1. Medium-induced jet flavor conversion in e+A
Wei-Tian Deng (邓维天)
in collaboration with
Ning-Bo Chang (畅宁波)， Xin-Nian Wang (王新年)

2. Semi-Inclusive Deeply Inelastic Scattering
Jet Produced in Medium
Heavy Ion collisions
Jet (hard probe) created by parton scattering with large pT.
——penetrate QGP
——Jet quenching
Semi-Inclusive Deeply Inelastic Scattering
Struck quark with large virtuality
——travel through the remnant of large nucleus.
——Jet energy loss

3. Medium Induced gluon radiation
Medium modified Frag Function
Hard parton travel through QCD medium
Suffer multiple parton scattering
The accepted explanation for Jet Quenching
Induced gluon radiation
Reduce the energy and virtuality

4. Medium Induced q-qbar Pair Production
Medium modified Frag Function
Hard parton travel through QCD medium
Suffer multiple parton scattering
The accepted explanation for Jet Quenching
Induced q-qbar pair production
Induced gluon radiation
Change final hadron flavor composition
Reduce the energy and virtuality

5. High-twist model medium modified fragmentation function (mFF):
medium-modified DGLAP (mDGLAP):
X. F. Guo and X. N. Wang
Phys. Rev. Lett. 85, 3591(2000)
B. W. Zhang and X. N. Wang
Nucl. Phys. A 720, 429 (2003)
numerically
N. B. Chang, WTD, X. N. Wang
Phys.Rev. C89 (2014) 3,
The flavor of initial quark could be converted to others

6. Encode nuclear geometry:1,
Woods-Saxon 2,
Medium modification factor in e+A:
Compare with HERMES data

7. Extract parameter from Jet energy loss
Extract parameter value:

8. Jet flavor conversion Vacuum FF
To get clear signal of flavor conversion
Consitituent quarks (ubar, s) of K- are not any valence quarks (u, d) in target nucleus
Vacuum FF
At intermediate and large z region, the FF to K- is dominated by its consitituent quarks (ubar, s)
The FF of (u, d …) fall off exponentially at large z.
The ratio is sensitive to flavor conversion

9. Ratio of Final effective mFF/Vacuum FF
At intermediate z, the mFF’s are all suppressed due to energy loss.
At small z, mFF’s are all enhanced due to soft gluon and pair production.
At large z:
the mFF of initial struck (ubar, s) are suppressed due to energy loss.
But for initial struck (u, d …) quarks, there is an enhancement due to flavor conversion.
N. B. Chang, WTD, X. N. Wang
Phys.Rev. C92 (2015) no.5,

10. To test the sensitivity of K- to the flavor conversion, we choose two xB regions:
Moderate xB region ~0.1
Large xB region ~0.5
Valence+Sea quarks
Only Valence quarks

11. N. B. Chang, WTD, X. N. Wang
Phys.Rev. C92 (2015) no.5,
At moderate xB ~0.1
Both valence quarks and sea quarks are struck as initial jet.
flatter than K+
Comes from the competition of :
Enhancement of (u, d) quarks
Suppression of (ubar, s) quarks

12. The evidence in HERMES In HERMES data, its xB value is about xB~0.1
HERMES data shows already a relative rise of K- spectra compare to K+ at large z.

13. At large xB ~0.5 Only valence quarks are struck as initial jet.
N. B. Chang, WTD, X. N. Wang
Phys.Rev. C92 (2015) no.5,
At large xB ~0.5
Only valence quarks are struck as initial jet.
Large enhancement
Comes only from:
The enhancement of (u, d) quarks

14. Prediction of Enhancement
Not obvious
Clear enhancement
Compare to proton

15. Summary and Outlook
nuclear modification factor for K- in e+A at large z is very sensitive to medium induced flavor conversion.
Beside energy loss, flavor conversion is another independent probe of the properties of nuclear medium.
To understand the flavor substructure of jet in hot medium

16. Thank you!

18. As a function of Q2:
X. F. Guo, Phys. Rev. D58,114033(1998)

19. Results with DSS for K