Chapter 6 Characteristics of Atoms

1. Chapter 6Characteristics of Atoms Department of Chemistry and Biochemistry Seton Hall University

2. Characteristics of Atoms • Atoms posses mass • most of this mass is in the nucleus • Atoms contain positive nuclei • Atoms contain electrons • Atoms occupy volume • electrons repel each other, so no other atom can penetrate the volume occupied by an atom • Atoms have various properties • arises from differing numbers of protons and electrons • Atoms attract one another • they condense into liquids and solids • Atoms can combine with one another

3. Wave aspects of Light • Most useful tool for studying the structure of atoms is electromagnetic radiation • Light is one form of that radiation • Light is characterized by the following properties: • frequency, , nu • wavelength, , lambda • amplitude

4. Electric and magnetic field components of plane polarized light • Light travels in z-direction • Electric and magnetic fields travel at 90° to each other at speed of light in particular medium • c (= 3 × 1010 cm s-1) in a vacuum

5. Connections between wavelength and frequency • c = 3108 m/s in a vacuum • make sure the units all agree!

6. Characterization of Radiation

7. Wavelength and Energy Units • Wavelength • 1 cm = 108Å = 107 nm = 104  =107 m (millimicrons) • N.B. 1 nm = 1 m (old unit) • Energy • 1 cm-1 = 2.858 cal mol-1 of particles = 1.986  1016 erg molecule-1= 1.24  10-4 eV molecule-1 • E (kcal mol-1)  (Å) = 2.858  105 • E(kJ mol-1) = 1.19  105/(nm)297 nm = 400 kJ

8. The photoelectric effect • A beam of light impacts on a metal surface and causes the release of electrons (the photoelectron) if certain conditions are satisfied • Conditions • light must have a frequency above the threshold, o • number of photoelectrons increases with light intensity, but not the kinetic energy

9. Explanation of the photoelectric effect • Ephoton = hphoton • h = Planck’s constant = 6.626  10-34 J s • Applying the Law of the Conservation of Energy • energy of the photon is absorbed by the metal surface and is transferred to the photoelectron • the minimum frequency is the binding energy of the electron • the remaining energy shows up as the kinetic energy of the electron

10. Photoelectric effect • Electron kinetic energy = Photon energy - Binding energy • Ekinetic(electron) = h - ho • Comments • if frequency is too low, the photo energy is insufficient to overcome the binding energy of the electron • energy in excess of the binding energy shows up as the kinetic energy of the electron • increasing the intensity of the light increases the number of photons impacting on the metal

11. Particle properties of light • Light has a dual nature of acting like a wave and acting like a particle • The photoelectric effect confirmed that light occurs as little packets of energy • Light is still diffracted like a wave, has wavelength and frequency

12. Light and atoms • When matter absorbs photons of light, the energy of the photon is transferred to the matter • In the case of atoms, the absorption process yields information about the atom • Absorption of a photon transforms the atom to a higher energy state • All higher energy states are referred to as excited states • The most stable state is the ground state

13. Absorption and Emission • White light (light containing all energies of light) is passed through a sample • Sample absorbs some of the light • Light that passes through the sample is dispersed by a prism or other wavelength selecting device • Photodetector records the intensity of the light passing through the sample, which is then interpreted as absorption of light

14. Beer’s Law • Io = Intensity of incident light • I = Intensity of transmitted light •  = molar extinction coefficient • l = path length of cell • c = concentration of sample

15. UV Spectral Nomenclature

16. UV and Visible Spectroscopy • Vacuum UV or soft X-rays • 100 - 200 nm • Quartz, O2 and CO2 absorb strongly in this region • N2 purge good down to 180 nm • Quartz region • 200 – 350 nm • Source is D2 lamp • Visible region • 350 – 800 nm • Source is tungsten lamp

17. Emission • Sample is excited by light • Excited sample emits the light • Emitted light is wavelength selected • The light is detected by a photodetector • Plot of emission intensity vs wavelength is generated

18. Quantization of absorption and emission • One of the three things that led to quantum theory was that the absorption and emission of light occurred at discrete frequencies, not continua • Interpreted as the energy of the photon must match the difference in energy of two energy levels in the atom or molecule

19. Molecular process • Absorption and emission of visible and ultraviolet light • Photon is annihilated upon absorption, and the electrons in the molecule are rearranged into the excited state • Emission results from the conversion of excited electron energy being converted to a photon of light • Ephoton = Eatom

20. Energy level diagrams • Wiggle lines indicate radiative processes • Straight lines indicate nonradiative processes • Each energy level represents an arrangement of electrons in the atom

21. Properties of electrons • Each electrons have the same mass and charge • Electrons behave like magnets through a property called spin (actually, magnets are magnets because electrons have this property) • Electrons have wave properties (diffract just like photons)

22. Heisenberg uncertainty principle • A particle has a particular location, but a wave has no exact position • The wave properties of electrons cause them to spread out, hence the position of the electron cannot be precisely defined • They are referred to as being delocalized in a region of space • Heisenberg proposed that the motion and position of the particle-wave cannot be precisely known at the same time

23. Bound electrons and quantization • The properties of electrons bound to a nucleus can only take on certain specific values (most importantly, energy) • Absorption and emission spectra provide experimental values for the quantized energies of atomic electrons • Theory of quantum mechanics links these data to the wave characteristics of electrons bound to nuclei

24. The Schrödinger Equation • A second order partial differential equation • The solutions to such equations are other equations • These equations describe three-dimensional waves called orbitals • These solutions have indexes that are integers (the solutions are quantized naturally) • These indexes are called quantum numbers

25. Quantum numbers • n - principle quantum number • values of the positive integers • n = 1,2,3,… • l - azimuthal quantum number • values correlate with the number of preferred axes of a particular orbital, indicating its shape • l = 0,1,2,…(n - 1) • value of l is often indicated by a letter (s, p, d, f, for l = 0, 1, 2, 3)

26. Quantum number • ml - magnetic quantum number • directionality of orbital • ml = 0, ±1, ±2, ±l • ms - spin orientation quantum number • ms = ±½ • A complete description of an atomic electron requires a set of four unique quantum number that meet the restrictions of quantum mechanics

27. Shapes of atomic orbitals • Each atomic energy level can be associated with a specific three-dimensional atomic orbital • Orbitals are maps of the probability of the electron being in a particular location around the nucleus • While there are many representations, the most important to learn are the 90% probability volumes (which I will draw for you)

28. Depictions of orbitals • electron density plot - electron density plotted against the distance from the nucleus • orbital density plots • electron contour diagrams (90% probability drawings) • All are useful in helping us visualize the orbital

29. Waves and nodes

30. A variety of radial projections

31. Radial depictions

32. The p-orbitals

33. The d-orbitals

34. d-orbital radial projection