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1 TOF ENMA JAEA-RMS)

2 TOF Pre-scission JAERI-RMS (m-state

3 16 O + 27 Al 150MeV d TOF Nucl. Phys. A444, (1985).

4 l = m d

5 Pre-scission Scission 10-19

6 (Post_scission) (Pre-scission) Proton_fission Alpha_fission F 1,F 2 : Fission counters 1,2,3,4: E-E telescopes 19 F+ 181 Ta 146MeV Phys. Rev. C42, (1990).

7 Multiplicity Pre-scission proton Pre-scission alpha Multiplicity Phys. Rev. C46, (1992).

8 T charged fission particles sec T neutron fission sec

9 JAERI-RMS 300

10 JAERI-RMS Detector ED2 RotatingTarget Booster ED1 MD Nucl. Instr. and Meth. A376, (1996) Beams New isotopes 209 Th, 212 Pa, New isomer 217 Pa, alpha decay 213 Ra ED1

11 Z p Z t >1800 DIC Quasi-fission

12 R) R < Position of saddle point R saddle side R tip R side R<R saddle R>R saddle R tip Distance between mass center r/r Moller and Nix R tip R side : 4 He, 2: 12 C, 3: 16 O, 4: 28 Si, 5: 32 S, 6: 40 Ar 7: 60 Ni, 8: 76 Ge, 9: 82 Se, 10: 86 Kr Cohen and Swiatecki A Z Sm 76 Ge+ 150 Nd 40 Ar+ 180 Hf Fissility 60 Ni+ 154 Sm 76 Ge+ 150 Nd

13 Excitation energy MeV) Cross sections (mb) Ni Sm Calc. 216 Th (xn) data 215 Th V(MeV) Collision angle (deg.) 214,213 Th 212,211 Th E cm (MeV) Phys. Rev. C62, (2000)

14 Zn Pb 82 Se 138 Ba Se 134 Ba 78 P. MÖller et al., Z. Phys. A359(1997)251

15 Cross section (mb) E ex (MeV) Th+ 215 Ra 216 Th Th n 218 Th+ 214 Ra n n Th 3n 2n 218 Th Se Ba 3n2p E CM (MeV) 4n 5n 6n+ 7n 215 Th 213 Th+ 214 Th 214 Th 213 Th Phys. Rev. C 65, (2002) Cross section (mb) E ex (MeV) Th (1n) 215 Ac (1p) Th (2n+3n) n 2n 3n 214 Th 213 Th Th (4n+5n) 212 Th 211 Th Se Ba 1p E CM (MeV) 211 Th Ac+ (pn) 207 Ra pn (5n+pn + 5n) Ac (p4n+p5n) 211 Ac 210 Ac ( 138 Ba:5.26%, 137 Ba:1.94%, 136 Ba:4.03%, 135 Ba:15.2%, 134 Ba:73.5%)

16 138 Ba 134 Ba 82 Se+ 138 Ba 82 Se+ 134 Ba Fusion probability Fusion probability Se Ba calculation 40 Ar Hf calculation 124 Sn+ 96 Zr E cm - V Bass (MeV) 82 Se Ba calculation 40 Ar Hf calculation 124 Sn+ 92 Zr E xx =8.0MeV, σ=4.0mev E cm - V Bass (MeV)

17 Energy (MeV) Ecm DIC Fusion 1: 0h 2 :120h 3:160h Kr+ 136 Xe 4 : 200h R (fm) Christensen-Winther Akyuz-Winther Proximity Bass80 Double folding 48 Ti+ 208 Pb R(fm)

18 potential 45 Target Solid State Detectors (SSD) Beam Monitor ~100µg/cm

19 Energy spectra 200 E cm=178.0 MeV θ= Ti+ 208 Pb E cm =194.2 MeV θ= Cr+ 208 Pb elastic Ecm =186.5 MeV θ= Ecm =203.7 MeV θ= Counts 0 50 E cm =192.6 MeV θ=172 PLF Counts 0 90 E cm =215.7 MeV θ= Quasi-elastic, transfer 0 50 E cm =198.7 MeV θ= E cm =220.4 MeV θ= E (MeV) E (MeV) Deep-inelastic events appear in the energy spectrum. Red curve: Deep-inelastic events (DIC) calculated by the code LINDA

20 Bass Phys. Rev. Lett. 99, (2007)

21

22 Nucl. Instr. and Meth. 187 (1981)25-35

23 Phys. Lett. 159B (1985)90-94 C+ 12 C C C C

24 28 Si 58 Ni : Si 64 Ni : Phys. Rev. Lett. 62 (1989)

25 Y. Sugiyama H. Ikegami D.J. Hinde T. Murakami N. Shikazono S. Kubono H.J. Kim T. Tachikawa Y. Tomita O. Hashimoto D.R. Napoli M. Ogihara K. Ideno M. Tanaka A.M. Stefanini K. Tsuruta E. Takekoshi T. Nomura C. Signorini K. Satou W. Yokota N. Kato J. Lu T. Ikuta Y. Nagame H. Fujita B.J. Qi T. Kuzumaki Y. Tsukada T. Sugimitsu L.M. Duan I. Nishinaka S.M. Lee C.J. Lin A. Iwamoto S.C. Jeong S. Hamada Y. watanabe Y. Yamanouchi H. Fujiwara K. Nishio T. Ohtsuki S. Mitsuoka I. Kanno

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