4287704
Description
Mind Map by jacob gray, updated more than 1 year ago
|
Created by jacob gray
over 8 years ago
|
|
Energy
- Enthalpy
- Enthalpy change of formation, ΔHF
Annotations:
- The enthalpy change that occurs when one mole of a compound is formed from its constituent elements in their standard states under standard conditions e.g. K(s) + 1/2Cl2(g) -> KCl(s)
- Usually exothermic for an ionic compound.
- Enthalpy change of atomisation, ΔHat
Annotations:
- The enthalpy change that takes place when one mole of gaseous atoms forms from the element in its standard state E.g. K(s) -> K(g) or 1/2Cl2(g) -> Cl(g)
- Always exothermic as a bond is being broken
- First ionisation energy, ΔHI
Annotations:
- The enthalpy change the accompanies the removal of one electron from each atom to form one mole of gaseous 1+ ions E.g. Ca(g) -> Ca+(g) + e^-
- Always endothermic as the electron being lost has to overcome attraction from the nucleus
- First electron affinity, ΔHEA
Annotations:
- The enthalpy change that accompanies the addition of an electron to one mole of gaseous atoms to form one mole of gaseous 1- ions E.g. Cl(g) + e^- -> Cl^-(g)
- Always exothermic as the electron is attracted into the outer shell of an atom by the nucleus
- Hess's law
Annotations:
- If a reaction can take place by more than one route and the initial and final conditions are the same, the total enthalpy change is the same for each route,
- Lattice enthalpy, ΔHLE
Annotations:
- The energy change that accompanies the formation of one mole of an ionic compound from its gaseous elements under standard conditions e.g. 2K^+(g) + S^2-(g) -> K2S(s)
- This is an exothermic change Indicates the strength of an ionic lattice, higher the lattice enthalpy the stronger the bond Covalent structures do not have a lattice enthalpy as their are no ions in the structure. Impossible to measure directly as you cant form one mole of a ionic lattice in gaseous form
- Enthalpy change of neutralisation, ΔHneut
Annotations:
- The energy change that accompanies the neutralisation of an aqueous acid by an aqueous base to form one mole of H2O(l) under standard conditions Ionic equation = HCl(aq) + NaOH(aq) -> NaCl(aq) + H2O(l)
- Enthalpy change of solution
Annotations:
- The enthalpy change that takes place when one mole of a compound is completely dissolved in water under standard conditions. E.g. KCl(s) +aq -> K^+(aq) + Cl^-(aq)
- Enthalpy change of hydration, ΔHhyd
Annotations:
- The enthalpy change that takes place when one mole of isolated gaseous ions is dissolved in water forming one mole of aqueous ions under standard conditions e.g. K+(g) + aq -> K+(aq)
- The effect of ionic charge and
radius on lattice enthalpy and
enthalpy change of hydration
- Lattice enthalpy
- Ionic radius
- As ionic radius increases, the attraction between the ions is
weaker and the lattice enthalpy becomes less exothermic
- The bonds are weaker and therefore the
boiling and melting points are lower
- The bonds are weaker and therefore the
boiling and melting points are lower
- For a smaller radius, there is greater
attraction from a larger charge density
- As ionic radius increases, the attraction between the ions is
weaker and the lattice enthalpy becomes less exothermic
- Ionic charge
- The stronger the charge, the more
exothermic the lattice enthalpy
- The stronger the charge, the more
exothermic the lattice enthalpy
- Ionic radius
- Enthalpy change of hydration
- Ionic radius
- As smaller molecules exert more
attraction on water molecules releasing
more energy, as the radius increases,
the reaction becomes less exothermic
- As smaller molecules exert more
attraction on water molecules releasing
more energy, as the radius increases,
the reaction becomes less exothermic
- Ionic charge
- As the charge increases, the radius decreases so the attraction
increases, making the enthalpy change more exothermic
- As the charge increases, the radius decreases so the attraction
increases, making the enthalpy change more exothermic
- Ionic radius
- Lattice enthalpy
- Enthalpy change of formation, ΔHF
- Born-Haber
- Entropy
- Entropy, S
Annotations:
- A quantitiative measure of disorder in a system
- As molecules are always moving, S is always positive
- Calculating the entropy
change of a reaction, ΔS
Annotations:
- ∑S(products) - ∑S(reactants)
- What can it can help us explain
- Gas expanding in a room
- How things dissolve
- Heat dispursing
- Heat dispursing
- How things dissolve
- Gas expanding in a room
- Changing entropy
Annotations:
- Entropy always increases when particles become more disordered
- The entropy of a pure substance increases with increasing temperature
- Changing state
- Solid/liquid
Annotations:
- Perfect crystals have 0K entropy. as they heat up and change to a liquid, entropy increases as the particles become more randomly placed.
- Liquid/gas
Annotations:
- When water evaporates, its entropy changes from 70 to 189
- Solid/liquid
- More moles of gas
Annotations:
- If a reaction has more moles of gas on one side than the other, the more moles of gas will have the highest entropy, shown by giving the reaction. e.g. 3O2-> 2O3 is a decrease in entropy
- Dissolving
Annotations:
- When something dissolves the entropy increases.
- Entropy, S
- Free energy
- Feasibility of reaction
Annotations:
- A reaction is feasible if ΔG has a negative value.
- Free energy change,
ΔG
Annotations:
- The balance between enthalpy, entropy and temperature for a process ΔG=ΔH-TΔS ΔH is the enthalpy change to the surroundings ΔS is the entropy change in the system T is the temperature in Kelvin (degrees C + 273)
- Feasibility of reaction
- Redox
- Cells and half cells
- Cell potentials
- Feasibility reactions
- Storage and fuel cells
- Acid hydrogen cell
- Alkaline hydrogen cell
- Cell potentials
- Hydrogen for fuel
Media attachments
Want to create your own Mind Maps for free with GoConqr? Learn more.