Chemistry Unit 1 AOS 1

PT Trends

Intermolecular

Intramolecular

Chance 1

Chance 2

100

Tells you the number of valence electrons

Groups

100

List the three different intermolecular forces.

Dispersion, dipole-dipole, hydrogen bonding

100

List the three intramolecular bonds.

Covalent, ionic and metallic.

100

VSEPR stands for ________.

Valence Shell Electron Pair Repulsion

100

Salt and hydrogen gas are the products.

Metals + acid

200

Increases as you go up a group and right across a period. Top right hand corner is the most ________.

Electronegativity (and ionisation energy)

200

Explain the differences between the three intermolecular forces.

Dispersion forces: exists everywhere

Dipole-dipole: is polar

Hydrogen bonds: is polar and is the strongest. Occurs between H-FON

200

Malleability and ductility

Metallic Bonding: Delocalised sea of electrons allow for charged particles (electrons) to move freely along oppositely charged ions without breaking/shattering.

200

Symmetrical and asymmetrical

Determines polarity.

Symmetrical = non-polar (even distribution of charges)

Asymmetrical = polar (uneven distribution of charges)

200

Metal hydroxides and hydrogen gas are produced. Metal hydroxides provide a pink colour when phenolphthalein is added to the solvent.

Metals + water

300

Increases down a group and to the left across a period. Bottom left hand corner has the strongest ________.

Metallic character/reactivity

300

Propan-1-ol has a higher boiling and melting point than propane.

They both have 3 carbons. Propan-1-ol has a -OH group present. The -OH is a polar covalent bond and hydrogen bonds are present.

Propane is a non-polar covalent bond and only dispersion forces are present.

300

Delocalised sea of electrons or charged particles can flow from a positive end to a negative end to produce current.

Electrical conductivity.

Covalent (none)

Ionic (molten/liquid state)

Metallic (always)

300

Why does methane (CH₄) have a lower melting and boiling point compared to ethane (C₂H₆)?

Only dispersion forces present in both. Ethane is a larger molecule, therefore more energy will be required to break ethane apart. Hence, methane has a lower melting and boiling point compared to ethane.

300

Shape and polarity of ethanol (C₂H₅OH)

Tetrahedral (4 bonded pairs around our C)

400

Stays the same as you go down a group. Increases as you move across a period towards the right.

Core charge

400

Same molecule of similar mass and size. Molecule 1 is made up of -OH, and Molecule 2 contains a C=O group attached. Explain which molecule will have a higher boiling point.

Molecule 1: Hydrogen bonds (H-FON). Strongest intermolecular force.

Molecule 2: Dipole-dipole forces. Stronger than dispersion forces, but weaker than hydrogen bonds.

Molecule 1 has a stronger intermolecular force and will require more energy to break these bonds. Therefore, Molecule 1 will have a higher boiling point.

400

Hard and brittle

Ionic compounds.

Hard: strong electrostatic forces between oppositely charged ions. Strong force is required to disrupt the lattice.

Brittle: like-charged ions (eg. + and +) repel against each other.

400

Linear, bent, tetrahedral, trigonal planar, trigonal pyramidal

VSEPR theory - uses lone pairs (or unbonded pairs) of electrons to determine the shape of molecules.

400

Two reactants are mixed together to form two new products (ie. The cations have swapped anions to form new products).

Double displacement reactions

500

Elements such as chromium and copper have special electron configuration - they like to have half-filled subshells. Explain this property with reference to a PT trend.

Half-filled = stable.

Stable = high ionisation energies.

Noble gases are very stable (octet rule) so they have very high ionisation energies compared to the elements before them.

500

Butan-1-ol (4 carbons) has a -OH group and its melting point is -89.8 °C. Decane (10 carbons) only has C's and H's but its melting point is 174.1°C. Why?

Larger molecule = more dispersion forces. Even though butan-1-ol has a -OH group with hydrogen bonds present, decane is a much larger molecule and has a stronger force overall. Hence, decane (despite only have dispersion forces), will have a higher melting point than butan-1-ol.

500

Does not conduct electricity. Is often not soluble in water and has low melting and boiling points. Describe the bond and why this bond exists.

Covalent bonding. Neither atoms are stable by themselves so they compensate with each other by obeying the octet rule. Covalent bonds are formed via sharing electrons.

500

A customer hypothesises that by heating up food containing salt at a moderate temperature, the salt will degrade and thus not have the same health consequences. Comment on the customer’s hypothesis, referring to the properties of ionic compounds.

The customer’s hypothesis is likely incorrect.

This is because ionic compounds are usually highly heat resistant and have a high melting point because of the strength of the ionic bonds.

Therefore, exposing food to moderate heat would be insufficient to degrade the molecule, and it would therefore still have the same health effects.

500

List the properties of use from these ionic compounds.

a) Lining surface of engines: Magnesium oxide (MgO)

b) Human bones and teeth: Calcium phosphate (Ca₃(PO₄)₂)

c) Electrolyte enabling current flow in cell batteries: Ammonium chloride (NH₄Cl)

a) High melting point

b) Hardness

c) Electrical conductivity