1. summary Y. Akiba

5. sPHENIX/fsPEHNIX/ePHENIX sPHENIX/fsPHENIX/ePHENIX Jamie NaglesPHENIX physics overview John HaggertysPHENIX overivew Kenta Shigakihard probes ShinIchi EsumiSoft probes Xiaochun HeQuarkonia YAtracker/preshower John LajioeMPC-EX Yuji Gotofs/ePHENIX spin Joe SeelefsPHENIX detector eRHIC Abhay Deshpande ePHENIX LOI Kieran Boyle Jin Huang Itaru Nakagawa

6. Where we are

7. BaBar Solenoid Excellent foundation for sPHENIX and ePHENIX: inner radius 140 cm, length 385 cm, field 1.5 T Reduces technical risk associated with acquiring new superconducting research magnets Just moving to SLAC station A Soon to Brookhaven

8. 7/29/20138 sPHENIX

9. ePHENIX – built on the sPHENIX foundation

11. Lively discussion on “what is MUST in eRHIC/ePHENIX

12. Advance in theory QCD overview Tetsuo Hatsuda Lattice QCD Taku Izubuchi Spin Xiangdong JiDelta G Yoshitaka HottaDecomposition Yuji Koiketransverse spin QGP/CGC Theory Yukinao AkamatsuHeavy Flavor Yasushi NaraJet and flow Hirotsugu FujiiCGC and pA

13. Great advance in Lattice computation Realistic simulation  QGP properties and nucleon structure Izubuchi Much larger volume Clever and efficient algorithm Big computer Hatsuda

14. Advance in spin physics theory JiHatta Koike

15. QGP theory Akamatsu Nara Fujii

16. detector sPHENIX Detector/Simulation Eric MannealFEE/Test Beam Edward KistenevCalorimeter NagashimaG4 preshower XiaochunHe G4 calorimeter Detector technology Akira Yamamotosuperconducting magnet Yasuo AraiSOI pixel Youngil KwonSilicon at Korea Atsushi TaketaniSilicon for sPHENIX tracker

17. Progress/status of sPHENIX Detector Ed KistenevEric Mannel

18. sPHENIX simulation X. He Nagashima Preshower

19. Superconducting detector magenet A. Yamamoto J.Haggerty

20. Monolithic Detector having fine resolution of silicon and data processing power of CMOS LSI by using the FD-SOI Pixel Technology. SOI Pixel Detector (SOIPIX) 20 Y. Arai

21. 6 inch fabrication line 8 inch fabrication line R&D environment 1 cm 2 ~ $ 2 Possibility in Korea Y. Kwon

22. Non-PHENIX experiment Yuji Yamazakilow x physics at HERA/LHC Katsuo TokushukuHERA/ZEUS ToshiAki ShibataHermes, SeaQuest Yoshiyuji MiyachiCompass Hideki HamagakiAlice Yajun MaoCMS quarkonium KiyoshiTanidacharm baryon Nuclear Physics Experiment in Japan Hirokazu Tamura Nuclear Theory in Japan Masayuki Asakawa The time when PHENIX was born Shoji Nagamiya

23. ep collider experiment  ePHENIX Y. Yamazaki K. Tokushuku

24. ePHENIX Detector Concept Use BABAR magnet -1<  <1: – Keep sPHENIX EMCal and HCal – Add  -TPC and DIRC -4<  <-1: – Crystal calorimeter with good (2%) Energy resolution – GEM Trackers (+  -TPC) – No PID 1<  <4: – HCal (1<  <5) – EMCal PbSc restack? – GEM Trackers (+  - TPC) PID requires good resolution – Aerogel (1<  <~2) – RICH sPHENIX Upgrade Workfest--August 2, 201324 Next two talks: Tracking & Magnetic Field: Jin Huang PID: Itaru Nakagawa

26. Thank you!