Dual Nature of Light: Energy Quantization and Wave-Particle Duality

1. Chapter 7 Atomic Structure and Periodicity g orbital dz2 orbital

2. Electromagnetic Radiation

4. Electromagnetic Radiation Electric Field and Magnetic Field Traveling at Right Angle

5. Waves • Waves have 3 primary characteristics: • 1. Wavelength : distance between two peaks in a wave. • 2. Frequency : number of waves per second that pass a given point in space. • 3. Speed c: speed of light is 2.9979  108 m/s.

6. Relation between wavelength and Frequency: Inverse Proportionality • (m)   (s-1) = c (m/s) 1Hz = cycles/s = s-1 1 nm = 10-9 m; 1 Ǻ = 10-10 m; 1 pm = 10-12 m 1nm = 10 Ǻ

7. As the amplitude increases, the intensity (the brightness) increases Intensity is proportional to A2: I  A2

8. Nature of Matter? End of 19 th Century: It was believed that MATTER and ENERGY are different No Intermingling between the two forms Particles: Mass; momentum; Localized (position specified) Waves: Massless; delocalized BUT WAS THIS REALLY TRUE? The Answer turns out to be No

9. UV-Catastrophe: significant historical importance heat blackbody ?!! UV-Catastrophe Planck: E = nh  Planck constant h = 6.626 10-34 j.s n = 1, 2, 3, 4…  frequency s-1 Meaning: Energy is quantized

10. Planck ContributionQuantization of Energy-- Max Planck: (summer of 1900) E = n h  Planck constant h = 6.626 10-34 j.s n = 1, 2, 3, 4…  frequency s-1 Energy transfer in matter is quantized Energy is absorbed and emitted in discrete quanta Each has an energy = h  = hc 

11. The Photoelectric Effect Explained by Einstein  Increasing the intensity of light increased the number of photoelectrons, but not their maximum kinetic energy.  Red light will not cause the ejection of electrons from Na, however much the intensity is increased.  A weak violet light will eject only a few electrons, but their maximum kinetic energy is greater than those ejected by intense light of longer wavelengths.

12. Summary of experimental results from the photoelectric effect • Electrons are not ejected when light shined is below a minimal frequency, called the threshold frequency o • The kinetic energy increased as the frequency of light increased above o • The magnitude of current was independent of  but increased as the intensity of light increases • The kinetic energy of the e was independent of the light intensity

13. DUAL NATURE of LIGHT Wave-Particle Duality Albert Einstein (Nobel Prize 1921): Light long thought of as waves is now theorized to consist of a stream of particles called photons: Each photon has an energyE = h  Therefore light has a wave nature and a particle nature In the special theory of relativity (1905):E = mc2 mc2 = h c / mc = h/ m.v = linear momentum, a property of particles

14. (620 nm) E = hν=Eo+K.E.= h νo + ½ mv2 Threshold frequency Kinetic energy of the electron

15. Evidence of the particle nature of light: Compton’s experiment (1922) Collisions between X-rays and electrons showed that photons actually have momentum as calculated by formula: mc = h/ 

16. It was thought before that scattering takes place as follows: Emits a spherical wave of the same frequency Beam of radiation Oscillating electron: vibrates with the frequency as the beam of the waves The particle nature of the photon (therefore particle-particle collision) explained why the scattered X-rays had a different frequency than the incident X-rays.

17. Summary: what do we know so far? 1. Energy quantization: energy can be absorbed or emitted by matter in discrete units called quanta (quantum) 2. Light has particulate and wave nature, known as the dual nature of light