Atomic Structure

Created by

Shannon Obeng

Cards (50)

Atom 
Mainly made up of protons and neutrons, contained in the middle, with electrons orbiting in shells
Atom 
Protons have a positive charge
Neutrons have a zero charge
Electrons have a negative charge
Relative mass 
Protons and neutrons have a relative mass of 1, electrons have a relative mass of 1/2000
Element 
Top number is the mass number (protons + neutrons), bottom number is the atomic number (protons)
Atoms are neutral because the number of protons equals the number of electrons
Ion 
Has a different number of electrons and protons, forming a stable charge
Negative ion 
O2- has gained 2 electrons for a -2 charge
Positive ion 
Na+ has lost 1 electron for a +1 charge
Isotopes 
Elements with the same number of protons but different numbers of neutrons
Isotopes react chemically the same but have slightly different masses
John Dalton proposed atoms were solid spheres 
1803
JJ Thompson proposed the plum pudding model with electrons in a positive pudding 
Later
Rutherford discovered the small, positive nucleus and surrounding electron cloud 
Later
Niels Bohr proposed fixed energy levels for electrons
1913
Time-of-flight mass spectrometry 
1. Vaporize sample
2. Ionize sample
3. Accelerate ions
4. Ions drift at constant speed
5. Detect ions
Relative atomic mass 
Average mass of an atom of an element, relative to carbon-12
Relative molecular mass 
Average mass of a molecule, relative to carbon-12
Relative isotopic mass 
Mass of an isotope, relative to carbon-12
Mass spectra show isotopes of an element, with the mass/charge ratio on the x-axis and the abundance on the y-axis
Isotopic mass 
The mass of an isotope which makes it relatively straightforward if it had two electrons knocked off which would be quite rare
If an isotope has two electrons knocked off
The mass to charge ratio will be half as much
Abundance 
Always shown on the left, can be written as a percentage or a nominal value
If the abundance is a percentage, the total abundance of all isotopes must be 100%
Mass spectrometer spectrum 
Shows two isotopes of one element
One isotope has a mass of 35
One isotope has a mass of 37
Most abundant isotope 
The most common isotope
Calculating relative atomic mass
1. Abundance of isotope A * Mass to charge ratio of A
2. + Abundance of isotope B * Mass to charge ratio of B
3. Divide by total abundance
The calculated relative atomic mass can be used to identify the element
Molecular fragments 
When molecules are sent through a mass spectrometer, they break into smaller bits called fragments
Molecular ion peak 
The last significant peak on a mass spectrum, representing the unfragmented molecular ion
Electron subshells 
S
P
D
F
Electron subshells 
S has 1 orbital, can hold 2 electrons
P has 3 orbitals, can hold 6 electrons
D has 5 orbitals, can hold 10 electrons
F has 7 orbitals, can hold 14 electrons
Electron configuration 
Represents the arrangement of electrons in an atom's subshells, written as 1s2 2s2 2p6 etc.
Filling electron configurations 
1. Fill from lowest energy level upwards
2. Fill orbitals singly first before pairing up
Transition metal electron configurations
Electrons can move from higher energy 4s orbitals to partially fill 3d orbitals to create more stable configurations
Determining ion electron configurations
1. Remove electrons from highest energy levels first
2. For transition metals, remove 4s electrons before 3d
Ionization energy 
The minimum energy required to remove one mole of electrons from one mole of atoms in the gaseous state
Removing electrons from an ion
1. Remove electrons from 4s first
2. Then remove from 3D
3. Check the numbers to ensure total matches
Ionization energy 
Minimum amount of energy required to remove one mole of electrons from one mole of atoms in the gaseous state
Ionization energy is always endothermic and has a positive value
Shielding 
The more shells or electron shells between the positive nucleus and the outer electron, the less energy is required and the weaker the attraction