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Where is the Electron Located? WHAT IS ENERGY? ABILITY TO DO WORK MEASURED IN JOULES (J) WORK: TO USE A FORCE TO MOVE AN OBJECT A DISTANCE FXd KINETIC: ENERGY DUE TO MOTION POTENTIAL: ENERGY DUE TO POSITION WHAT ARE THE DIFFERENT FORMS OF ENERGY? Law Of Conservation of Energy (also known as the First Law of Thermodynamics): Energy cannot be created or destroyed it merely changes form HEAT (THERMAL) ELECTROMAGNETIC CHEMICAL NUCLEAR MECHANICAL SOUND LIGHT (RADIANT) THE DUALITY OF LIGHT LIGHT IS A VIBRATION (WAVE) IN ELECTRIC AND MAGNETIC FIELDS THAT CAN TRAVEL ACROSS SPACE AS A PHOTON (PACKET OF ENERGY). IT IS PART OF THE ELECTROMAGNETIC SPECTRUM. LIGHT CAN BE REFLECTED, REFRACTED AND DIFFRACTED WAVE PROPERTIES WAVELENGTH (λ): DISTANCE BETWEEN TWO IDENTICAL POINTS ON A WAVE (METERS, m) FREQUENCY (ƒ): NUMBER OF WAVES THAT PASS A FIXED POINT IN A SECOND (HERTZ, Hz) SPEED OF LIGHT: c = ƒλ (3.00 X 108 m/s) Waves Albert Einstein Suggested that electromagnetic radiation can be viewed as a stream of particles called photons PHOTOELECTRIC EFFECT: Ejection of electrons from the surface of a metal or other material when high energy/frequency light shines on E =hƒ E = Energy H = Planck’s Constant(6.63 X 1034 J/s) f = Frequency Albert Einstein Developed the equation E = mc2 Energy has mass We can calculate the mass of a photon Arthur Compton Collided X-rays with electrons Showed that photons do exhibit the mass from Einstein’s equation Nature of Matter Max Planck – German physicist Experimented with energy Energy can be lost or gained only in whole-number multiples Energy is “quantized” Summary Energy is quantized Electromagnetic radiation exhibits wave-like and particle-like behavior Large pieces of matter mostly exhibit particle-like properties Tiny pieces, like photons, exhibit mostly wave-like Intermediate, like electrons, exhibit both The Bohr Model Developed a quantum model for hydrogen Electrons moved in circular orbits around the nucleus Equation that can be used to calculate the change in energy when an electron changes orbits: E = -2.178 X 10-18J (Z2/n2) n = an integer Z = nuclear charge BOHR’S ATOMIC THEORY HOW CAN A LINE SPECTRA IDENTIFYAN ELEMENT? LINE SPECTRUM: Shows only specific wavelengths of light (EM spectra) What are uses of line Spectra in technology? The Bohr Model Ground state – lowest possible energy state for an electron Suppose an electron in level n = 6 of an excited hydrogen atom falls back to level n = 1. Calculate the change in energy when this happens. ΔΕ = energy of final state – energy of initial state What is the wavelength of the emitted photon? E = -2.178 X 10-18J (Z2/n2) E =hƒ c = ƒλ (c = 3.00 X 108 m/s) The Quantum Mechanical Model Bohr’s equation only worked for hydrogen Heisenberg, de Broglie, and Schrodinger developed the theory behind our current model Schrodinger came up with a mathematical equation to describe the location of the electron A specific wave function = an orbital Led to the Heisenberg uncertainty principle and the exact speed of light (c) The Quantum Model of the Atom Heisenberg uncertainty principle: It is impossible to determine both the position and velocity of an electron or any other particle What is the Address of the Electron? Principle Quantum Number (n): Indicates the energy level occupied by an electron. Angular Momentum (l): Indicates the shape of the orbital (s,p,d,f,g) Atomic Numbers and Quantum Numbers Magnetic Quantum Number (m): Indicates the orientation of an orbital around the nucleus. Spin Quantum Number (↓↑): Indicates which way the electron is spinning Quantum Numbers Symbol What It Means Acceptable Values n Main energy level 1, 2, 3, 4, etc. l Orbital shape ml Space orientation -l…0…+l ms Electron spin 0, 1, 2,…n-1 +1/2 and -1/2 What are the Rules Governing Electron Configuration? Aufbau Principle: An electron occupies the lowest energy orbital available Pauli Exclusion Principle: Only two electrons per orbital and they must spin in opposite directions Hund’s Rule: Each orbital of equal energy must have one electron before a second electron is added Let’s Fill Up The Orbitals! Summary of Orbitals Principle Sublevels Quantum # 1 s Number of Number of Orbitals Electrons 1 2 2 s, p 3 8 3 s, p, d 5 18 4 s, p, d, f 7 32 Exceptions to Aufbau