Chapter 23 - The Transition Metals

Description

A quiz based on the Transition Metal chemistry required for the new AQA A2 spec
Leah Firmstone
Quiz by Leah Firmstone, updated more than 1 year ago
Leah Firmstone
Created by Leah Firmstone almost 7 years ago
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Resource summary

Question 1

Question
Which of the following are typical properties of a Transition Metal element?
Answer
  • They are found in the d-block of the Periodic Table.
  • They are found to the right of the 'staircase' in the Periodic Table.
  • Each element can have a number of different oxidation states.
  • They form brightly coloured compounds.
  • They form mainly colourless or white compounds/solutions.
  • They only conduct electricity when molten or in solution.
  • They are able to form complex ions.
  • They can often be used as catalysts.

Question 2

Question
Which of the following is the correct electron configuration of Copper (Cu)?
Answer
  • [Ar] 3d10 4s1
  • [Ar] 3d9 4s2
  • [Ar] 3d8 4s3
  • [Ar] 4d9 4s2
  • [Ar] 4d10 4s1

Question 3

Question
When ions are formed from transition metal elements, the 4s electrons are lost first.
Answer
  • True
  • False

Question 4

Question
The formal definition of a transition element: An [blank_start]element[blank_end] which forms at least one [blank_start]stable[blank_end] ion with a [blank_start]partially-filled[blank_end] [blank_start]d-shell[blank_end] of electrons.
Answer
  • element
  • stable
  • partially-filled
  • d-shell

Question 5

Question
Scandium and Zinc are both d-block and transition metal elements
Answer
  • True
  • False

Question 6

Question
Match each definition to the correct term. Multiple labels may be required to complete each definition (some were too long).
Answer
  • An atom, ion or molecule that forms a
  • co-ordinate bond with a transition metal
  • ion using a lone pair of electrons.
  • Number of co-ordinate bonds to the TM
  • A TM ion surrounded by ligands.
  • A complex ion with polydentate ligands
  • A ligand which has multiple atoms with
  • lone pairs of electrons which bond to
  • the TM ion, e.g. EDTA

Question 7

Question
Only transition metals are able to form complexes.
Answer
  • True
  • False

Question 8

Question
How would you classify the following ligands?
Answer
  • monodentate
  • unidentate
  • hexadentate
  • bidentate

Question 9

Question
What is the shape of this complex ion?
Answer
  • octahedral
  • square planar
  • tetrahedral
  • linear

Question 10

Question
What is the shape of this complex ion?
Answer
  • octahedral
  • tetrahedral
  • square planar
  • linear

Question 11

Question
Complex ions with multidentate ligands are called [blank_start]chelates[blank_end]. Chelates can be used to effectively remove [blank_start]d-block[blank_end] metal ions from solution. If you add a hexadentate ligand such as [blank_start]EDTA[blank_end] to a solution of a transition metal salt, the EDTA will replace all six water [blank_start]ligands[blank_end] in the aqua ion, for example: [Cu(H2O)6](2+) + EDTA(4-) --> [CuEDTA](2-) + 6H2O In this equation, [blank_start]two[blank_end] species are replaced by [blank_start]seven[blank_end]. This increase in the number of particles causes a significant increase in [blank_start]entropy[blank_end] which drives the reaction to the right. for this reason chelate complexes with [blank_start]polydentate[blank_end] ligands are favoured over complexes with [blank_start]monodentate[blank_end] ligands. This is known as the chelate effect.
Answer
  • chelates
  • d-block
  • EDTA
  • ligands
  • two
  • seven
  • entropy
  • polydentate
  • monodentate

Question 12

Question
Optical isomerism occurs in transition metal complexes when there are two or more bidentate ligands.
Answer
  • True
  • False

Question 13

Question
Geometric isomerism occurs in transition metal complexes which are octahedral or tetrahedral in shape.
Answer
  • True
  • False

Question 14

Question
When the ligands bond with the transition metal ion, there is [blank_start]repulsion[blank_end] between the electrons in the ligands and the electrons in the d orbitals of the [blank_start]metal ion[blank_end]. That raises the energy of the d orbitals. However, because of the way the d orbitals are arranged [blank_start]in space[blank_end], it doesn't raise all their energies by the same amount. Instead, it splits them into [blank_start]two groups[blank_end], one group of 2 orbitals with a slightly [blank_start]higher[blank_end] energy level than the other 3. The size of the energy gap between them varies with the nature of the transition metal ion, its [blank_start]oxidation state[blank_end] (whether it is 3+ or 2+, for example), and the nature of the [blank_start]ligands[blank_end]. When [blank_start]white light[blank_end] is passed through a [blank_start]solution[blank_end] of this ion, some of the energy in the light is used to [blank_start]promote[blank_end] an electron from the lower set of orbitals into a space in the upper set. The amount of energy absorbed in order to promote this electron corresponds to a [blank_start]wavelength[blank_end] of the visible light. We therefore see a combination of the other colours in the spectrum, which often shows as the [blank_start]complementary[blank_end] colour of the one absorbed.
Answer
  • repulsion
  • metal ion
  • in space
  • two groups
  • higher
  • oxidation state
  • ligands
  • solution
  • promote
  • wavelength
  • white light
  • complementary

Question 15

Question
Why can transition metals form ions with variable oxidation states?
Answer
  • As they can use both their 4s and 3d electrons in bonding.
  • As they can form dative covalent (co-ordinate) bonds.
  • As their electrons are delocalised within the lattice structure.

Question 16

Question
Which two transition metals are found in the catalytic converters of modern cars?
Answer
  • Platinum
  • Rhodium
  • Iron
  • Nickel

Question 17

Question
A heterogenous catalyst is in the same phase as the reactants.
Answer
  • True
  • False

Question 18

Question
What can be done to minimise the costs of using heterogenous catalysts?
Answer
  • Increase the surface area - higher surface area = better efficiency.
  • Spread the catalyst onto an inert support medium, therefore increasing the surface-to-mass ratio so that a little goes a long way.
  • Use less catalyst but dot lumps of it across a surface.
  • Increase the concentration of the reactants.

Question 19

Question
Catalysts will eventually cease to work.
Answer
  • True
  • False

Question 20

Question
When the catalyst is in the same phase as the reactant, an intermediate species is formed.
Answer
  • True
  • False

Question 21

Question
What is autocatalysis?
Answer
  • When one of the products of the reaction catalyses the reaction.
  • When the reaction only begins on the addition of a catalyst.
  • When catalysts are used in cars.
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