Background: In $\pi^+n$ and $\pi^-p$ electroproduction, conventional models
cannot satisfactory explain the data above the resonance region, in particular
the transverse cross section. Although no high-energy L-T-separated
cross-section data is available to date, a similar scenario can be inferred for
$K^+\Lambda$ electroproduction.
  Purpose: Develop a phenomenological model for the $p(\gamma^*,K^+)\Lambda$
reaction at forward angles and high-energies. Propose a universal framework for
interpreting charged-kaon and charged-pion electroproduction above the
resonance region.
  Method: Guided by the recent model for charged-pion electroproduction,
developed by the authors, a framework for $K^+\Lambda$ electroproduction at
high energies and forward angles is constructed. To this end, a Reggeized
background model for $K^+\Lambda$ photoproduction is first developed. This
model is used as a starting base to set up an electroproduction framework.
  Results: The few available data of the unseparated $p(\gamma^*,K^+)\Lambda$
cross section are well explained by the model. Predictions for the
L-T-separation experiment planned with the 12 GeV upgrade at Jefferson Lab are
given. The newly-proposed framework predicts an increased magnitude for the
transverse structure function, similar to the situation in charged-pion
electroproduction.
  Conclusions: Within a hadronic framework featuring Reggeized background
amplitudes, $s$-channel resonance-parton effects can explain the observed
magnitude of the unseparated $p(\gamma^*,K^+)\Lambda$ cross section at high
energies and forward angles. Thereby, no hardening of the kaon electromagnetic
form factor is required.Comment: 9 pages, 7 figure

Nys, Jannes

Ryckebusch, Jan

Vrancx, Tom

English

arXiv

Tom Vrancx

Jan Ryckebusch

Jannes Nys

Crossref

Physical Review C

<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"><mml:mrow><mml:msup><mml:mi>K</mml:mi><mml:mo>+</mml:mo></mml:msup><mml:mi>Λ</mml:mi></mml:mrow></mml:math>electroproduction above the resonance region

Background: In π+ n and π− p electroproduction, conventional models cannot satisfactory explain the data above the resonance region, in particular the transverse cross section. Although no high-energy L-T-separated cross-section data is available to date, a similar scenario can be inferred for K+ Λ electroproduction.
Purpose: Develop a phenomenological model for the p(γ*,K+)Λ reaction at forward angles and high-energies. Propose a universal framework for interpreting charged-kaon and charged-pion electroproduction above the resonance region.
Method: Guided by the recent model for charged-pion electroproduction, developed by the authors, a framework for K+ Λ electroproduction at high energies and forward angles is constructed. To this end, a Reggeized background model for K+ Λ photoproduction is first developed. This model is used as a starting base to set up an electroproduction framework.
Results: The few available data of the unseparated p(γ*,K+)Λ cross section are well explained by the model. Predictions for the L-T-separation experiment planned with the 12 GeV upgrade at Jefferson Lab are given. The newly-proposed framework predicts an increased magnitude for the transverse structure function, similar to the situation in charged-pion electroproduction.
Conclusions: Within a hadronic framework featuring Reggeized background amplitudes, s-channel resonance-parton effects can explain the observed magnitude of the unseparated p(γ*,K+)Λ cross section at high energies and forward angles. Thereby, no hardening of the kaon electromagnetic form factor is required

Ghent University Academic Bibliography

K+ Λ electroproduction above the resonance region