of a chemical reaction increases if the surface area of any solid reactant is increased. This increases the frequency of collisions between reacting particles.
- The effect of catalysts
Anmerkungen:
- -Catalysts change the rates of chemical reactions.
-Catalysts that speed up reactions lower the activation energy required, therefore more successful collision occur.
- Catalysts do not get used up during a chemical reaction.
- Different catalysts are needed for different reactions.
- The effect of
concentration
Anmerkungen:
- Increasing concentration increases the frequency of successful collisions (these are the ones with the activation energy). This therefore will increase the rate of reaction.
- The effect of pressure
Anmerkungen:
- Increasing pressure increases the frequency of collisions because particles are closer together since they occupy a smaller volume. This will increase the frequency of collisions with enough activation energy and so increases the rate of reaction.
- Catalysts in action
Anmerkungen:
- -Catalysts are used in industry to increase the rate of reactions and reduce energy costs.
-This means that less fossil fuels are burned. therefore conserving resourcing and reducing pollution
- Traditional
catalysts
Anmerkungen:
- Often transition metals or their compounds. However, some of these are toxic and may cause harm to the environment.
- Modern catalysts
Anmerkungen:
- Being developed in industry which result in less waste and are safer for the environment.
- Exothermic and
endothermic
reactions
Anmerkungen:
- In a reaction, energy may be transferred to or from the reacting substances.
- Exothermic
Anmerkungen:
- Reactions that transfer energy to the surroundings.
- Examples
Anmerkungen:
- -Combustion (burning fuels)
-Oxidation reactions (respiration)
-Neutralization reactions (involving acids and bases)
- Uses
Anmerkungen:
- Used in hand warmers and self-heating cans.
- Endothermic
Anmerkungen:
- Reactions which take in energy from the surroundings.
- Examples
Anmerkungen:
- Some cause a decrease in temperature and others require a supply of energy.
- Solid compounds that are mixed with water cause temperature decrease because endothermic changes happen as they dissolve
- Thermal decomposition reactions need to be heated continuously to keep the reaction going.
- Uses
Anmerkungen:
- Used in instant cold packs for sports injuries.
- Energy and
reversible
reactions
Anmerkungen:
- In reversible reactions, the reaction in one direction is exothermic and in the other, endothermic.
- Example
Anmerkungen:
- Hydrated copper sulfate ⇌ anhydrous copper sulfate
CuSO₄⋅5H₂O ⇌ CuSO₄ + 5H₂O
- The hydrated copper sulfate must be heated continuously for the reaction to complete, because it is an endothermic reaction.
- Adding water to the anhydrous copper sulfate causes the mixture to get hot, because it is an exothermic reaction.
- C2.5 - Salts and electrolysis
- Acids and Alkalis
Anmerkungen:
- Acids are substances that produce H⁺(aq) ions, when they are added to water.
- Alkalis are bases that dissolve in water to make alkaline solutions. They produce OH⁻ ions.
- Bases
Anmerkungen:
- React with acids and neutralizes them.
- pH scale
Anmerkungen:
- Potential Hydrogen scale - it shows how acidic or alkaline a solution is.
- Salts from metals
or bases
Anmerkungen:
- Acids will react with metals that are above hydrogen in the reactivity series.
- Equation
Anmerkungen:
- Acid + Base → Salt + Hydrogen
- When this happens, a neutralisation reaction take place.
- Crystals
Anmerkungen:
- Salts can be crystalllised from solutions by evaporating off water.
- Examples
Anmerkungen:
- HCl → Chlorides
HNO₃ → Nitrates
H₂SO₄ → Sulfates
- Salts from solutions
Anmerkungen:
- We can make soluble salts by:
Acid + Alkali → Salt + Water
- Neutralisation
Anmerkungen:
- H⁺(aq) + OH⁻(aq) → H₂I(l)
- Insoluble salts
Anmerkungen:
- Mixing solutions of soluble salts that contain the ions needed, in order to form a precipitate (insoluble salt).
- Precipitation
Anmerkungen:
- An important way of removing some metal ions from industrial waste water.
- Electrolysis
Anmerkungen:
- -Electricity is used to break down ionic compounds into elements.
-When electricity is passed through molten ionic compounds or a solution containing ions, electrolysis takes place.
-Substance broken down is an electrolyte.
- Electrodes
Anmerkungen:
- -Made of an inert substance that doesn't react with the products.
-Ions which move to either electrode are discharged to produce elements.
- Anode
Anmerkungen:
- Negatively charged ions are attracted to the anode, losing their charge and forming non-metallic elements.
- Cathode
Anmerkungen:
- Positively charged ions are attracted to the cathode, losing their charge and forming either hydrogen or metals, depending on the electrolyte.
- Changes at the electrodes
Anmerkungen:
- When an ion reaches an electrode, they lose or gain electrons to become neutral atoms.
- OILRIG
Anmerkungen:
- Oxidation
Is
Loss
Reduction
Is
Gain
- Oxidation
Anmerkungen:
- Negative ions lose electrons to become neutral atoms, with some non-metals forming molecules.
- Reduction
Anmerkungen:
- Positive ions gain electrons.
- Half equations
Anmerkungen:
- Anode: 2Br⁻ → Br₂ + 2e⁻
Cathode: Pb²⁺ + 2e⁻ → Pb
Anode - Losing electrons.
Cathode - Gaining electrons.
- Aqueous solutions
Anmerkungen:
- Water contains hydrogen and hydroxide ions.
- Negative electrode
Anmerkungen:
- Hydrogen may be produced at the negative electrode if the positive ions in the solution are those of a metal more reactive than hydrogen.
- Positive electrode
Anmerkungen:
- Oxygen is usually produced. If the solution has a high concentration of a halide ion, then a halogen will be produced.
- Extraction of aluminium
Anmerkungen:
- Aluminium oxide is electrolysed, because aluminium is more reactive than carbon. We do this to manufacture aluminium.
- Cryolite
Anmerkungen:
- Added to aluminium oxide to reduce the melting temperature (from 2000°C to 850°C)
- Electrodes
Anmerkungen:
- Different products are formed at either electrode.
- Anode
Anmerkungen:
- Oxide ions are oxidised to oxygen atoms by losing electrons and these oxygen atoms form oxygen molecules.
- Substances
Anmerkungen:
- -Anode is made of carbon.
-At high temperatures, the oxygen reacts with the carbon to form carbon dioxide.
-All the carbon electrodes gradually burn away, therefore they must be replaced regularly.
- Cathode
Anmerkungen:
- Aluminium ions are reduced to aluminium atoms by gaining electrons. The molten aluminium is collected from the bottom of the cell.
- Electrolysis of brine
Anmerkungen:
- Brine is a solution of sodium chloride in water.
- Brine ions
Anmerkungen:
- Brine contains:
-Na⁺ sodium ions
-H⁺ hydrogen ions
-Cl⁻ chloride ions
-OH⁻ hydroxide ions
- Electrodes
- Anode
Anmerkungen:
- Chlorine is produced from the chlorine ions.
2Cl⁻ → Cl₂ + 2e⁻
- Cathode
Anmerkungen:
- Hydrogen ions.
2H⁺ + 2e⁻ → H₂
- Leaving
Anmerkungen:
- A solution of sodium ions and hydroxide ions.
- Products
Anmerkungen:
- Sodium hydroxide is a strong alkali and has many uses:
-Soap
-Paper
-Bleach
-Neutralising acids
-Controlling pH
- Chlorine is used to:
-Kill bacteria in drinking water and swimming pools.
-Make bleach.
-Make disinfectant.
-Make plastics.
- Hydrogen is used to:
-Make margarine.
-Make hydrochloric acid.
- Electroplating
Anmerkungen:
- Uses electrolysis to put a thin coating of metal onto an object.
- Uses
Anmerkungen:
- Electroplating is used to:
-Make the object look more attractive.
-Protect a metal object from corroding.
-Increase the hardness of a surface.
-Reduce costs by using a thin layer rather than pure metal.
- Process
Anmerkungen:
- Object to be electroplated is made the negative electrode.
- Electrolyte
Anmerkungen:
- A solution containing ions of the plating metal.
- Electrodes
- Anode
Anmerkungen:
- -Made from the plating metal.
-Atoms of the plating metal lose electrons to form metal ions which go into the solution.
- Cathode
Anmerkungen:
- Metal ions from the solution gain electrons to form metal atoms which are deposited on the the object to be plated.