Atoms, Ions and Molecules The Building Blocks of Matter Chapter 2 1
Chapter Outline 2.1 The Rutherford Model of Atomic Structure 2.2 Nuclides and Their Symbols 2.3 Navigating the Periodic Table 2.4 The Masses of Atoms, Ions, and Molecules 2.5 Moles and Molar Mass 2.6 Making Elements 2.7 Artificial Nuclides Experiments in Atomic Structure J. J. Thompson (1906 Nobel Prize in Physics) - cathode ray tube experiments; discovery of the electron; measurement of the charge-to-mass ratio. Robert Millikan (1923 Nobel Prize in Physics) - oil-drop experiments; measured the mass of the electron, therefore calculate the charge Ernest Rutherford (1908 Nobel Prize in Physics) - gold-foil experiments; the nuclear atom James Chadwick (1935 Nobel Prize in Physics) - discovery of the neutron 2
J.J. Thomson Cathode Ray Tube Experiments - Electrons Results of Cathode Ray Experiments Travel in straight lines invisible independent of cathode composition bend in a magnetic field like a negatively-charged particle would charge/mass = -1.76 x 10 8 C/g 3
Thompson s Plum Pudding Model of the Atom electrons distributed throughout a diffuse, positively charged sphere. Robert Millikan s oil drop Experiment - measured the mass of the electron 4
Millikan s Results The air molecules in the chamber were ionized by a beam of X-rays, producing electrons and positively-charged fragments Fine mist of oil introduced into chamber; electrons adhere to the droplets Negatively-charged droplets settle to bottom of chamber under influence of gravity Charged repeller plates adjusted until droplets were suspended in mid-air From the physics and knowledge of the size of the gravitational and electrostatic forces, the charge on each droplet could be calculated Discovered that each droplet was a whole-number multiple of 1.60 X 10-19 C, so the mass = 9.11 X 10-28 g Radioactivity and the Nuclear Atom Spontaneous emission of particles and/or radiation from a decaying, unstable nucleus -particles = -particles = -rays = 5
Ernest Rutherford - the nuclear atom 6
Rutherford's Observations b) Expected results from plum pudding model. c) Actual results. 1. the majority of particles penetrated undeflected 2. some particles were deflected at small angles 3. occasionally -particles scattered back at large angles Rutherford s Conclusions The atom is mainly empty space because most of the -particles passed through undeflected The nucleus is very dense and positively charged because some of the -particles were repulsed and deflected Electrons occupy the space around the nucleus The atom is electrically neutral 7
Rutherford s Model of the Atom atomic radius ~ 100 pm = 1 x 10-10 m nuclear radius ~ 5 x 10-3 pm = 5 x 10-15 m If the nucleus was the size of an orange, then the radius of the atom would be 2.5 miles mass p mass n = 1840 x mass e - 8
Chapter Outline 2.1 The Rutherford Model of Atomic Structure 2.2 Nuclides and Their Symbols 2.3 Navigating the Periodic Table 2.4 The Masses of Atoms, Ions, and Molecules 2.5 Moles and Molar Mass 2.6 Making Elements 2.7 Artificial Nuclides Atomic Mass Units Atomic Mass Units (amu) Comprise a relative scale to express the masses of atoms and subatomic particles. Scale is based on the mass of 1 atom of carbon:» 6 protons + 6 neutrons = 12 amu. 1 amu = 1 Dalton (Da) 9
Isotopes: Experimental Evidence Atomic number (Z) = number of protons in nucleus Mass number (A) = number of protons + number of neutrons = atomic number (Z) + number of neutrons Isotopes (nuclides) are atoms of the same element (X) with different numbers of neutrons in the nucleus Mass Number Atomic Number A ZX Element Symbol 1 H 2 1 1H (D) 1H (T) 3 238 92 U 92 U 235 10
Practice: Isotopic Symbols Use the format A X to write the symbol for the nuclides having 28 protons and 31 neutrons. Collect and Organize: Analyze: Solve: Think about It: Practice: Identifying Atoms and Ions Complete the missing information in the table. Collect and Organize: Analyze: Solve: Think about It: 11
Chapter Outline 2.1 The Rutherford Model of Atomic Structure 2.2 Nuclides and Their Symbols 2.3 Navigating the Periodic Table 2.4 The Masses of Atoms, Ions, and Molecules 2.5 Moles and Molar Mass 2.6 Making Elements 2.7 Artificial Nuclides The Periodic Table of the Elements Mendeleev s Periodic Table Dmitrii Mendeleev (1872): Ordered elements by atomic mass. Arranged elements in columns based on similar chemical and physical properties. Left open spaces in the table for elements not yet discovered. 12
The Modern Periodic Table Also based on a classification of elements in terms of their physical and chemical properties. Horizontal rows: called periods (1 7). Columns: contain elements of the same family or group (1 18). Several groups have names as well as numbers. Navigating the Modern Periodic Table Groups and Families 13
1/10/2014 Groups of Elements (cont.) 14
These 7 elements occur naturally as diatomics (memorize) - H 2 N 2 F 2 O 2 I 2 Cl 2 Br 2 Metals found to the left of the diagonal line lose electrons in chemical reactions solids (except for Hg, Cs, and Fr) conduct electricity ductile (draw into a wire) malleable (roll into sheets) form alloys ("solid-solution" of one metal in another) 15
Nonmetals found to the right of the diagonal line like to gain electrons from metals, or share electrons among themselves found as solids, liquids (Br), and gases (Inert gases, H, N, O, F, Cl) diatomics - H 2, N 2, F 2, O 2,I 2, Cl 2, Br 2 oxygen also exist as ozone, O 3 insulators (except for graphite or C) Helium-Neon lasers Metalloids elements next to the diagonal line B, Si, Ge, As, Sb, and Te physical properties of a metal (can be convinced to conduct electricity) and chemical properties of a nonmetal Elemental Si is used in the semiconductor industry 16