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Transition metals Transition Metals Coloured Compounds Diagram 1 Absorption of light energy Diagram 2 Example: a blue coloured compound arises because:

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Presentation on theme: "Transition metals Transition Metals Coloured Compounds Diagram 1 Absorption of light energy Diagram 2 Example: a blue coloured compound arises because:"— Presentation transcript:

1 Transition metals Transition Metals Coloured Compounds Diagram 1 Absorption of light energy Diagram 2 Example: a blue coloured compound arises because: Experiment – Chromium Experiment – Manganese Experiment – Manganese ctd Experiment – Iron Experiment – Copper Experiment – Vanadium (DEMO) Transition metal colours

2 from Sc to Zn electrons are filling the 3d orbitals (4s filled already except Cr and Cu) from Sc to Zn electrons are filling the 3d orbitals (4s filled already except Cr and Cu) A transition element has AT LEAST ONE ION with a PARTIALLY FILLED d-SHELL (so Sc, Sc 3+ and Zn aren’t – no ion with partially filled d-shell) A transition element has AT LEAST ONE ION with a PARTIALLY FILLED d-SHELL (so Sc, Sc 3+ and Zn aren’t – no ion with partially filled d-shell) Transition Metals Start

3 All 5 d-orbitals in an isolated transition element have the same energy. When ligands bond to the central ion, the d-orbitals move up to two different energy levels. The gap between the energy levels depends upon – the ligand, the coordination number and the transition metal ion. All 5 d-orbitals in an isolated transition element have the same energy. When ligands bond to the central ion, the d-orbitals move up to two different energy levels. The gap between the energy levels depends upon – the ligand, the coordination number and the transition metal ion. Coloured Compounds Start

4 Diagram 1 Energy gap,  E 3d orbitals in a Cu 2+ ion Ligands split the 3d energy level Start

5 Absorption of light energy An electron can be promoted from the lower 3d energy level by absorbing energy EXACTLY equal to the energy gap. This energy is provided by radiation from the visible and UV regions of the spectrum. An electron can be promoted from the lower 3d energy level by absorbing energy EXACTLY equal to the energy gap. This energy is provided by radiation from the visible and UV regions of the spectrum. Start

6 Diagram 2 Absorption of light energy Promotion of electron to higher energy level Cu(H 2 O) 6 2+ in an excited state Start

7 Example: a blue coloured compound arises because: absorption of light energy in the red, yellow, and green regions of the spectrum. This absorbed radiation provides the energy for an electron to be excited to a higher energy level absorption of light energy in the red, yellow, and green regions of the spectrum. This absorbed radiation provides the energy for an electron to be excited to a higher energy level reflection of blue light only reflection of blue light only The colour of a transition metal complex ion results from the transfer of an electron between the orbitals of an unfilled d sub- shell The colour of a transition metal complex ion results from the transfer of an electron between the orbitals of an unfilled d sub- shell Start

8 Transition metal colours Zn(II) (ZnSO 4 ) colourless Zn(II) (ZnSO 4 ) colourless Cu(I) (Cu 2 O) brick red, Cu(II) blue (with some black compounds), CuI white. Cu(I) (Cu 2 O) brick red, Cu(II) blue (with some black compounds), CuI white. Mn(VII) (MnO 4 - ) purple, Mn (VI) (MnO 4 2- ) green, Mn(IV) (MnO 2 ) brown, Mn(II) (Mn 2+ ) colourless/pale pink Mn(VII) (MnO 4 - ) purple, Mn (VI) (MnO 4 2- ) green, Mn(IV) (MnO 2 ) brown, Mn(II) (Mn 2+ ) colourless/pale pink V(V) (VO 2 + )orange, V(IV) (VO 2+ ) blue, V(III) (V 3+ ) (green) V(II) (V 2+ ) violet V(V) (VO 2 + )orange, V(IV) (VO 2+ ) blue, V(III) (V 3+ ) (green) V(II) (V 2+ ) violet Fe(II) pale green, Fe(III) orange Fe(II) pale green, Fe(III) orange Start

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