Chapter 12: Alkanes (12.1-12.2) Flashcards
general formula of alkanes
CnH2n+2
alkanes are saturated hydrocarbons, what does this mean
alkanes have single bonds only
properties of sigma bonds
formed from the overlap of orbitals directly between the bonding atoms
can rotate freely
shape and bond angle of alkane
tetrahedral
109.5
boiling point trends in straight-chain alkanes
as the carbon chain length increases, the boiling point increases
more electrons and more points of contact between molecules means strength of London forces between molecules increases. More energy is needed to overcome these forces
boiling point trends in branched-chain alkanes
as branching in isomers increases, the boiling point decreases
fewer points of contact between molecules means strength of London forces decreases
less energy needed to break IMFs
solubility of alkanes
alkanes are non-polar molecules
not soluble in polar solvents (e.g. water). soluble in non-polar solvents (e.g. oil)
reactivity of alkanes
low reactivity
sigma bonds (C-C and C-H) are have high enthalpy (strong, hard to break)
C-C and C-H bonds are non-polar (making them less reactive)
what is a fuel
fuels are substances that can be burnt in oxygen to release heat energy
how does an alkane act as a fuel
although unreactive, many alkanes react exothermically with oxygen to make good fuels
alkane + oxygen –>
excess oxygen, complete combustion
CO2 (g) + H2O (l)
alkane + oxygen –>
excess alkane, incomplete combustion
CO (g) + H2O (l)
carbon only undergoes partial oxidation, unburnt carbon atoms can be released as carbon particles (soot)
dangers of carbon monoxide
toxic gas that binds with haemoglobin in red blood cells, preventing haemoglobin from carrying oxygen
difficult to detect: colourless and odourless
reactions of alkanes with halogens
alkane + halogen –> haloalkane + hydrogen-hailide
radical substitution, needs UV light to start
What time of fission is used in free radical substitution and what is needed?
UV radiation provides energy for homolytic fission
