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Electron Configuration, Electron Lab. Objective Today I will be able to: Calculate the electron configuration for elements on the periodic table Construct a model of where electrons in the 1s orbital are located. Evaluation/ Assessment
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Objective • Today I will be able to: • Calculate the electron configuration for elements on the periodic table • Construct a model of where electrons in the 1s orbital are located. • Evaluation/ Assessment • Informal assessment – student responses when reviewing electron configuration problems. Listening to group interactions on practice sheets and lab • Formal Assessment – collecting and analyzing responses to electron configuration worksheet 2 and the where is the electron lab?
Lesson Sequence • Warm – Up • Elaborate: write electron configurations with a partner for questions 1-18 • Evaluate: review the questions as a class (informal assessment) • Explain: electron configurations using 3d orbitals. • Elaborate: Students will complete 19-36 on electron configuration WS with a partner • Evaluate: review the questions as a class (informal assessment) • Explain: abbreviated electron configurations • Elaborate: Students will add a column to the WS and repeat write the abbreviated configuration • Evaluate: Abbreviated configurations will be reviewed as a class (informal assessment) • Explore: Students will be sorted into groups and will complete the where is the 1s electron lab located • I will be assessing students progress during the lab as I monitor group discussions • Evaluate: Students will complete an electron configuration WS (assessment) • Explain: principles, rules and diagrams of electron configurations • Exit Ticket
Warm - Up • How many electrons can each orbital hold? • s = • p = • d = • f = • Write the electron configuration for the following elements • Helium • Nitrogen • Silicon
Objective • Today I will be able to: • Calculate the electron configuration for elements on the periodic table • Construct a model of where electrons in the 1s orbital are located.
Homework • Electron Configuration Practice
Agenda • Warm – Up • Electron Configuration Practice • Electron Configuration Notes • Electron Configuration Practice • Where’s the electron Lab • Exit Ticket
Electron Configuration Practice Complete numbers 1-18
Electron Configuration n 1 2 3 4 5 6 7 p-block s-block d-block n-1 f-block n-2
Electron Configurations • We can write the electron configurations for each element (assuming the atom has a neutral charge) representing the location of the elements electrons in the energy levels
Examples • Sodium (Na) • Has 11 electrons (when neutral) • Electron Configuration: • 1s22s22p63s1 • Cobalt (Co) • Has 27 electrons (when neutral) • Electron Configuration • 1s22s22p63s23p64s23d7
Why does 4s come before 3d? • 3d is of slightly higher energy than 4s, but 4s is further from the nucleus • It takes less energy for a 3d electron to form pairs then a 4s electron
Aufbau Diagram • Instead of using the periodic table as a road map, you can use the aufbau diagram to determine the order that the electrons occupy the different energy levels • Electrons fill the lowest energy orbitals first
Abreviated Electron Configuration • Scientists are lazy ;) • We need a shorthand way to represent electron configuration • It would take a long time to write the configuration for elements with a lot of electrons • How do we do this? • Noble Gas Configuration
Noble Gas Configuration • The last column on the periodic table is referred to as the noble gases • To write in abbreviated configuration: • Find the last noble gas within the configuration • Write the symbol • Write the remaining configuration • Example • Ca - 1s2 2s2 2p6 3s2 3p6 4s2 • Noble Gas Configuration = [Ar] 4s2
Noble Gas Configuration • Writing Noble Gas Configurations for ions is a little bit different • Must account for an electron being gained or lost • Chlorine Ion = Cl-1 • [Ne] 3s2 3p6 • Sodium Ion = Na+1 • [He] 2s2 2p6
Electron Configuration Practice Go back and write the Abbreviated (Noble Gas) configuration for the elements on the worksheet on the right hand margin
Pauli Exclusion Principle • An orbital can hold a max of 2 e- • To occupy the same orbital, they must spin in opposite directions • If 2 e- occupy an orbital, they are said to be “paired” • If only 1 e- is present in an orbital, it is “unpaired”
Hund’s Rule • e- occupy orbitals so that a max number of unpaired e- result • More stable arrangement
Orbital Diagram • Shows the electrons in their sublevels • Represented with arrows
Orbital Diagram 1s 2s 2px 2py 2pz H ↑ ↑ ↓ He C ↑ ↓ ↑ ↓ ↑ ↑ ↑ ↓ ↑ ↓ ↑ ↓ ↑ ↓ ↑ ↓ Ne
Exit Ticket • Draw an orbital diagram representing the arrangement of the electrons in sulfer