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Exp. 38 Transition Metal Chemistry p. 423

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Exp. 38 Transition Metal Chemistry p. 423. To observe the various colors ... The reds, blues, and greens that we. associate with some chemicals are ... – PowerPoint PPT presentation

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Title: Exp. 38 Transition Metal Chemistry p. 423


1
Exp. 38 Transition Metal Chemistry
p. 423
  • To observe the various colors associated with
    transition metal ions.
  • To determine the relative strength of a ligand.
  • To compare the stability of complexes
  • To synthesize a coordination compound.

2
Exp. 38 Introduction
  • The reds, blues, and greens that we
  • associate with some chemicals are
  • often due to transition metal ions.
  • Transition metals are from
  • Scandium to Copper.
  • Color changes can occur when
  • molecules or ions bond to the
  • metal ion to form a complex

3
Exp. 38 Introduction
  • These molecules or ions are called ligands
  • and are Lewis bases (electron pair donors)
  • which bond directly to the metal ion,
  • producing a change in the electronic
  • energy levels of the metal ion. As a result,
  • the energy and wavelength of light
  • absorbed and transmitted by the electrons
  • in the metal change. The solution has a
  • new color.

4
Exp. 38 Introduction
  • The complex has a number of ligands bonded
  • to the transition metal ion which form a
  • coordination sphere. The complex, along
  • with its neutralizing ion is called a
  • coordination compound.
  • Ex Fe(CN)64- - complex
  • 6 CN- ions ligands
  • Fe(CN)6 coordination sphere
  • K4Fe(CN)6 coordination compound

5
Exp. 38 Introduction
  • Colors are nice, but there are also practical
  • uses for transition metal complexes
  • The removal of the calcium in water that causes
    hardness is accomplished by adding a
    polyphosphate to form a soluble calcium complex
  • Ca2(aq) P3O105-(aq) ? CaP3O103-(aq)
  • A treatment for ingested Pb or Hg is to swallow
    mercaptol, C3H8OS2, which forms a complex with
    the Hg or Pb
  • Hg2(aq) 2C3H8OS2(aq) ? Hg(C3H8OS2)22(aq)

6
Exp. 38 Introduction
  • Monodentate a single ligand forms one
  • bond to the metal ion.
  • Bidentate a single ligand forms two bonds
  • to the metal ion.
  • Chelating agents ligands that form 2 or
  • more bonds to a transition metal ion
  • (polydentate ligand).
  • The complex formed between a chelating
  • agent and a metal ion is generally more
  • stable that that formed by a monodentate
  • and a metal ion.

7
Exp. 38 Introduction
  • Coordination number the number of bonds
  • between a metal ion and its ligands, or, the
  • number of positions available for bonding.
  • Ex 4 monodentate coord. no. 4
  • 2 bidentate coord. no. 4
  • 6 H2O, 6 CN- or 3 bidentate 6
  • Coordination numbers 2, 4, 6 are the most
  • common.

8
Exp. 38 Introduction
  • The stability of a complex can be determined
  • by mixing it with an anion known to form a
  • precipitate with the cation. The anion most
  • commonly used is OH-.
  • Ex Cu2 4X- ? CuX42-
  • If OH- is added to this equilibrium, the Cu2
  • now has to choose which anion it will
  • combine with. If ligand X- forms the stronger
  • bond, the copper remains in solution and no
  • change is observed. If OH- forms a stronger
  • bond to Cu2, Cu(OH)2 precipitates.

9
Exp. 38 Procedure Notes
  • For the purpose of this experiment,
  • the coordination number of Cu2 is
  • always 4 and Ni2 and Co2 are always 6.
  • F. Do first. You will be using both a Bunsen
    burner and 95 ethanol be aware!
  • A.1. Caution! You will be using conc. HCl
  • in this step.
  • B.1. Caution! You will be using conc. NH3.
  • Use the hood.
  • D., E., G. omit

10
Exp. 38 Report Sheet
  • Question 4
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