The Structure of the Atom

Transcription

1 CHAPTER 5 The Structure of the Atom 5.4 Light and Spectroscopy

2 BC Today Democritus Atomism Dalton Modern atomic theory Crookes Cathode rays Thomson Discovery of the electron Rutherford Discovery of the nucleus Pauli Pauli exclusion principle Light and Spectroscopy

3 BC Today Democritus Atomism Dalton Modern atomic theory Crookes Cathode rays Thomson Discovery of the electron Rutherford Discovery of the nucleus Pauli Pauli exclusion principle Light and Spectroscopy

4 BC Today Democritus Atomism Dalton Modern atomic theory Crookes Cathode rays Thomson Discovery of the electron Rutherford Discovery of the nucleus Pauli Pauli exclusion principle Light and Spectroscopy

5 BC Today Democritus Atomism Dalton Modern atomic theory Crookes Cathode rays Thomson Discovery of the electron Rutherford Discovery of the nucleus Pauli Pauli exclusion principle Do we have evidence to support these claims? Light and Spectroscopy

6 A wave particle But light waves come in bundles of light (photons) and an electron behaves as a wave Light and Spectroscopy

7 orbital: group of quantum states that have similar spatial shapes, labeled s, p, d, and f Light and Spectroscopy

8 8 5.4 Light and Spectroscopy

9 Lithium s 3 rd electron has to go into the 2 nd energy level One electron per quantum state Fill lowerenergy levels first Light and Spectroscopy

10 Electromagnetic radiation. The photoelectric effect (where wave energy from the sun is absorbed by a metal and turned into electrical energy) and the fact that waves slow down when they go through a different medium (like water) indicates that the wave must have some type of particle property Light and Spectroscopy

11 frequency: the rate at which an oscillation repeats; one hertz (Hz) is a frequency of one oscillation per second. wavelength: the distance (separation) between any two successive peaks (or valleys) of a wave Light and Spectroscopy

12 The higher the frequency, the higher the energy Light and Spectroscopy

13 Light is a form of electromagnetic energy that comes from electrons in atoms The human eye can only detect a certain range of that energy: the visible spectrum Light and Spectroscopy

14 Light is a form of electromagnetic energy that comes from electrons in atoms The human eye can only detect a certain range of that energy: the visible spectrum Light and Spectroscopy

15 Analyzing starlight with a prism (one of the first spectrometers) White light from a lamp or the sun is not truly white! Light and Spectroscopy

16 Visible light is only a small range in the electromagnetic spectrum Light and Spectroscopy

17 We are surrounded by electromagnetic energy Light and Spectroscopy

18 18 increasing frequency increasing wavelength Light is a carrier of energy. Energy is proportional to frequency. Frequency is inversely proportional to wavelength.» Longer wavelength = lower frequency = lower energy.» Shorter wavelength = higher frequency = greater energy.

19 Light and Spectroscopy

20 On the scale of atoms Electrons Light Planck s constant (h) is used to calculate the energy and wavelength of electrons and photons Light and Spectroscopy

21 Energy of a photon Remember that light travels as bundles called photons A very small unit of energy 1 electron volt (ev) = x J Light and Spectroscopy

22 Wavelength and frequency are related Light and Spectroscopy

23 The wavelength of red laser light is 652 nm. What is its frequency? How much energy does a photon of this light have in electron volts? Light and Spectroscopy

24 The wavelength of red laser light is 652 nm. What is its frequency? How much energy does a photon of this light have in electron volts? Asked: Given: Relationships: Frequency and energy m c, E h Light and Spectroscopy

25 The wavelength of red laser light is 652 nm. What is its frequency? How much energy does a photon of this light have in electron volts? Asked: Given: Relationships: Solve: Frequency and energy m c, E h c 3 10 m / s c therefore m s V s s E h e / 1.9 ev Light and Spectroscopy

26 The wavelength of red laser light is 652 nm. What is its frequency? How much energy does a photon of this light have in electron volts? Asked: Given: Relationships: Solve: Frequency and energy m c, E h c 3 10 m / s c therefore m s V s s E h e / 1.9 ev Light and Spectroscopy

27 The wavelength of red laser light is 652 nm. What is its frequency? How much energy does a photon of this light have in electron volts? Asked: Given: Relationships: Solve: Answer: Frequency and energy m c, E h c 3 10 m / s c therefore m s V s 1 / s E h e ev Since 1 Hz = 1/s, the frequency is 4.6 x Hz and the energy is 1.9 ev Light and Spectroscopy

28 Light from an incandescent light bulb: prism all possible energy levels electron Light and Spectroscopy

29 Light from pure hydrogen: prism fixed energy levels electron Light and Spectroscopy

30 Line Emission Spectra of Excited Atoms Excited atoms emit light of only certain wavelengths The wavelengths of emitted light depend on the element Light and Spectroscopy

31 Hydrogen atoms can only absorb and emit light of very specific energies Light and Spectroscopy

32 Matter and light Why does the atom absorb only specific (discrete) energies? Light and Spectroscopy

33 Matter and light Why does the atom absorb only specific (discrete) energies? Remember: only some energy levels are allowed Light and Spectroscopy

34 An excited lithium atom emitting a photon of red light to drop to a lower energy state Light and Spectroscopy

35 Electrons and Quanta Ground state the lowest energy position an e - can occupy. Excited state a temporary high-energy position. Quantum (pl. quanta) the amount of energy needed to move an e - to a higher energy level Light and Spectroscopy

36 Electrons and Quanta If an atom absorbs exactly 1 quantum of energy, an electron can be boosted from a ground state to an excited state. The electron is only in the excited state for a very short period of time. Soon the e - returns to its ground state and emits the quantum of energy as light. In some cases the emitted light is in the visible spectrum Light and Spectroscopy

37 Light and Spectroscopy

38 An excited H atom returns to a lower energy level Light and Spectroscopy

39 Matter and light Energy levels Energy levels Photon (energy) Energy of the photon matches a gap between levels Energy (light) is absorbed. Energy of the photon does not match a gap between levels Energy (light) passes through the atom Light and Spectroscopy

40 Matter and light Energy levels Photon (energy) another photon is emitted Energy of the photon matches a gap between levels Energy (light) is absorbed. specific color (wavelength) Light and Spectroscopy

41 Each type of atom has a different electron structure. Each element has unique energy levels like a fingerprint Light and Spectroscopy

42 Flame Tests Flame test used to ID some metals in compounds. Each metal gives a flame a characteristic color. Can identify metals based on flame colors Light and Spectroscopy

43 Spectrum cards How to read the spectrum cards Light and Spectroscopy

44 Spectrum cards Combinations of elements contain spectral lines from both Light and Spectroscopy

45 Visible light is only a small range of the electromagnetic spectrum Light and Spectroscopy

46 Each type of atom has a different electron structure. Each element has unique energy levels like a fingerprint Light and Spectroscopy