1. Atomic Structure

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Plum Pudding Model 
After the discovery of electrons, the theory of atoms by which electrons are located in a sea of dispersed positive charge
Sub-Atomic Particles 
The fundamental particles; protons, neutrons and electrons
Nucleus 
The central part of the atom containing protons and neutrons
Nucleons 
The sub-atomic particles within the nucleus
Proton 
A sub-atomic particle:- Relative mass = 1- Relative charge = +1Contained within the nucleus
Neutron 
A sub-atomic particle:- Relative mass = 1 Relative charge = 0 Contained within the nucleus
Electron
A sub-atomic particle:- Relative mass = 1/1840- Relative charge = -1Surrounds the nucleus in orbitals
Strong Nuclear Force 
The force that holds the sub-atomic particles in the nucleus, despite being like particles so should repel one another
Electrostatic Force 
The force that holds protons and electrons together in the atom
Isotope 
The same number of protons within the nucleus, the same number of electrons, but a varied number of neutrons within the nucleus. The element does not change and is chemically the same due to the same number of electrons interacting with other electrons and elements
Mass Number 
Number of protons + number of neutrons.Also known as nucleon number (Physics)
Atomic Number 
Number of protons.Also known as proton number
Carbon-14 
A radioactive isotope of carbon
Octet Rule 
When drawing electron orbitals, this must be the rule that is considered for MOST elements. e.g. Boron defies this rule
Time of Flight Mass Spectrometer 
A device that measures the abundance of isotopes in a sample
Vacuum 
The whole TOF:MS is kept under this condition to prevent interference of foreign particles
Ionisation 
The sample is dissolved in a volatile solvent and pushed through a fine hollow point needle. This needle is connected to a positive high voltage supply, which rips off electrons from the sample. The solvent then evaporates to form single ions
Acceleration
The positive ions are attracted towards a negative plate. Lighter ions travel faster
Ion Drift 
The ions pass through a hole in the negatively charged plate. This forms a bean of ions which travel across a flight chamber
Detection 
When ions meet the detector (at different velocities due to their varies masses) the flight times are recorded as they hit a detector which causes a flow of current. This current enables the machine to identify how abundant that mass is
Data Analysis 
The signal that is detected is sent to a computer which plots on a graph the abundance of that mass
Low Resolution
A TOF:MS that detects to one decimal place. This is a more common TOF:MS
High Resolution
A TOF:MS that detects to five decimal places. This is a less common TOF:MS
Mass/Charge Ratio 
What data is plotted from a TOF:MS
TOF:MS 
Abbreviation for time of flight mass spectrometer
Overall Isotope Present
[(m/z1 x abundance1) + (m/z2 x abundance2)...]/ total abundance
Mini-Mass Spectrometer 
A mass spectrometer that investigates a library of spectra to detect chemical weapons, drugs or explosives
s
The first sub-level, can hold 2 electrons
p
The second sub-level, can hold 6 electrons
d
The third sub-level, can hold 10 electrons
f
The fourth sub-level, can hold 14 electrons
Arrows 
How to represent electrons in subshells
Spin 
Each element in the same orbital must have an opposite -BLANK-
Ionisation Energy 
The minimum enthalpy change required to remove one mole of electrons from one mole of an element in the gaseous state
Increase 
The trend in first ionisation energies across a period
Electron has entered a higher energy sub-level 
The reason for the first anomaly in first ionisation energy across a period. The first ionisation energy has a drop
Electron has paired up so has like charge repulsion 
The reason for the second anomaly in second ionisation energy across a period. The first ionisation energy has a drop
Decrease 
The trend in first ionisation energies down a group