P4: Atomic Structure
Cards (41)
- AtomosIdentical lumps that all matter was made up of, according to early Greek philosophers
- Democritus proposed that all matter was made up of tiny "atomos"5th Century BC
- Plum Pudding ModelAtoms were spheres of positive charge with tiny negative electrons stuck in them like fruit in a plum pudding
- Alpha Scattering Experiment1. Firing a beam of alpha particles at thin gold foil2. Most particles passed straight through3. Some were deflected more than expected4. A few were deflected back the way they had come
- Findings from Alpha Scattering Experiment
- Most of the mass of the atom must be concentrated at the centre in a tiny nucleus
- The nucleus must also have a positive charge, since it repelled the positive alpha particles
- Most of an atom is just empty space
- Nuclear Model of the AtomA positively charged nucleus surrounded by a cloud of negative electrons
- Bohr's Theoretical Calculations1. Electrons orbit the nucleus at certain distances called energy levels2. Agreed with experimental data
- Improved Nuclear Model
- Nucleus made up of a group of particles (protons) which all had the same positive charge that added up to the overall charge of the nucleus
- Existence of neutrons proved, which explained the imbalance between atomic and mass numbers
- Current Model of the Atom
- Tiny nucleus containing protons and neutrons, surrounded by a cloud of fast-moving electrons
- Nucleus makes up most of the mass of the atom
- Electrons in energy levels can move within or leave the atom
- The current model of the atom may change in the future as new experiments are conducted
- IsotopesAtoms with the same number of protons (atomic number) but different numbers of neutrons (mass number)
- Radioactive DecayUnstable isotopes decay into other elements and give out radiation to become more stable
- Types of Ionising Radiation
- Alpha
- Beta
- Gamma
- Alpha ParticlesHelium nuclei emitted from the nucleus, strongly ionising but not very penetrating
- Beta ParticlesFast-moving electrons emitted from the nucleus, moderately ionising and moderately penetrating
- Gamma RaysElectromagnetic radiation emitted from the nucleus, weakly ionising but highly penetrating
- When an atom emits an alpha particleIts atomic number decreases by 2 and its mass number decreases by 4
- When an atom undergoes beta decayA neutron turns into a proton, increasing the atomic number by 1 but not changing the mass number
- Gamma rays do not change the charge or mass of the nucleus
- Uses of Radioactive Radiation
- Alpha radiation in smoke detectors
- Beta radiation to test metal sheet thickness
- Gamma radiation for various uses
- Nuclear EquationsShow radioactive decay, with the total mass and atomic numbers equal on both sides
- Alpha decayA type of radioactive decay where an atomic nucleus emits an alpha particle
- Gamma rays are sometimes also released when a nucleus decays by alpha or beta decay
- Beta decay1. Neutron in the nucleus turns into a proton and releases a fast-moving electron (the beta particle)2. The number of protons in the nucleus has increased by 13. The mass of the nucleus doesn't change as protons and neutrons have the same mass4. A beta particle is written as e in nuclear equations
- In both alpha and beta emissions a new element will be formed, as the number of protons (atomic number) changes
- Gamma rays don't change the charge or mass of the nucleus
- Gamma raysA way of getting rid of excess energy from a nucleus
- RadioactivityA totally random process where radioactive substances give out radiation from the nuclei of their atoms
- ActivityThe rate at which a radioactive source decays, measured in becquerels (Bq) where 1 Bq = 1 decay per second
- The radioactivity of a source decreases over time as radioactive nuclei decay
- Half-lifeThe time taken for the number of radioactive nuclei in an isotope to halve
- The half-life is the time taken for the activity, and so count-rate, to halve
- A short half-life means the activity falls quickly, while a long half-life means the activity falls more slowly
- A graph of activity against time will always be shaped like an exponential decay curve
- The half-life can be found from the graph by finding the time interval corresponding to a halving of the activity
- Background radiationLow-level radiation that's around us all the time, from natural sources and human activity
- Background radiation comes from naturally occurring unstable isotopes, radiation from space, and radiation due to human activity
- Radiation doseThe risk of harm to body tissues due to exposure to radiation, measured in sieverts (Sv)
- Exposure to radiation is called irradiation, which does not make an object radioactive
- ContaminationRadioactive particles getting onto or into an object, which can then decay and cause harm