EL

Question 1

What is nuclear fission?

Answer 1

The splitting of a large, unstable isotope triggered by bombarding it with smaller, high-speed particles (usually neutrons)

Question 2

What conditions are needed for nuclear fusion?

Why?

Answer 2

High temps and pressure to provide the energy needed to overcome the repulsion between the 2 positive nuclei

Question 3

What is the nuclear symbol for a neutron?

Answer 3

10n with the 0 below the 1

Question 4

Define nuclear fusion.

Answer 4

The process by which, under high temperature and pressure, lighter nuclei fuse, forming a heavier nucleus of a new element.

Question 5

Flame test colour of Ba2+

Answer 5

Apple green

Question 6

Flame test colour of Ca2+

Answer 6

Brick red

Question 7

Flame test colour of Cu2+

Answer 7

Green with blue streaks.

Question 8

Flame test colour of Li+

Answer 8

Crimson

Question 9

Flame test colour of K+

Answer 9

Lilac

Question 10

Flame test colour of Na+

Answer 10

Yellow

Question 11

State the major trend in first ionisation energies/ enthalpies across a period.

Answer 11

-Ionisation enthalpy increases across period
-All elements have electrons in the same number of shells/ energy levels.
-But there are more protons across the period.
-So attraction is greater and therefore more energy required to remove outer electron.

Question 12

State the major trend in first ionisation energies going down the groups.

Answer 12

-Going down a group the first ionisation energy decreases.
-A shell is added for each element going down the group.
-so outer electrons experience less nuclear attraction as there is more e- shielding.
-so outer electron is easier to remove, requiring less energy.

Question 13

State the major trend in reactivity going down a group.

Answer 13

-Going down a group the reactivity increases.
-A shell is added for each element going down the group.
-so outer electrons experience less nuclear attraction as there is more e- shielding.
-so outer electron is easier to remove, requiring less energy.

Question 14

State the group 1 and 2 trends.

Answer 14

-Elements become more metallic down the group. The most reactive elements are found at the bottom of each group.
-Elements become less metallic across a period from left to right. Group 1 metals are more reactive than group 2 metals in the same period.

Question 15

Give the three factors affecting ionisation enthalpies.

Answer 15

1. Atomic radius
2. Nuclear charge
3. Electron shielding

Question 16

Explain why each successive ionisation enthalpy is larger than the one before.

Answer 16

-As each electron is removed, there is less repulsion between the electrons and each shell will be drawn closer to the nucleus.
-As the distance of each electron from the nucleus decreases, nuclear attraction increases.
-More energy is needed to remove each successive electron.

Question 17

Explain the solubility of group 2 hydroxides.

Answer 17

Solubility in water increases down the group with more alkaline solutions produced because as you go down the group, the size of the metal ion increases.
This decreases attraction between the metal cation and OH- anion in hydroxide.
Makes it easier for water molecules to break up the lattice so enthalpy of hydration is greater than lattice enthalpy.
Therefore more of solid will dissolve.
So resulting solutions are more alkaline the further down the group.

Question 18

Give 3 group 2 trends.

Answer 18

1. Reactivity increases down group 2.
2. Carbonates decompose at higher temperatures down the group (become more thermally stable).
3. Hydroxides are more soluble down the group, and more alkaline in solution.

Question 19

What is meant by thermal decomposition?

Answer 19

The breaking up of a chemical substance with heat into at least two chemical substances.

Question 20

Explain the trend in thermal stability of the group 2 carbonates going down the group?

Answer 20

The thermal stability increases as you go down Group 2. This is because the Group 2 ion has lower charge density, and thus distorts the carbonate ion less. The less distorted the carbonate ion is, the more stable it is, and so a higher temperature is required to decompose the carbonate.

Question 21

What is the atomic number?

Answer 21

The number of protons in the nucleus of an atom.

Question 22

What is the mass number?

Answer 22

The total number of protons and nuetrons in the nucleus of an atom.

Question 23

What is relative atomic mass (Ar)?

Answer 23

The mass of one atom of an element relative to 1/12 the mass of carbon-12

Is an average of relative isotopic masses, taking into account abundance

Question 24

What is an isotope?

Answer 24

Atoms of the same element with same no. of protons and a different no. of neutrons.

Question 25

What is relative isotopic mass?

Answer 25

Mass of the isotope compared to 1/12th the mass of a carbon-12 atom.

Question 26

What is relative formula mass?

Answer 26

The mass of a molecule or a formula unit relative to the mass of a carbon-12 atom.

Question 27

What is relative molecular mass Mr?

Answer 27

The average mass of a molecule relative to 1/12th the mass of a carbon-12 atom.

Question 28

What is the Avogadro constant (NA)?

Answer 28

The number of atoms/molecules in 1 mole of a substance

Question 29

What does quantised mean?

Answer 29

Energy that can only take particular values (known as quanta)

Question 30

What is the ground state?

Answer 30

The lowest energy level that an electron can occupy

Question 31

What is a photon?

Answer 31

Quanta of energy in the form of electromagnetic radiation

Question 32

What properties does light have the mean it can be described as a particle?

Answer 32

Made up of ‘tiny packets of energy’ called photons

The energy of a photon corresponds to its position in the EM spectrum

Increased freq. = increased energy + decreased wavelength

Question 33

What equation links the wave + particle models of light?

Answer 33

ΔE = hv

Question 34

What equation expalins the wave properties of light?

Answer 34

c = vλ

Question 35

Describe the appearance of an emission spectrum.

Answer 35

Consists of coloured lines on a black background

The lines become closer at higher frequencies

There are several series of lines (although some may fall outside visible part of spectrum)

Question 36

What is spectroscopy?

Answer 36

The study of how light and matter interact

Uses IR, visible, and UV light

Question 37

Explain the formation of an emission spectrum.

Answer 37

Electrons in the ground state absorb energy
This promotes them to a higher energy level - excited state
Electrons then drop back down to lower energy levels. The energy lost (ΔE) us emitted as a photon of light
The frequency of the photon is related to the energy lost by ΔE = hv
Different energy gaps produce photons of different frequencies
This produces different coloured bands on the emission spectrum

Question 38

Why can emission/absorption spectra be used to identify different atoms from a compound/mixture?

Answer 38

Because each element has a unique configuration of electrons, therefore has a unqiue emission/absorption spectrum

The energy levels of the electrons are discrete + quantised means only certain freqs. emitted/absorbed - it’s not continuous.

Question 39

What are flame tests?

Answer 39

Used to identify the presence of specific metals in a sample

Different metals give different coloured flames depending on their emission spectra

Question 40

What is flame colour?

Answer 40

The light emitted by metal ions when a vaporised metal salt is heated up in a flame

Question 41

Describe the appearance of an absorption spectrum.

Answer 41

If white light is passed through a sample of vaporised atoms, an absorption spectrum is seen

Shown by black lines on a rainbow background (showing all colours of visible light)

Question 42

How are atomic absorption spectra formed?

Answer 42

Electrons in the ground state absorb photons of light
The energy from these photons causes the electrons to be excited to higher energy levels
The electrons drop back down to the ground state and a photon/light is emitted
The energy of this photon is related to the frequency/energy of light initally absorbed as ΔE = hv
Light of the frequency doesn’t pass through the sample (as it’s absorbed) so a black line is seen in the spectrum

Question 43

What are the similarities between emission and absorption spectra?

Answer 43

For a given element, lines appear at the same frequency

Lines converge at a higher frequency

Several series of lines are seen

Question 44

What are the differences between atomic emission and absorption spectra?

Answer 44

Emission spectra show coloured lines on a black background

Absorption spectra show black lines on a coloured background

Question 45

Why do the lines of emission/absorption spectra get closer together at higher frequencies?

Answer 45

These are produced from translations from higher energy levels

Higher energy levels are much closer together than lower energy levels

Translations from adjacent energy levels will have similar ΔE values and hence produce light of similar frequencies

Question 46

Why are several series of lines seen on emission/absorption spectra?

Answer 46

Lines are produced when electrons drop to a lower energy level

Different series of lines are produced by electrons dropping to different ground states/electron energy levels

Question 47

What is the principle quantum number?

Answer 47

Shell

Given as n (i.e. 1,2,3 etc. the number before the letter…)

The higher the value, the higher the energy

Question 48

What is each sub-shell divided into?

What are its properties?

Answer 48

Atomic orbitals

Each can hold max of 2 electrons

These electrons must have opopsite (or paired) spins

Represented by boxes. Arrows drawn in them represent electrons

Question 49

How many orbitals does the s sub-shell contain?

Answer 49

1 s-orbital

Question 50

How many orbitals does the p sub-shell have?

Answer 50

3

Question 51

How many orbitals does the d sub-shell have?

Answer 51

5

Question 52

How many orbitals does the f sub-shell have?

Answer 52

7

Question 53

What are the rules that determine the distribution of electrons in atomic orbitals?

Answer 53

The orbitals are filled in order of increasing energy

Where there is more than one orbital at the same energy, the orbitals are first occupied by a single electron. When each orbital is singly occupied, the electrons pair up in the orbitals

Electrons in singly occupied orbitals have parallel spins

Electrons in doubly occupied orbitals have opposite (paired) spins

Question 54

How are elements in the periodic table arranged?

How did they used to be arranged?

Answer 54

Arranged by atomic number (no. protons)

Used to be arranged by Ar

Question 55

What trend do melting/boiling points follow across a period?

(e.g. period 3)

Answer 55

Melting point increases then decreases across the period
This is because the metals on the left-hand side of a period are metalically bonded so have higher melting points due to the delocalised electrons between nuclei. The further across the period, the more electrons and the more positive the nucleus becomes, so the stronger the bonds.
Silicone has a high melting point because it is a giant covalent structure which requires a lot of energy to break
The remaining non-metals are simple molecules. They are only held together by weak intermolecular forces (e.g. id-id). To melt these molecule you don’t need to break the strong covalent bonds, only the weak intermolecular bonds.

Question 56

What is first ionisation enthalpy?

Answer 56

The energy needed to remove one electron from each atom in one mole of isolated gaseous atoms of an element

Question 57

What is the general equation for first ionisation enthalpy?

Answer 57

X(g) → X+(g) + e-

Question 58

What is the trend for atomic radii across a period?

Answer 58

Decreases due to the increased number of protons

This means there is greater attraction between the outer electrons and the nucleus

Question 59

Why are s-block elements more reactive than p-block elements?

Answer 59

Because the formation of M+ or M2+ ions only requires input of energy equivalent to the first/second ionisation enthalpy.

For p-block elements greater input of energy is needed to lose eletrons due to the greater electron affinity as a result of a more positive nucleus

Question 60

What is a dative covalent bond?

Answer 60

A type of covalent bond in which both electrons come from the same atom

Show by arrow pointing away from donor

Question 61

What is a lone pair?

Answer 61

A pair of electrons in the outer shell of an atom that are not involved in bonding

Question 62

What is ionic bonding?

Answer 62

Bond formed between metal + non-metal atom

Metal transfers/donates electron(s) to non-metal atom

This results in formation of charged ions, often with full outer shells. This makes them particularly stable

Question 63

How are individual ions held together to form ionic compounds?

Answer 63

Cations + anions produced by ionic bonding held together by electrostatic attraction between each other

Results in the formation of a giant ionic lattice

Question 64

What is covalent bonding?

Answer 64

Bonding that occurs between 2 non-metal atoms

Formed by the atoms sharing one or more pairs of electrons

(If 2 pairs shared, double bond formed, etc.)

Question 65

What is electron pair repulsion theory?

(AKA VSEPR - Valance Shell Electron Pair Repulsion)

Answer 65

States that the shape adopted by a simple molecule is that which keeps repulsive forces to a minimum.

All bond angles must add up to = 360º

Question 66

Describe/explain how electron pair repulsion determines the shape of molecules

Answer 66

• Electrons will arrange themselves to get as far apart as possible
• State the no. total pairs of electron
• State the no. bonding pairs/groups of electrons
• (if applicable) state the no. lone pairs
• (if applicable) lone pairs repel more than bonding pairs (decrease bond angle by 2.5º each)
• This creates the shape […] with the angle(s) […]

Question 67

How do double/triple bonds affect the number of bonding electrons?

Answer 67

Can be thought of as a single group of electrons

e.g. CO2 has double 2 double bonds (4 electron pairs in total) which can be thought of as 2 electron groups

Question 68

Describe the structure of a giant ionic lattice.

Answer 68

Has a regular repeating pattern of postivitely and negatively charged ions in all 3 dimensions

The attraction between these oppositely charged ions outweighs the repulsion between ions with the same charge because the oppositely charged ions are closer

Question 69

What are the characteristic properties of giant ionic lattices?

Answer 69

High melting point because of strong electrostatic attractions between ions

Often soluble in water (due to charges of ions)

Conduct electricity when molten/in solution as charged ions able to move freely.

Question 70

Describe the structure/bonding in simple molecular covalent bonding

Answer 70

Strong covalent bonds within molecules (between atoms) (strong intramolecular bonds)

But only weak intermolecular bonds between molecules

Question 71

What are the characteristic properties of simple covalent molecules?

Answer 71

Low melting point

Usually insoluble in water

Do not conduct electricity (or heat)

Question 72

What are the characteristic properties of giant covalent networks?

Answer 72

High melting point because all bonds in structure are strong covalent bonds

Insoluble in water

Do not conduct electricity (apart from graphite)

Question 73

What are the characteristic properties of giant metallic lattices?

Answer 73

High melting point because there is strong electrostatic attraction between ions + electrons

Insoluble in water

Conduct electricity when solid/molten because delocalised electrons are free to move

Question 74

What are delocalised electrons?

Answer 74

Electrons that are not associated with a particular atom

Instead are free to move over several atoms

Question 75

What is electron affinity?

Answer 75

Energy change when 1mol gaseous atoms aquires 1mol electrons from 1mol gasous anions

Question 76

What is a complex ion?

Answer 76

Ion containing more than 1 atom

Charge is spread across whole ion

Contains covalent bonds

Question 77

What is a precipitate?

Answer 77

A suspension of solid particles fromed by a chemical reaction in solution

Question 78

What is a precipitation reaction?

Answer 78

Reaction between ions in solution that forms a precipitate

Question 79

What happens when ionic substances dissolve into solution/water?

Answer 79

The ions become surrounded by water + spread throughout the solution

They behave independantly of each other

Question 80

Which ionic substances are soluble?

Answer 80

All compounds containing…

Group 1 metals

Nitrate ions

Ammonium ions

… are soluble

Question 81

Which ionic substances are insoluble?

Answer 81

Sulfates of Ba, Ca, Pb, and Ag

Halides of Ag + Pb

All carbonates except those of Group 1/ammonium ions

Hydroxides containing some Group 2, Al, or d-block ions

Question 82

The presence of which ions can be tested for by adding barium chloride solution?

(Solution containing Ba2+ ions)

Answer 82

Sulfate (SO42-) ions - white ppt formed

Question 83

The presence of which ions can be tested for by adding silver nitrate solution (containing Ag+ ions)?

Answer 83

Shows presence of halide ions

White ppt forms for Cl-
Cream ppt forms for Br-
Yello ppt forms for I-

Question 84

What are the 4 ways/reactions that can be used to make an ionic salt?

Answer 84

Acid + base/alkali → Salt + Water

Acid + Carbonate → Salt + Water + CO2

Acid + Metal → Salt + Hydrogen

Question 85

Give three examples of practical applications of precipitation reaction.

Answer 85

Water treatment

Production of coloured pigments for paints/dyes

Identification of certain metal ions in solutions

Question 86

What is empirical formula?

Answer 86

The simplest whole number ratio of atoms in a compound.

Question 87

What is water of crystallisation?

Answer 87

Number of water molecules contained in an ionic lattice per molecule of salt

(i.e. how hydrated the salt is)

Question 88

Why might percentage yield be lower than expected?

Answer 88

Loss of product from reaction vessels (when transfering)

Side reactions (may create by-products)

Impurities in reactants

Changes in temp + pressure (may effect equilibrium)

If the reaction is an equilibrium system

Question 89

How do group 2 metals react with water?

Answer 89

Group 2 metal + Water → Metal hydroxide + Hydrogen

M(s) + 2H2O(l) → M(OH)2(s) + H2(g)

Question 90

How do Group 2 metals react with oxygen (when heated)?

Answer 90

Metal + Oxygen → Metal oxide

2M(s) + O2(g) → 2MO(s)

Question 91

What substances do Group 2 metal oxides react with?

What property does this give them?

Answer 91

They react with acids, so can act as bases

Metal oxide + Acid → Salt + Water

MO(s) + H2SO4(aq) → MSO4(aq) + H2O(l)

Question 92

How do metal hydroxides react with acids?

Answer 92

Metal hydroxide + Acid → Salt + Water

M(OH)2(s/aq) + 2HCl(aq) → MCl2(aq) + 2H2O(l)

Question 93

What happens to Group 2 metal carbonates when they are heated?

Give the general equation

Answer 93

Undergo thermal decomposition

Metal carbonate → Metal oxide + Carbon dioxide

MCO3(s) → MO(s) + CO2(g)

Question 94

What is a polarised ion?

Answer 94

A large (complex) ion that can have its electron distribution altered by small, highly-charged ions

This is known as polarisation

Question 95

What is charge density?

Answer 95

The charge of an ion relative to its size

Question 96

What is an acid?

Answer 96

A substance that produces/donates H+ ions in a solution

Question 97

What is a base?

Answer 97

A compound that reacts with an acid to produce water and a salt

Is a proton acceptor

Question 98

What is an alkali?

Answer 98

A soluble base

Dissolves in water to produce hydroxide (OH-) ions

Question 99

Briefly describe how a soluble salt can be made

Answer 99

By reacting the appropriate acid and alkali together

The solid salt can then be produced by evaporating the excess solution/water

Question 100

Breifly describe how an insoluble salt can be made

Answer 100

By a precipitation reaction

E.g. silver iodide can be made by reacting silver nitrate + potassium iodide