Zusammenfassung der Ressource
Collision Theory and Energy Transfer
- Reaction rates are explained by collision theory. The rate of
reaction depends on how often and how hard the reacting
particles collide with each other. In order to react they have to
collide hard enough (with enough energy)
- More collisions increase the rate of reaction
- The effects of temperature concentration and
surface area on the rate of reaction can be
explained in terms of how often the reacting
particles collide successfully
- Higher temperature increases collisions
- When the temperature is increased the particles all move quicker. If there moving quicker they are going to collide more often
- Higher concentration (or pressure) increases collisions
- If a solution is made more concentrated it means there are more
particles of reactant knocking about between the water molecules
which makes collisions between the important particles more likely. In
a gas increasing the pressure means the particles are more
squashed up together so there will be more frequent collisions
- Larger surface area
- If one of the reactants is a solid then breaking it up into smaller
pieces will increase the total surface area. This means the particles
around it in the solution will have more area to work on so theyll be
more frequent collisions
- Collision theory and catalysts
- Increasing the temperature causes faster reactions
- Reactions only happen if the particles collide with enough energy.
- The minimum amount of energy needed by the particles to react is known as the activation energy.
- At a higher temperature there will be more particles colliding with enough energy to make the reaction
- Catalysts speed up reactions
- A catalyst is a substance which speeds up a
reaction without being changed or used up
- A solid catalyst works by giving the reacting
particles a surface to stick to. This increases
the number of successful collisions and so
speed the reaction up
- Catalysts help reduce cost in industrial reactions
- The plant doesnt need to operate for as long to produce the same amount of stuff
- Allows the reaction to operate at a much lower
temperature this reduces the energy used up in the
reaction (energy cost) which is good for sustainable
development
- Disadvantages
- Very expensive to buy.
- Different reactions use different catalysts so if you make more
than one product at your plant youll probably need to buy
different catalysts
- Catalysts can be poisoned by impurities so
they stop working. This means you have to
keep the reaction very clean
- Energy transfer in reactions
- Whenever chemical
reactions occur energy is
transferred to or from the
surroundings
- In an exothermic reaction heat is given off
- An exothermic reaction is one which
transfers energy to the surroundings usually
in the form of heat and usually shown by a
rise in temperature
- e.g. Combustion gives of a lot of heat
- Neutralisation reactions (acid + alkali) are also exothermic
- Many oxidation reactions are exothermic
- Have lots of everyday uses. E.g. Hand warmers
use the exothermic oxidation of iron in air to
generate heat.
- In an endothermic reaction heat is taken in
- An endothermic reaction is one which takes in
energy from the surroundings usually in the form
of heat and is usually shown by a fall in
temperature
- Less common
- Thermal decomposition
- Heat must be supplied to make calcium carbonate decompose to make quicklime CaCO3 to CaO + CO2
- Everyday uses include some sports
injury packs use endothermic reactions
they take heat in and the pack becomes
very cold
- Reversible Reactions can be endothermic and exothermic
- In reversible reactions if the reaction is
endothermic in one direction it will be
exothermic in one direction, it will be
exothermic in the other direction. The energy
absorbed by the endothermic reaction is equal
to the energy released during the exothermic
reaction. A good example is the thermal
decomposition of hydrated copper sulfate