Topic 1

Created by

Holly Haggarty

Cards (42)

Transition metals compared to group 1
Harder and stronger
Higher melting points (except for mercury) and higher densities
Much less reactive and don't react as vigorously with oxygen or water
Transition metals 
chromium
manganese
iron
cobalt
nickel
copper
Periodic table 
Elements are arranged in order of atomic (proton) number (smaller number) and so that elements with similar properties are in columns, known as groups
Elements in the same periodic group
Have the same amount of electrons in their outer shell, which gives them similar chemical properties
John Newlands 
Ordered his table in order of atomic weight
Realised similar properties occurred every eighth element – 'law of octaves' but broke down after calcium
chromium 
lustrous, brittle, hard metal
manganese 
hard and very brittle, difficult to fuse, but easy to oxidise
Atoms 
The smallest part of an element that can exist
Dmitri Mendeleev 
Ordered his table in order of atomic mass, but not always strictly – i.e. in some places he changed the order based on atomic weights
Left gaps for elements that he thought had not been discovered yet
Chemical symbols 
Represent an atom of an element e.g. Na represents an atom of sodium
The table is called a periodic table because similar properties occur at regular intervals
Compounds 
Formed from elements by chemical reactions, contain two or more elements chemically combined in fixed proportions, can be represented by formulae
iron 
good conductor, rusts easily in air, strong, ductile
cobalt 
malleable, brittle, hard, high melting point
Elements with similar properties are found in the same column (groups)
nickel 
hard, malleable, and ductile, fairly good conductor of heat and electricity
Mixtures 
Consist of two or more elements or compounds not chemically combined together, can be separated by physical processes
copper 
highly ductile and conductive, malleable and soft
Development of the model of the atom
1. First thought to be tiny spheres
2. Discovery of electron led to plum pudding model
3. Alpha particle scattering experiment led to conclusion mass concentrated in nucleus
4. Bohr suggested electrons orbit nucleus at specific distances
5. Later experiments showed positive charge subdivided into protons
6. Chadwick's work provided evidence for neutrons
Typical properties of transition metals
They have ions with many different charges
Form coloured compounds
Are useful as catalysts
Atomic number 
The number of protons in an atom of an element, all atoms of a particular element have the same number of protons
Transition metal ion charges
chromium: +2 +3 +4 +5 +6
manganese: +2 +3 +4 +5 +6 +7
iron: +2 +3 +4 +5 +6
cobalt: +2 +3 +4
nickel: +2 +3 +4
copper: +1 +2 +3
Relative electrical charges of subatomic particles
Proton: +1
Neutron: 0
Electron: -1
Elements with properties predicted by Mendeleev were discovered and filled the gaps
Colours of compounds with transition metals
chromium: +2 +3 +6
manganese: +2 +4 +6 +7
iron: +2 +3
cobalt: +2 +3
nickel: +2
copper: +2
An atom has an overall charge of 0, so number of protons = number of electrons
Knowledge of isotopes made it possible to explain why the order based on atomic weights was not always correct
Uses of transition metals as catalysts 
Decomposition of hydrogen peroxide (2H2O2 -> 2H2O + O2)
Haber process (N2 + 3H2 ↔ 2NH3)
Manufacture of margarine (adding H2 to double bonds)
When electrons, protons and neutrons were discovered in the early 20th century, elements were ordered in atomic (proton) number
Atom size and mass
Atoms are very small (radius ~0.1 nm), nucleus is less than 1/10,000 of atom size but holds almost all the mass
Relative mass: Proton 1, Neutron 1, Electron very small
When this was done, all elements were placed in appropriate groups
Metals 
Elements that react to form positive ions
Non-metals 
Elements that do not form positive ions
Mass number 
The sum of the protons and neutrons in an atom
Isotopes 
Atoms of the same element with different numbers of neutrons
Group 1 - Alkali metals 
They have characteristic properties due to the single electron in their outer shell
Metals in group one react vigorously with water to create an alkaline solution and hydrogen
They all react with oxygen to create an oxide
They all react with chlorine to form a white precipitate
The reactivity of the elements increases going down the group
Group 0 - Noble gases
They have 8 electrons in their outer shell (except helium, which has 2)
All of them (including helium) have full outer shells
They are unreactive and do not easily form molecules, because they have a stable arrangement of electrons (full outer shell)
The boiling points of the noble gases increase with increasing relative atomic mass (going down the group)
Relative atomic mass 
An average value that takes account of the abundance of the isotopes of the element
Calculating relative atomic mass
Carbon has 2 isotopes: carbon-14 (20% abundance) and carbon-12 (80% abundance). Relative atomic mass = ((14 x 20) + (12 x 80)) / 100 = 12.4
Group 7 - The halogens 
Similar reactions due to their seven electrons in their outer shell
Non-metals and exist as molecules made of pairs of atoms (e.g. Cl2)
They react with metals to form ionic compounds in which the halide ion carries a -1 charge
They react with nonmetals to form covalent compounds, where there is a shared pair of electrons
As you go down the group, relative molecular mass, melting point and boiling point all increase
Reactivity decreases down the group because halogens react by gaining an electron (to increase their number of outer shell electrons from 7 to 8) and the number of shells of electrons increases down the group, so down the group the element attracts electrons from other atoms less, so can't react as easily
A more reactive halogen (one from higher up group 7) can displace a less reactive one in an aqueous solution of its salt