Transcript EMR info
EMR info Waves, light, and energy: Where chemistry and physics collide http://imagers.gsfc.nasa.gov/ems/waves3.html Before we get started…. 1. What is light? 1. 2. 2. List as many interactions of light and matter as you can. 3. Is it matter? What forms of light exist? think how light changes matter, and how matter changes light What are some uses of light? First things first: Waves a and b represent different wavelengths (λ)- the distance of a wave from crest to successive crest; measured in meters http://www.lbl.gov/MicroWorlds/ALSTool/EMSpec/EMSpec.html Waves: amplitude The height of a wave from crest to midline or trough to midline; measured in meters Terms you need to know: Wavelength (λ) Amplitude Frequency (ⱱ) ; I know some of you have used f, move on and get with chemistry! :) the number of cycles (oscillations) per second measured in cycles per second (s-1) or Hz (Hertz) Waves on a string http://www.lbl.gov/MicroWorlds/ALSTool/EMSpec/EMSpec2.html http://micro.magnet.fsu.edu/primer/lightandcolor/images/electromagneticfigure1.jpg http://lepus.physics.ualr.edu/~tahall/EXAM2/emspec.jpg http://www.arpansa.gov.au/images/emsline2.gif Visible Light color Violet Indigo Blue Green Yellow Orange Red wavelength(nm) 400---460 460---475 475---490 490---565 565---575 575---600 600---800 ⱱ (*1014 Hz) 7.5--6.5 6.5--6.3 6.3--6.1 6.1--5.3 5.3--5.2 5.2--5.0 5.0--3.7 Energy (*10-19 J) 5.0--4.3 4.3--4.2 4.2--4.1 4.1--3.5 3.5--3.45 3.45--3.3 3.3--2.5 Some equations you need to know = c / ⱱ and E = hⱱ So…. E = hc / And… = h / mv* When • = wavelength in m • c = speed of light, 3.00E8 m/s • ⱱ (nu)= frequency in Hz •(cycles/sec or s-1 or 1/s) •E= energy in J •h= Planck’s constant, 6.626E-34 J*s [Joule(seconds)] •m= mass of particle in kg •V*= velocity in m/s What the h? Planck’s Constant When metals are heated, they glow 1800s- physicists were trying to determine the relationship between the color (wavelength) and intensity of the glow Max Planck (1900)- energy can be released or absorbed only in little chunks (packets) of energy “of some minimal size” Max Planck and the h The chunks of energy were dubbed “quantum” (“fixed amount”), which is the smallest amount that can be emitted or absorbed as EMR. Proposed: E = hⱱ The energy (E) of a single quantum is equal to its frequency (ν) times a constant Planck and the Nobel (Physics) Planck determined that h= 6.626E-34 J-s Energy is always released in multiples of hv (1hv, 2hv, 3hv, etc) h is so small that we cannot see the effects of this in our daily lives Analogous to… Planck won the 1918 Nobel Prize in physics for his work Einstein & Bohr: Perfect Together Einstein, left Bohr, above Einstein: The Photoelectric Effect Einstein discovered that one could cause electrons to be ejected from the surface of a metal if the energy of the light wave was strong enough He treated the light needed to do this as a piece of matter- a photon, if you will This ejection of eis the photoelectric effect The Photoelectric Effect Only light of a certain energy could knock off an electron from the metal Intense light of a weaker wavelength would not work, but even a low intensity of the correct wavelength would work (the energy of the light is transferred to the kinetic energy of the electron) Hmmm… light acting as a particle and as a wave….. The photoelectric effect… Online animations PhET http://www.lewport.wnyric.org/mgagnon/P hotoelectric_Effect/photoelectriceffect1.ht m http://www.xmission.com/~locutus/applet s/Photoelectric.html Getting to Bohr…. Light of a given wavelength is monochromatic (one color) Most common EMR sources are polychromatic, but we see only one color These can be reduced to a spectrum when the different wavelengths are separated out Spectral Emissions Continuous spectrum: shows all colors of the rainbow Bright line spectrum: only certain wavelengths are visible (the rest do not appear at all) Different elements have different bright line spectrum when they are heated Na is yellow Ne is orange-red Line spectrum Ne I2 http://www.cartage.org.lb/en/themes/Sciences/Astronomy/Modenastronomy/Interactionoflight/AtomicAbsorption/AtomicAbsorption.htm Hydrogen Spectra Emission Spectra Absorption Spectra http://www.mhhe.com/physsci/astronomy/applets/Bohr/content_files/section1.html http://www.cartage.org.lb/en/themes/Sciences/Astronomy/Modenastronomy/Interactionoflight/AtomicAbsorption/AtomicAbsorption.htm Color and what you see: Absorption: the wavelengths that are absorbed by an object are not available for us to see, as we see the wavelengths of light that are reflected off of an object This is not the same as those wavelengths that are emitted by an object that is emitting radiant energy. Color and what you see… Chlorophyll absorption spectra Perception of color Line spectra formation- go to….. http://www.mhhe.com/physsci/chemistr y/essentialchemistry/flash/linesp16.swf http://www.mhhe.com/physsci/chemistr y/animations/chang_7e_esp/pem1s3_ 1.swf Bohr Model and Spectral Emissions Bohr proposed that the emission of light energy from an (electrically or thermally) excited atom corresponds to the orbit of the electron around the nucleus of the atom That energy can only be achieved by being a specific distance from the nucleus What you’ve seen so far…. Model of an Iodine atom (atomic number =53) Bohr Model and moving electrons http://www.colorad o.edu/physics/2000 /quantumzone/bohr .html Energy levels- Bohr Model Electrons travel within set energy levels that have a particular energy associated with each level After all, the e-s are moving around the nucleus think KE here Each shell has a number Closest to the nucleus is n=1 For each successive level add 1 to n n=2, n=3, ect…. Energy increases as the distance from the nucleus increases Bohr Model and moving electrons http://www.color ado.edu/physic s/2000/quantu mzone/bohr.ht ml Electron config in energy level SO… We know that the e-’s are free to move around the nucleus They also can move from one energy level to the next (and fall) back when energy is added Move from ground state (“home” level) to a higher level (the “excited” state) Returning back to the ground state releases energy This emission is how we see colors: the wavelengths of EMR released from an atom when it has been excited by Heat energy Electrical energy Chemical energy Think glowing red hot metal, or fireworks Determining Energy for n To determine the energy for a given energy level, use the equation: En=(-RH)(Z/n2) RH = 2.18E-18J, Z= the atomic number of the atom n=1, 2, 3, 4…. So En=(-2.18E-18J)(Z/n2) To determine E emitted or absorbed: To determine the change in energy for a given energy transition: ΔE=Ef-Ei *Remember E=hⱱ, so ΔE=hⱱ so ΔE=[(-2.18E-18J)(Z/n2)]f- [(-2.18E-18J)(Z/n2)]i Remember that + values mean E that is absorbed, and – values mean released E changes continued *Remember E=hν, so ΔE=hⱱ to get the frequency of the light emitted or absorbed If ΔE is positive since Ef >Ei E is absorbed The e- was going from ground state to an excited state If ΔE is negative since Ef < Ei E is released The e- was going to ground state from an excited state To determine E emitted or absorbed: What is the change in energy associated with an electron dropping from n=5 to n=1 in a Hydrogen atom? ΔE=Ef-Ei so ΔE=[(-2.18E-18J)(Z/n2)]f- [(-2.18E-18J)(Z/n2)]i ΔE=[(-2.18E-18J)(1/12)]f- [(-2.18E-18J)(1/52)]I ΔE = -2.09E-18 J Which means 2.09E-18J are released Makes sense; an e- is dropping from 5 to1, E is released when e- drop Back to basics EMR calcs… That released Energy can be used to determine the wavelength and frequency of the EMR emitted. Remember that you need to treat the energy as positive to do this! The sign only gives direction of energy flow There is no negative energy, only energy leaving If you used – energy, you’d get a - or -ⱱ This isn’t possible! Also…life after Einstein and Bohr We know that electrons have characteristics of both light (waves) and matter, so we say that they have a dual nature De Broglie De Broglie proposed that an electron moving about the nucleus had a wave-like behavior, so it has a particular wavelength associated with it. This wavelength depends upon the mass and velocity of the electron. = h / mv mv = the momentum of the particle Mass* velocity = p momentum = p so therefore = h / p p = mv This matter-wave idea applies to all matter, not just to electrons However, the mass is so large, and the wavelength so small, that we cannot see it in macroscale objects This matter-wave theory led to applications like the electron microscope Scanning electron microscope image of a leaf from a Black Walnut tree. Image shows a cross-section of a cut leaf, itsupper epidermal layer, mesophyll layer with palisade cells and vascular bundles, and lower epidermal layer. The protrusion at center is just over 50 microns tall. (Dartmouth Electron Microscope Facility/Dartmouth College)# Pollen from a variety of common plants: sunflower, morning glory, hollyhock, lily, primrose and caster bean. The largest one at center is nearly 100 microns wide. (Dartmouth Electron Microscope Facility/Dartmouth College) # De Broglie wavelength Heisenberg: The Uncertainty Principle We can’t determine information about small scale objects the same way we can for large scale objects Case in point: a ball rolling down a rampwe can get position, direction, and speed at the same time We can’t for electrons Hence, the uncertainty principle Heisenberg, cont’d It is inherently impossible for us to simultaneously know both the exact momentum and exact location of an electron This is because anything we do to determine the location or momentum of the electron moves it from its original path and location; this can’t be reduced past a certain minimal level We can know only momentum or location- not both We can talk probability of the location/ momentum of an electron Which brings us to this question: What the heck does all of this have to do with electron configuration and how matter behaves? On to electron configuration, courtesy of Schrödinger and company (enter math that we’ll skip) Quantum theory