Expanding the Model of the Atom (Electrons in Atoms) Ch 5 (Chem IH) Ch 2.2 & 7 (Chem I)
Electromagnetic Spectrum 1
Electromagnetic Spectrum 2
Light: Electromagnetic Spectrum Energy can travel in waves. There are high energy and low energy waves. The ones we can see are called “the visible spectrum.” ROY G BIV Red is the low energy end: violet is the high energy end.
Properties of Waves 1. Wavelength (λ): distance between crests of a wave. Ex: radio waves = 10 2 m
Properties, cont. 2. Frequency(ν): number of wave cycles to pass a point per second (wps). wps = hertz (Hz) Ex: microwaves = 3 x x Hz
Properties, cont. 3. Amplitude: wave height from zero to crest 0→0→ crest →
Speed of EM Radiation All EM radiation travels at the speed of light, c. c = x 10 8 m/s
Relationship between wavelength & frequency c = λν It is a constant relationship The product of the 2 variables = the speed of light If λ increases, ν decreases If ν increases, λ decreases
Sample Problem 5.1(p 140) Calculate the wavelength of the yellow light emitted by the lamp shown if the frequency of the radiation is 5.10 x Hz
Solution 1. Analyze: Knowns: ν (frequency)= 5.10 x Hz c = x 10 8 m/s Unknown: Wavelength (λ) = ?m
Solution 2. Calculate Solve the equation c = ν λ for λ Substitute the known values and solve. λ =2.998 x 10 8 m/s 5.10 x Hz =
Solution (Cont.) 3. Evaluate: Does the result make sense? The magnitude of the frequency is much larger than the numerical value of the speed of light, so the answer should be much less than 1. Is it?
Developments in the Atomic Model In 1913, we had the Rutherford model of the atom. electrons thought to occupy the area outside the nucleus.
Research at the time (1913) Scientists knew elements release light when they are excited (by electricity or other energy sources.) Different elements released different colors.
Bohr’s Model of the Atom Bohr theorized that e-s could only exist at certain distances from the nucleus in energy levels (E.L.’s):
Light, Energy, and Electrons e-s are arranged in energy levels (e.l.’s), at different distances from nucleus Close to nucleus = low energy Far from nucleus = high energy
Light, Energy, & Electrons, cont. e-s in highest occupied level are “valence e-s” Only so many e-’s can fit in e.l.’s e-s fill lower e.l.’s before being located in higher e.l.’s* Ground state is the lowest energy arrangement of e-s. * There are exceptions we will learn later!)
Light, Energy, and Electrons e-s can jump to higher energy levels if they absorb energy. They can’t keep the energy so they lose it and “fall back” to lower levels. When they do this, they release the energy they absorbed in the form of light.
Light, Energy, and Electrons (See p 75 of text (ChemI)/ p 129 (ChemIH)) Electron energy levels are like rungs of a ladder. Ladder – To climb to a higher level, you can’t put your foot at any level, – you must place it on a rung Electron energy levels – e-s must also move to higher or lower e.l.’s in specific intervals
Niels Bohr "The opposite of a correct statement is a false statement. But the opposite of a profound truth may well be another profound truth." Neils Bohr Neils Bohr studied w/Rutherford
Bohr Model of the Atom Interactive Bohr Model
Light, Energy, and Electrons Quantum-the amount of energy required to move an electron from one E.L. to another.
Atomic Emission Spectrum (A.E.S) Each element emits a color when its excited e- s “fall back.” Pass this light thru a prism, it separates into specific lines of color. You can identify an element by its emission spectrum! (no 2 elements have the same AES)
Emission Spectra of H, He, Ne
Atomic Emission Spectrum (cont.) See Fig 7.4 on p 235 (ChemI) /p143 (ChemIH) H has 4 spectral lines (4 colored lines) Mercury (Hg) has 11 lines! Ne has 20+ lines! Problem: there are more lines than you would expect if there are only a few energy levels. Hypothesis: There must be many sublevels in an energy level
Quantum Mechanical Model of Atom Bohr’s Model only adequately explained behavior of H This new model (QMM) explains why so many emission spectrum lines
QMM, cont. Says that particles can behave like waves Gives us the allowed energies of e-s & the likelihood of finding e-s at various locations around the nucleus
QMM, cont. Albert Einstein (1905) proposed that light behaves like particles(matter) b/c it has packets of energy called photons These photons correspond to quanta of energy
QMM, cont. Louis de Broglie (1924) proposed that particles (matter) can also behave like waves. Confirmed in 1927 by Clinton Davisson who bombarded metals with e- beams. – He observed reflection patterns very much like X- rays (EM radiation) – e-s were behaving like waves!
Use of e- waves Electron microscope magnifies tiny objects b/c e- wavelength much smaller than visible light snowflake
Heisenburg Uncertainty Principle Def: if you want to locate something, you can shine light on it When you do this to an electron, the photons send the e- off in an unpredictable direction (def):Therefore, you can never know BOTH the position and velocity of an e- at the same time
Electron Sublevels Each electron has an “address,” where it can be considered to be located in the atom. Main energy level (principal quantum #) = “hotel” Sublevel = “floor” Orbital = “room” – Regions of space outside the nucleus – All orbitals in a sublevel have the same energy – 2 electrons max can fit in an orbital
Sublevels in Atoms See Fig 7.5 on p 235 Main energy level Types of sublevels # of orbitals# of electrons 1s1 2spsp 1 3 (4 total) 3spdspd (9 total) 4-7spdfspdf (16 total)
Orbitals s orbitals are spherical – There is only 1 orbital p orbitals are dumbbell shaped – There are 3 orbitals, all with = energy – Each is oriented on either x, y, or z axis – They overlap d orbitals have varying shapes – There are 5 orbitals, all with = energy f orbitals have varying shapes – There are 7 orbitals, all with = energy
Electron Configurations Electrons are always arranged in the most stable (lowest energy) way This is called“electron configuration” or “ground state”
The Periodic Table & Atomic Structure Shape of p. table is based on the order in which sublevels are filled REGIONS OF THE P. TABLE (see p 244 of book) s REGION (“block”) - Groups 1 & 2 p REGION (block) - Groups d REGION (block)- Groups 3-12 (Transition Elements) f REGION (block)- (Inner Transition Elements)
Regions or “Blocks” of the P. Table (don’t need to copy)
Writing e- Configurations for Elements Using the P. Table 1. Always start with Period 1-go from L to R. 2. Go to Period 2-from L to R 3. Go to Period 3- from L to R 4. Continue w/Periods #4-7, L to R, until you arrive at the element you are writing e- configuration for. Exception: elements in d block are 1 main E.L lower than the period where they are located Exception: elements in f block are 2 main E.L.s lower than the period where they are located
Correct Order of Sublevels (lowest to highest energy) 1s, 2s, 2p, 3s, 3p, 4s, 3d, 4p, 5s, 4d, 5p, 6s, 4f, 5d, 6p, 7s, 5f, 6d, 7p
e- configurations Use the P. Table to write the sublevels in increasing order. Add a superscript next to each sublevel that shows how many e-s are in the sublevel Ex: Hydrogen: 1s 1 Helium: 1s 2 Lithium: 1s 2 2s 1 Oxygen: 1s 2 2s 2 2p 4
Identifying Valence e-s Valence e-s are the electrons in the highest occupied main energy level. Identify them by finding the “biggest big number” in your e- configuration. Ex: Oxygen: 1s 2 2s 2 2p 4 There are 6 valence e-s in the 2nd main energy level (valence level)
Why are d & f block elements’ sublevels out of order? When you get to the higher main E.L.’s, the sublevels begin to overlap.
Exceptions: Some Transition Elements (don’t need to copy) Titanium - 22 electronsNORMAL 1s 2 2s 2 2p 6 3s 2 3p 6 4s 2 3d 2 Vanadium - 23 electronsNORMAL 1s 2 2s 2 2p 6 3s 2 3p 6 4s 2 3d 3 Chromium - 24 electronsEXCEPTION 1s 2 2s 2 2p 6 3s 2 3p 6 4s 2 3d 4 is expected But this is wrong!!
Chromium is actually… (copy this!) 1s 2 2s 2 2p 6 3s 2 3p 6 3d 5 4s 1 3d 5 4s 1 Instead of 4s 2 3d 4 There is less repulsion (lower energy) in the 2 nd arrangement 4s3d
Noble Gas Notation Short-cut way of showing e- configuration A Noble Gas is a Group 18 element. 1.Identify the noble gas in the period above your element of interest. Write this symbol in brackets. 2.Write the e- configuration for any additional e-s that your element of interest has, but the noble gas doesn’t have. Ex: Nitrogen: 1s 2 2s 2 2p 5 becomes [He] 2s 2 2p 5
Arrow Orbital Diagram- Used to show e- configuration. SYMBOLS: A box represents an orbital – Label each box with the sublevel: 1s 2s 2p 2p 2p An arrow represents an electron – 2 arrows (e-s) in the same orbital face opposite directions. – Example: oxygen, see above ↑ ↓ ↑↑
Arrow Orbital Diagram- Used to show e- configuration, cont. INSTRUCTIONS: Fill electrons from lowest to highest sublevel. Never place 2 e-s in the same orbital of a sublevel until you have placed one in each of the orbitals (Hund’s Rule)