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Lecture 8: Understanding the form factor 30/9/ Why is this a function of q 2 and not just q ? Famous and important result: the “Form Factor.

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Presentation on theme: "Lecture 8: Understanding the form factor 30/9/ Why is this a function of q 2 and not just q ? Famous and important result: the “Form Factor."— Presentation transcript:

1 16.451 Lecture 8: Understanding the form factor 30/9/2003 1 Why is this a function of q 2 and not just q ? Famous and important result: the “Form Factor Expansion”, derived as follows:

2 continued... but note the definition of the mean square charge radius: The first nontrivial term in the expansion is proportional to (details for homework! ) Think carefully: 1. This expansion only applies at small momentum transfer; it does not replace the exact result obtained by integration over the charge density explicitly. 2.The result is universal, independent of any details of  (r) except for the mean square charge radius. 3. We can use it to assess when “pointlike” behavior should be observed, and what q 2 range is necessary to observe details of the structure of the scattering object, e.g. for (1 - F(q 2 ) ) > 0.1, we require q 2 > 0.6/ Result: 2

3 continued.... To see the structure of a nucleus like 208 Pb, = (1.2 A 1/3 ) 2 = 50 fm 2, we need q 2   0.01 fm -2  400 (MeV/c) 2 For a proton, = 0.64 fm 2, we need q 2   1 fm -2  40,000 (MeV/c) 2 = 0.04 (GeV/c) 2 Since we know that q 2 is limited by the incident beam momentum, we need a much higher energy accelerator facility to map out the structure of the proton than to study heavy nuclei (e.g. SLAC experiment, data table shown in lecture 4, used beam energies in the range 5 – 21 GeV and scattering angles in the range 20° – 30° to map out the proton form factor at “large momentum transfer”...) Next: How does our cross-section formula change if proper relativistic quantum mechanics is used, so that we can correctly apply it to the proton? 3

4 Relativistic Formulation: spin ½ beam and target 1. Differential cross-section for scattering of spin-½ electrons from a pointlike (spin 0) target is given by the “Mott cross-section”, which is our result multiplied by cos 2 (  /2) and a “recoil factor” E’/E o fine structure constant,  : 2. In terms of the 4-momentum transfer, Q 2, the result for an extended spin ½ target, with both electric charge and magnetization distributions, is formulated in terms of electric and magnetic form factors: NB. Notation is from kinematics, lecture 5 4

5 Form factors of the proton: “Rosenbluth formula”: 5 proton Recall 4-momentum from lecture 5: invariant!!!

6 What does this mean? both electric and magnetic form factors contribute to the scattering to disentangle the two contributions, one has to compare measurements at the same Q 2 but different scattering angles  6 “Rosenbluth separation method”: Example: e-p scattering (q 2 = Q 2 here )

7 Electromagnetic form factors of the proton: Electric:Magnetic: Same shape!!! scaling relation: 7

8 Interpretation of the form factors: At Q 2 = 0, we have: G E (0) = 1 (pointlike limit, G E (0) = normalized electric charge) G M (0) =  p ( “ “, G M (0) = magnetic moment ) 8 1. Evaluated in the center-of-mass reference frame, with initial state 3-momenta which exactly reverse after the collision: The 4-momentum transfer is then: and the charge density is: (M/E ratio is for the proton) The magnetization density is obtained in a similar manner from G M 2.

9 Recent discovery – Jefferson Lab data (see US Long Range Plan, lecture 2) “ For more than 20 years it has been assumed, based on the available data, that the charge and magnetization distributions in the proton were proportional to one another (corresponding to µGe/Gm=1). New data from Jefferson Lab shows this is not true, and is leading to a re-examination of the dynamics governing the proton’s quark wavefunctions.” M. K. Jones, et al., Phys. Rev. Lett. 84, 1398 (2000), O. Gayou, et. al., Phys. Rev. Lett. 88, 092301 (2002) “ For more than 20 years it has been assumed, based on the available data, that the charge and magnetization distributions in the proton were proportional to one another (corresponding to µGe/Gm=1). New data from Jefferson Lab shows this is not true, and is leading to a re-examination of the dynamics governing the proton’s quark wavefunctions.” M. K. Jones, et al., Phys. Rev. Lett. 84, 1398 (2000), O. Gayou, et. al., Phys. Rev. Lett. 88, 092301 (2002) Old scaling law: µG E /G M =1 Jefferson Lab Research Highlights: http://www.jlab.org/highlights/nuclear/Nuclear.html (new, high precision data taken using an alternative technique, complementary to the Rosenbluth method.) (Various new theoretical predictions, colored lines 1.. 5) 9 systematic error limits

10 The proton: where are we? Electric charge distribution: charge and magnetization distributions are very similar both the form factors appear to follow a “dipole” pattern, e.g. new measurements from Jefferson Lab show that the charge and magnetization distributions are increasingly different at higher Q 2 for reasons that are not yet fully understood Next: the proton has excited states! 10

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