1 / 36

Chapter 5 Arrangement of electrons in atoms

Chapter 5 Arrangement of electrons in atoms. * Rutherford's model of the atom does not explain how the electrons fill the space Light (electromagnetic radiation) has a dual nature, meaning it behaves like a wave and a particle. A) Wave description of light –

Télécharger la présentation

Chapter 5 Arrangement of electrons in atoms

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Chapter 5Arrangement of electrons in atoms

  2. *Rutherford's model of the atom does not explain how the electrons fill the space • Light (electromagnetic radiation) has a dual nature, meaning it behaves like a wave and a particle.

  3. A) Wave description of light – • 1800's scientists believed that light was a beam of energy moving through space in the form of waves • (like waves on a lake when a pebble is thrown in)

  4. *All waves have 4 characteristics: amplitude- height of wave origin to crest wavelength (λ)- distance between crests frequency (v) how fast up and down (oscillations) units: waves/sec, Hertz (Hz), s-1 speed (c) - constant 2.998 x 108 m/s

  5. C = speed of light (latincelerata) Formula: c = λv* *wavelength and frequency are inversely proportional, meaning that if wavelength decreases then frequency increases & vice versa.

  6. #1 Example problem: What is the frequency of light that has a wavelength of 450 nm? hint: convert nm to m (1m = 1 x 109 nm)

  7. #2 Example problem: What is the wavelength of electromagnetic radiation if its frequency is 4.5 x 10-3 Hz?

  8. Exit Question: 5 points • Write down 3 things that you learned today. • Write down one thing you don’t understand.

  9. B) Particle description of light • 1900's experiments showed that light behaved like a stream of extremely tiny, fast moving particles.

  10. 1) photoelectric effect - refers to the emission of electrons from a metal when light shines on the metal (but only if the frequency was at a certain minimum) ex/ solar powered items work if you have enough light

  11. 2) Max Planck - studied light emitted from hot metal objects • (like a hot horseshoe glows). • He suggests that objects emit energy in small specific amounts called quanta.

  12. 3) Quantum - minimum quantity of energy that can be lost or gained by an atom To calculate the energy of a quantum of light use formula: E = hv Where: E = energy (in Joules units) h = 6.626 x 10-34Js (Joule seconds) Planck's constant v = frequency

  13. Albert Einstein (1905) • Introduces the wave-particle dual nature of light. • wave & particle behavior • each particle carries a quantum of energy. • EM radiation is absorbed by matter in whole numbers of photons.

  14. photon - particle of light (EM radiation) having zero mass and carrying a quantum of energy. Ephoton = hv

  15. Example problem: Using: Ephoton = hv Calculate the frequency for a photon of light that has an energy 3.2 x 10-19 J.

  16. Hydrogen’s line emission spectrum • Niels Bohr passed electric current through hydrogen gas • PINK colored light emitted • When energy is added to an atom, electrons become excited & move to higher energy level.

  17. A photon is emitted when the electrons move back to a more stable, GROUND state. • Ground state – lowest energy state of an atom • Excited state – state in which an atom has a higher potential energy than its ground state. • Ephoton= E2 – E1 = hv

  18. Ephoton= E2 – E1 = hv The energy of this photon is equal to the difference in energy between the atom’s initial state and its final state.

  19. Bohr Model of the Hydrogen atom 1913 • Bohr links the photon emission of hydrogen to a model of the atom’s electron. See p. 129 • Electron circles in orbits (defined paths) • Electron has a fixed energy • Each concentric circle orbit had an empty space in between where the electron could not exist (ladder analogy p. 129)

  20. Explanation of the spectral lines produced by hydrogen: An electron cannot gain or lose energy. It can move to a higher energy orbit by gaining an amount of energy equal to the difference in final and initial states.

  21. The Quantum Model of the atom • Quantum Theory – • modern description, • primarily mathematical, • of the behavior of electrons in atoms. • (it estimates the probability of finding an electron in a certain position)

  22. Louis De Broglie (“de broylee”) 1924 He proposed an equation that suggested that any matter with mass and velocity has a corresponding wavelength.

  23. Setting both energy equations equal to each other: • E = mc2 E=hv • mc2 = hv (substitute v with wavelength from c = λv) • Wavelength(λ) = h/mc

  24. Werner Heisenberg 1927 • e- s are detected by their interaction with photons. • This interaction will change both the direction and position of the e-.

  25. Heisenberg uncertainty principle • it is impossible to determine simultaneously both position and velocity of an e-

  26. Therefore, e- s are located in orbitals or 3-D clouds of probable location • (not neat orbits like Bohr’s model)

  27. Erwin Schrodinger came up with an equation that treated electrons in atoms as waves. • Quantization of electron energies was an outcome of his equation (vs. Bohr’s theory that assumed quantization as a fact) • Quantum numbers - numbers used to specify the energy, location, shape, orientation of atomic orbitals, & spins of electrons in orbitals

  28. Quantum numbers - • Numbers used to describe an e- • 1. energy level • 2. location • 3. Shape of orbital • 4. orientation of orbitals • 5. spins of e-s in orbitals

  29. 1) Principle quantum number– (n) main energy level occupied by the electron; the distance of an orbital to the nucleus. ex/ n= 1, n=2 (whole numbers) • 2) Angular momentum quantum number (l) indicates shape of orbital: s – sphere shape (2 e-) p – dumbbell shape (6e-) d – double dumbbell (10 e-) f – complex shape (14 e-)

  30. 3) Magnetic quantum number (m) orientation of orbital (x, y, z) • 4) Spin Quantum number has two possible values +1/2 or -1/2

  31. Electron Configurations - the ways in which electrons are arranged around the nucleus of an atom. Apply three rules: • Aufbau principle – electrons enter orbital of lowest energy first • Pauli exclusion principle – two electrons of opposite spin occupy an orbital (no two electrons in the atom can have the same set of quantum numbers)

  32. 3) Hund’s Rule – When electrons occupy orbitals of equal energy, electrons fill the orbitals one at a time and then will pair up. Write the electron configuration for the following elements: • H b) B c) C d) Fe e) Zn Draw orbital diagrams for the same elements above.

  33. Sec 1 • For electromagnetic radiation, c (speed of light) equals _________________________. • A quantum of electromagnetic energy is called _______________. • The energy of a photon is related to its _____________. • If electrons in an atom have the lowest possible energies, the atom is in the ________________. • Bohr’s theory helped explain why excited hydrogen gas gives off certain ___________ of light. • According to Bohr’s theory, an excited atom would _______________ energy.

  34. Section 2 Review Q’s • A three-dimensional region around a nucleus where an electron may be found is called a(n) ____________. • Unlike in an orbit, in an orbital an electron’s position cannot be known _______________. • What are the 4 quantum numbers and what do they represent? • What are the shapes of the orbitals? • How many electrons fit in each orbital? • What is the difference between a 2s orbital and a 4s orbital?

  35. Sec 2 • How many orbital shapes are possible at the 2nd energy level? 3rd energy level? • An electron for which n= 5 has more _____ than an electron for which n=3. • If 8 electrons completely fill a main energy level, what is n?

  36. Section 3 Review Q’s • Draw the diagonal rule. What does this rule show? • Know the 3 rules for writing electron configurtions. • Write the electron configuration for Si. • Draw the orbital diagram for Mg. • What element has the following configuration: 1s22s22p63s1 ? • How many electrons in the highest energy level of a bromine atom? • Which element has the electron configuration of [Ar]4s23d104p5

More Related