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Extracting neutron structure functions in the resonance region. Yonatan Kahn Northwestern University/JLab. Why are (new) extraction methods needed?. No free neutron targets – use light nuclei as effective targets EMC effect – nucleus not just a sum of free protons and neutrons!
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Extracting neutron structure functions in the resonance region Yonatan Kahn Northwestern University/JLab
Why are (new) extraction methods needed? • No free neutron targets – use light nuclei as effective targets • EMC effect – nucleus not just a sum of free protons and neutrons! • Previous extraction methods only reliable for positive-definite functions
Difficulties in the resonance region Fermi motion smears out resonance structure Is it possible to reconstruct full resonance structure of neutron structure functions from nuclear data?
Nuclear structure functions • Impulse approximation – virtual photon interacts with single nucleon inside nucleus • Can write nuclear structure functions as convolutions of nucleon structure functions: smearing functions S. Kulagin and R. Petti, Nucl. Phys. A 765(126), 2006; S. Kulagin and W. Melnitchouk, Phys. Rev. C77:015210, 2008
Smearing functions f(y, γ) • Can be calculated from nuclear wavefunction • parameterizes finite-Q2 effects; for most kinematics, γ ≤ 2 • For γ = 1, interpret as nucleon light-cone momentum distributions • Note sharp peak at y=1, similar shapes for f0 and fij
Effective smeared neutron function • Subtract known proton contribution: (For brevity, ) • Goal: extract neutron function from under the integral • (F = F2, xg1,2) (Note: system of 2 coupled equations for spin-dependent functions)
Extraction method – direct solution • Need to solve an integral equation for single-variable function F(x) at fixed Q2 • Can put into standard form: • This equation can be discretized, and solved by matrix inversion:
Extraction method – direct solution • However, kernel vanishes on diagonal, so matrix is singular and inversion fails • Strong physical reasons: single nucleon has vanishing probability of carrying entire momentum of nucleus • In particular, no existence/uniqueness theorems for this kind of integral equation • may be several free neutron functions that all give the same smeared neutron function… This method fails because the smearing functions are sharply peaked
Iterative extraction method for F2n • Need to solve for F2n(x) at fixed Q2 • Write → takes advantage of sharply peaked form of f0: δis small • Treat δ(x) as a perturbation, solve iteratively with a first guess F2n(0) → Note: Because convolution involves f (y) F2n(x/y),F2n(i+1) depends on F2n(i)all the way up to x = 1, especially at large x YK, W. Melnitchouk, S. Kulagin, arXiv:0809.4308; to appear in Phys. Rev. C
Iterative extraction method for xgn1,2 • Solve system of equations: • Can ignore off-diagonal contributions, since f12 and f21 are so small • In this approximation, extraction procedure same as for F2 Simulated xg1,2d looks identical with or without off-diagonal terms
Convergence of extraction method • Create deuteron “data” by smearing p and n parameterizations, try to recover input function • Initial guesses: F2n(1) = 0, xg1n(1) = 0 (not a great first guess!) Nearly perfect convergence after 30 iterations, despite initial guess! (But don’t really need 30 iterations in practice)
Comparison with smearing-factor method • Instead of assuming an additive correction, can assume a multiplicative “smearing factor”: • Works fine for positive-definite functions, but can diverge for spin-dependent functions, while our method has no such problems divergences
Dependence on initial guess → Eventual convergence regardless of initial guess, but resonance peaks converge quicker when first guess is better
Estimating errors same size as deuteron error bars! • Vary deuteron data points by Gaussians (ignore proton errors, since smeared) • Run 50 sample extractions, calculate RMS error on neutron function
F2n extraction from data (1 iteration) (preliminary) Data: Hall C experiment E00116 (S. Malace)
F2n extraction from data (2 iterations) (preliminary) Data: Hall C experiment E00116 (S. Malace)
F2n extraction from data (2 iterations) (preliminary) Errors have grown after two iterations More structure visible Data: Hall C experiment E00116 (S. Malace)
F2n extraction from data (5 iterations) (preliminary) Convergence with two different initial guesses, but error bars are quite large Data: Hall C experiment E00116 (S. Malace)
gn1,2 extraction from 3He data (1 iteration) Sparse data points + bumpy input function → large errors! PRELIMINARY Data: Hall A experiment E01-012 (P. Solvignon)
xg1n extraction from CLAS deuteron data PRELIMINARY Data: S. Kuhn, N. Guler
Limitations of extraction method • Discontinuities in input data are sharply magnified in output – worse for sparse data sets • Error bars grow after each iteration, so convergence after 10 iterations not practical • Some dependence on initial guess (faster convergence with a better first guess, so smaller errors) • Method currently limited to convolution representation of nuclear structure functions • Needs to be extended for off-shell effects (done), final-state interactions (more difficult) • Quasi-elastic peak can provide constraints on convolution model
Open questions • How to address dependence on initial guess and eventual convergence? • Better ways to estimate errors on extracted neutron structure function? • Best way to deal with sparse data?
Error tests (2) 1 iteration, calculate errors by shifting whole curve up or down by error bars
Quasi-elastic model Data: CLAS experiments E1D, E6A. Note: not LT-separated
F2n at low Q2 Data: CLAS experiments E1D, E6A. Note: not LT-separated