Post on 24-Feb-2016
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Topic 13
Periodicity
HL
Ionic or covalent bonding?
Na+ Cl-H-ClCl-Cl
13.1 Trends across third period; Chlorides
• When you go the number of valence electrons increase => increase the number of valence electrons to form bonds.
• NaCl, MgCl2, AlCl3 (Al2Cl6(g)), SiCl4, PCl5 (PCl3 exist), (sulphur chlorides not required), (Cl2)
Chlorides of metals (NaCl, MgCl2, AlCl3 )
• Ionically bonded crystalline solids with high melting points.
• Dissolves in water without a chemical reaction to its ions:
NaCl (s) → Na+ (aq) + Cl- (aq)• Conduct electricity in melted or in aqueous
solution.
Chlorides of non-metals (SiCl4, PCl5 )
• Molecular covalent structure.
• Weak forces between molecules => low melting and boiling points.
• Don’t conduct electricity (no ions and no mobile charges).
Reacts with water: Hydrolysis
PCl3 + 3 H2O H3PO3 + 3 HCl Acidic solution
(Phosphoric(III) acid, oxyacid of the element)
H3PO3 + H2O H3O+ + H2PO3-
The oxyacid may also dissociate into acidic oxoniumions.
• In water the chlorides will conduct electricity; Cl- (aq).• Chlorine, Cl2, if seen as Chlorine chloride, behaves in the
same way:React with water in a hydrolysis reaction
Cl2 + H2O HCl + HClO
• Aluminium chloride reacts as a non-metal chloride due to small size and high charge. It’s very reactive with water:
AlCl3 + H2O Al2O3 + 6 HCl
Oxides- across period 3
Trend: From basic to acidic characterBase
AcidNa2O, MgO, Al2O3, SiO2, P4O10, SO3 (SO2), Cl2O7 (Cl2O, Cl2O3, Cl2O5)
Ionic Giant Covalent structure
Left side- oxides are basic
• Na2O + H2O 2 Na+ + 2 OH-
• Magnesium hydroxide only weakly dissociated because of low solubility.
• Reacts with acids (basic oxides):MgO(s) + 2 H+ Mg2+ + H2O
In the centre- oxides are amphoteric
• Both aluminium and silicon oxides are almost insoluble • Aluminium oxides have amphoteric properties; reacts with both base
and acidAl2O3(s) + 6 H+ 2 Al3+ + 3 H2OAl2O3(s) + 2 OH- + 3 H2O 2 Al(OH)4
-(aq)
• Silicon dioxide can show weakly acidic properties; reacts with strong
alkali to form silicates
• Giant covalent lattices with high melting and boiling points
To the right in period 3
• Molecular bonding: Gases, liquids or low melting points
• The elements can often form 2 or more oxides with different state of oxidation.
• Reacts with water to form acids.SO3(g) + H2O H2SO4
H2SO4 + H2O H+ + HSO4-
Cl2 + H2O H+ +Cl- + HClO
13.2 First row d-block elements (Sc Zn) The transition elements
• An element that contain an incomplete d level of electrons in one or more oxidation states
• d-orbitals starts to fill up with electrons• They have some common characteristics
(except Sc and Zn):
– A variety of stable oxidation states– The ability to form ions– Coloured ions– Catalytic activity
Oxidation states
• The 4s and 3d orbitals are quite close in energy• The electrons in 4s orbitals can easily be lost• Gives stable state to the right of the d-block. To
the left it’s a powerful reductant. (Ti2+ + water Hydrogen)
• Sc to Mn can loose all 4s and 3d electrons and stay stable. More to the right they become strong oxidants
• Highest oxidation state usually occur as oxanions: E.g. dichromate (Cr2O7
2-), permanganate (MnO4-)
Energy
4s
3d
Mn atom [Ar]4s23d5
4s lower than 3d
4s3d
Mn2+ ion [Ar] 3d5
4s higher than 3d
Common oxidation states of the d-block elements
Ti V Cr Mn Fe Co Ni Cu
+7 X
+6 X X
+5 X
+4 X X X
+3 X X X (x) X (x)
+2 (x) X X X X X X X
+1 X
• All transition elements can show an oxidation number of +2
• You should be familiar withCr (+3, +6), Mn (+4, +7)Cu (+1,+2)
In solution: Ligand
• Ions of d-block elements have unfilled orbital's. These unfilled orbital's can attract a pair of electrons from an other compound = ligand.
• The ligand must have free (non-bonding) electron pair that they can donate to the ion.
• E.g. H2O, NH3, Cl-, CN-
In solution: Complex ion
• The ion and the ligand form a dative bond, co-ordinate bond(covalent) bond
• The Ion + ligands = complex ion
Examples of complex ions• Most complex ions have either six ligands arranged octahedrally around the
central ion (often water or ammonia ligands) or four ligands arranged tetrahedrally (often chloride ligands)
• [Cu(NH3)4]2+ (forms when an excess of ammonia is added to Cu(II)-salt)
• [Ag(NH3)2]+
• [Fe(H2O)6]3+
• [Fe(CN)6]3-
• [CuCl4]2-
• Complex formation can stabilise certain oxidation states and affect the solubility of the ion
Complexes have often specific colours
• In an isolated atom all d-orbital’s have the same energy.
• The Ligands in a complex ion affect the energy in the d-orbital’s.
• The orbitals split up to two groups with different energy. The energy gap is in the visible region.
• When light going through a transition metal solution energy is absorb when electrons are lifted from the lower level to the higher.
http://www.chemguide.co.uk/inorganic/complexions/colour.html
• White light (all colours) hits Copper(II) salt and red and yellow light absorbs => blue-green colour.
• Sc3+ and Ti4+ : no electrons in d-orbitals => colourless
• Zn2+ : filled d-orbital => colourless
Catalytic activity
• Catalyst is a substance that speeds up a reaction without being consumed by it self. Reduce the activation energy.
• Transition metals often have catalytic behaviour due to:– Ability to form complexes. Close contact.– Many oxidation states. Easy to lose or gain
electrons in redox reactions.
Homogeneous catalyst
• In the same phase as the reactants• E.g. dissolved ion in water solution
Heterogeneous catalyst• On the surface of the metal.E.g.• MnO2, Manganese(IV)oxide: 2 H2O2 2 H2O + O2
• Ni: Alkenes + hydrogen Alkanes
• Fe: Haber process, N2 + 3 H2 2 NH3
The worldwide ammonia production in 2004 was 109 million metric tonnes.[
• V2O5, vanadium(V)oxide: in the Contact process (manufacture sulphuric acid) 2 SO2(g) + O2(g) 2 SO3(g)SO3 + H2O H2SO4
Sulphuric acid. 165 million tonnes, with an approximate value of US$8 billion. Principal uses include ore processing, fertilizer manufacturing, oil refining, wastewater processing, and chemical synthesis.
• Co in vitamin B12
• Pd and Pd in catalytic converters