Quantum Mechanics of Alpha Decay

Quantum Mechanics of Alpha Decay Lulu Liu Partner: Pablo Solis December 5, 2007 8.13 Junior Lab Experiment #4

Classical Mechanics: What Do We Expect to See? • What is alpha decay? V(r) = ZZ e2 / r • r0 ~ fm, V(r0) is energy minimum • We see V(r0) > E • Less than energy min! • It happens at all! image from nu.phys.laurentian.ca

Quantum Tunneling • WKB Approximation T is transmission coefficient, R is radius of nucleus. derived in Yung-Kuo Lim (originally by Gamow) Geiger-Nuttall Law / Gamow Relation: image from hyperphysics.phy-astr.gsu.edu where  = 1/

Verifying the Geiger-Nuttall Law • Measure energy of emitted alphas • Radioactive Series and Bateman Equations • Equipment • Measure half-lives, 1/2 • Plot Ln(1/) vs. Z*E-1/2 (look for linear relation) • Errors • Conclusions

Naturally Occurring Radioactive Series

Bateman Equations • Governs time evolution • for A decays into B: • solve:

Can Detector to MCA Setup ... to MCA Decay chains start with Po

Rn-222 Half-Life Using Scintillator Assumption: Initially Pure Rn-222 Result: Equilibrium established in several hours

Plot of Rn-222 Activity Background ~1/s Accepted Value: 1/2 = 3.84 days Measured Value: 1/2 = 3.99 § 0.36 days

Energy Spectrum from Can Detector Calibrated to Po-212 alpha energy of 8.78 MeV

Evolution of Peaks E

Po-218 Half-Life - Method - Po-218/Bi-212/Rn-220 etc - Halt supply of Po atoms Po-218 - Integrate for 20s every minute • Assume constant background Po-212 • Po-212 (.3 s halflife) • daughter isotope of Bi-212 • Account for Bi-212 activity

Po-218 Half-Life Fit Accepted Value: 1/2 = 3.10 min Measured Value: 1/2 = 3.14 § 0.33 min

Bi-211 and Bi-212 Half-Lives • Initial Conditions: assume equilibrium dA/dt = dB/dt = dC/dt ... A, B, C are amounts of different isotopes in decay chain A/A = B/B = C/C follows from lab guide eq. 4.1 • Obtain ratios of isotope abundance. • Conduct Bateman analysis • decay under no voltage

Bi-212 Fit to Bateman Equations Po-215 -> Pb-211 -> Bi-211 Accepted Value: 1/2 = 1.01 hr Measured Value: 1/2 = 1.13 § 0.13 hr Bi-211

Geiger-Nuttall Fit

Errors • Half-Lives: statistical • Systematic Corrections: • background subtraction, bateman determinations • Additional Effects: • Lack of actual equilibrium in cans • Peak widening (degrading detectors)

Error- Continued Geiger-Nuttall Relation an approximation. Bismuth points Dependence on mass and atomic numbers, atomic radius Can be fit per decay chain, element, etc.

Conclusions • Geiger-Nuttall Law verified • Quantum mechanics offers explanation for alpha decay.

Po-218 Transient Behavior

Geiger-Nuttall Derivation Yung-Kuo Lim, 2000

Lack of Rise Time in Po-218 10 min

Comparing Parameters • m theoretical: -1.3 • m measured: -3.3

Quantum Mechanics of Alpha Decay

Quantum Mechanics of Alpha Decay

Presentation Transcript

Quantum Mechanics

Quantum tunnel effect and alpha-decay of nuclei

Quantum Mechanics

Quantum Mechanics

Quantum Mechanics

Alpha Decay

Alpha Decay

Alpha Decay basics

Principles of Quantum Mechanics What is Quantum Mechanics?

Quantum Mechanics

Quantum Mechanics

Quantum Mechanics

Alpha Decay

Alpha Decay 

Alpha Decay - Energy of alpha particle

Quantum Mechanics

ALPHA Decay

Quantum Mechanics

Quantum Mechanics

Quantum Mechanics

Quantum tunnel effect and alpha-decay of nuclei