Physics D Lecture Slides Lecture 15: Feb nd 005 Vivek Sharma UCSD Physics Where are the electrons inside the atom? Early Thought: Plum pudding model Atom has a homogenous distribution of Positive charge with electrons embedded in them (atom is neutral) e - e - e - e e- - e - e - e - e - e - e - e - e - e - e - e - e - e - e - Positively charged matter or? How to test these hypotheses? Shoot bullets at the atom and watch their trajectory. What Kind of bullets? + Core Indestructible charged bullets Ionized He ++ atom = α ++ particles Q = +e, Mass M α =4amu >> m e, V α = x 10 7 m/s (non-relavistic) [charged to probe charge & mass distribution inside atom] + 1
Plum Pudding Model of Atom Non-relativistic mechanics (V α /c = 0.1) In Plum-pudding model, α-rays hardly scatter because Positive charge distributed over size of atom (10-10 m) M α >> M e (like moving truck hits a bicycle) predict α-rays will pass thru array of atoms with little scatter (~1 o ) Need to test this hypothesis Ernest Rutherford Probing Within an Atom with α Particles Most α particles pass thru gold foil with nary a deflection SOME ( 10-4 ) scatter at LARGE angles Φ Even fewer scatter almost backwards Why
Rutherford Discovers Nucleus (Nobel Prize) Rutherford Scattering discovered by his PhD Student (Marsden) 3
Force on α-particle due to heavy Nucleus Outside radius r =R, F Q/r Inside radius r < R, F q/r = Qr/R Maximum force at radius r = R! particle trajectory is hyperbolic Scattering angle is related to impact par. # kq Q $ # " $ = % & % & ' ( ' (! Impact Parameter b cot m! v! Rutherford Scattering: Prediction and Experimental Result # n = 4 k Z e NnA $ 1 % 4!! " 4 R & m v ' Sin ( / ) ( ) # scattered Vs φ depends on : n = # of incident alpha particles N = # of nuclei/area of foil Ze = Nuclear charge K α of incident alpha beam A= detector area 4
Rutherford Scattering & Size of Nucleus nucleus nucleus distance of closest appoach # r size of nucleus 1 Kinetic energy of! = K! = m! v"! particle will penetrate thru a radius r until all its kinetic energy is used up to do work AGAINST the Coulomb potential of the Nucleus: 1 m v MeV = k K! =! " = 8 % kze r = K For K =7.7.MeV, Z = 13! kze % r = K Size of Nucleus = 10!! Size of Atom = 10-10 -15 Al = 4.9& 10 m m ( Ze)( e) r $ 15 m Dimension Matters! Size of Nucleus = 10 Size of Atom = 10-10 -15 m m how are the electrons located inside an atom How are they held in a stable fashion necessary condition for us to exist! All these discoveries will require new experiments and observations 5
Rutherford Atom & Classical Physics? Continuous & Discrete spectra of Elements 6
Visible Spectrum of Sun Through a Prism Emission & Absorption Line Spectra of Elements 7
Kirchhoff Experiment : D Lines in Na D lines darken noticeably when Sodium vapor introduced Between slit and prism Emission & Absorption Line Spectrum of Elements Emission line appear dark because of photographic exposure Absorption spectrum of Na While light passed thru Na vapor is absorbed at specific λ 8
Spectral Observations : series of lines with a pattern Empirical observation (by trial & error) All these series can be summarized in a simple formula 1 $ 1 1 % = R ", n f > ni, ni = 1,,3, 4..! & n f n ' ( i ) Fitting to spectral line series data R= 1.09737 # 10 m 7 " 1 How does one explain this? The Rapidly Vanishing Atom: A Classical Disaster! Not too hard to draw analogy with dynamics under another Central Force Think of the Gravitational Force between two objects and their circular orbits. Perhaps the electron rotates around the Nucleus and is bound by their electrical charge M1M Q1Q F= G! k r r Laws of E&M destroy this equivalent picture : Why? 9
Bohr s Bold Model of Atom: Semi Quantum/Classical -e 1. Electron in circular orbit m e around proton with vel=v. Only stationary orbits allowed. Electron does not F V radiate when in these stable +e (stationary) orbits 3. Orbits quantized: r e U ( r) =! k r 1 KE = m v e M e v r = n h/π (n=1,,3 ) 4. Radiation emitted when electron jumps from a stable orbit of higher energy stable orbit of lower energy E f -E i = hf =hc/λ 5. Energy change quantized f = frequency of radiation General Two body Motion under a central force Reduced Mass of -body system +e F -e m e V reduces to r m e Both Nucleus & e - revolve around their common center of mass (CM) Such a system is equivalent to single particle of reduced mass µ that revolves around position of Nucleus at a distance of (e - -N) separation µ= (m e M)/(m e +M), when M>>m, µ=m (Hydrogen atom) Νot so when calculating Muon (m µ = 07 m e ) or equal mass charges rotating around each other (similar to what you saw in gravitation) 10
Allowed Energy Levels & Orbit Radii in Bohr Model 1 e E=KE+U = mev! k r Force Equality for Stable Orbit " Coulomb attraction = CP Force e k r mev e " KE = = k r e Total Energy E = KE+U= - k r Negative E " Bound system This much energy must be added to the system to break up the bound atom mev = r Radius of Electron Orbit : mvr = n! n! " v =, mr 1 ke substitute in KE= mev = r n! " rn =, n = 1,,... # mke n = 1" Bohr Radius a 1!! 10 a0 = = 0.59$ 10 m mke In ge = = # neral rn n a0; n 1,,... Quantized orbits of rotation 0 Energy Level Diagram and Atomic Transitions " ke En = K + U = r since r = a n,n =quantum number n 0 Interstate transition: n 0 " ke 13.6 En = = " ev, n = 1,,3.. # a n n + E = hf = E " E i f i * n " ke $ 1 1 % = " a & 0 ni n ' ( f ) ke $ 1 1 % f = " ha & 0 n f n ' ( i ) 1 f ke $ 1 1 % = = "! c hca & 0 ( n f n ' i ) $ 1 1 % = R " & n f n ' ( i ) f 11
Hydrogen Spectrum: as explained by Bohr E n! ke " Z = #$ % & a0 ' n Bohr s R same as the Rydberg Constant R derived emperically from photographs of the spectral series Another Look at the Energy levels E n! ke " Z = #$ % & a0 ' n Rydberg Constant 1
Bohr s Atom: Emission & Absorption Spectra photon photon Some Notes About Bohr Like Atoms Ground state of Hydrogen atom (n=1) E 0 = -13.6 ev Method for calculating energy levels etc applies to all Hydrogenlike atoms -1e around +Ze Examples : He +, Li ++ Energy levels would be different if replace electron with Muons Bohr s method can be applied in general to all systems under a central force (e.g. gravitational instead of Coulombic) Q Q M M If change U ( r) = k! G r r Changes every thing: E, r, f etc 1 1 "Importance of constants in your life" 13
Bohr s Correspondence Principle It now appears that there are two different worlds with different laws of physics governing them The macroscopic world The microscopic world How does one transcend from one world to the other? Bohr s correspondence Principle predictions of quantum theory must correspond to predictions of the classical physics in the regime of sizes where classical physics is known to hold. when n [Quantum Physics] = [Classical Physics] 14