Development of Atomic Models Electrons in Atoms Development of Atomic Models Jot down 3 things you already know about atoms
Things Rutherford’s Atomic Model Could Explain Protons and Neutrons composed the atomic nucleus Electrons move around the nucleus in the same way that planets revolve around the sun
And Things it Couldn’t The chemical properties of elements: Why do metals give off specific colors when heated? He needed to better describe the behavior of electrons!
Rutherford’s Model Changed! 1913 – The Bohr Model Energy of an atom changes when it absorbs or emits light Electrons are only found in specific circular paths, or orbits around the nucleus Each possible orbit have fixed energy levels
Can an electron move into different energy levels? To move from one energy level to another, they need to gain or lose the right amount of energy A quantum of energy is the amount of energy required to move an electron from on energy level to another The amount of energy gained or lost is not always the same
Another Atomic Model is Developed 1926Schrodinger (Used Mathematical Solutions) Quantum Mechanical Model – determines the allowed energies an electron can have and how likely it is to find the electron in various locations around the nucleus
Where can you find electrons? Atomic Orbitals – region in space in which there is a high probability of finding an electron Principle energy levels (n = 1) Energy sublevels (1) Draw orbitals. Table on page 131.
Maximum numbers of electrons Energy level n # of electrons 1 2 8 3 18 4 32
Sublevels Sublevel corresponds to a different shaped orbital
Change Proceeds to Lowest Energy In an atom, electrons make the most stable arrangement Electron Configuration- the ways in which electrons are arranged in various orbitals around the nucleus of an atom Pencil demo
Aufbau Principle Electrons occupy the lowest energy orbital first
Pauli Exclusion Principle An atomic orbital may describe at most 2 electrons
Hund’s Rule Electrons occupy orbitals of the same energy in a way that makes the number of electrons with the same spin direction as large as possible Give examples. Then BATTTTLEEEEEEESHIPPPPPPPPPPPPP maybe next class
Energy Levels, Sublevels and Orbitals A sublevel is a region IN the energy level 4 possible sublevels Orbital is a region in the sublevel. Each orbital can hold only 2 electrons S 1 orbital 2 electrons p 3 orbitals 6 electrons d 5 orbitals 10 electrons f 7 orbitals 14 electrons
What is light? Newton believed it was made up of particles BUT it was proven to consist of waves. Wave cycles start at zero, increase to the highest value, passes through zero to reach its lowest value, and returns to zero again.
3 Properties of Waves Amplitude – the wave’s height from zero to the crest (highest point of the wave) Wavelength – distance between the crests Frequency – the number of wave cycles to pass a given point per unit of time
Calculate Wavelength λ= c/ν λ= Wavelength (m) C= Speed of Light (2.998 x108 m/s) ν= Frequency (/s)
Electromagnetic Spectrum
Practice! Calculate the wavelength of the yellow light emitted by a sodium lamp. The frequency of the radiation is 5.10x1014 /s. What is the frequency of radiation with a wavelength of 5.00x10-8m? 1. 5.88x10-7 2. 6.00x1015/s
Atomic Spectra When atoms absorb energy, electrons move into higher energy levels. These electrons move into higher energy levels and lose energy by emitting light and returning to the lower energy levels. The light emitted varies like a fingerprint
Electron Energy Ground State – Lowest possible energy of an electron When an electron absorbs energy it enters an excited state N= 2,3,4,5,6 etc. A quantum of energy in the form of light is emitted when an electron drops to a lower energy level Electronic Transition
Quantum Mechanics Einstein proposed that light could be described as quanta of energy Light quanta are known as particles
Classical vs. Quantum Classical Mechanics Quantum Mechanics Describes the motions of bodies much larger than atoms Quantum Mechanics Describes the motions of subatomic particles and atoms as waves
Heisenberg Uncertainty Principle It is impossible to know exactly both the velocity and position of a particle at the same time