1 / 30

Recent Progress for Lanzhou Gas-Filled Recoil Separator

Recent Progress for Lanzhou Gas-Filled Recoil Separator. 报告人:张志远 中科院近代物理研究所. 2012 超重核合成机制与性质研讨会. Outline. Introduction of the Lanzhou gas-filled recoil separator First fusion reaction experiment: 175 Lu( 40 Ar,n) 215-x Ac First superheavy nuclei experiment: 208 Pb( 64 Ni,n) 271 Ds

emile
Download Presentation

Recent Progress for Lanzhou Gas-Filled Recoil Separator

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Recent Progress for Lanzhou Gas-Filled Recoil Separator 报告人:张志远 中科院近代物理研究所 2012超重核合成机制与性质研讨会

  2. Outline Introduction of the Lanzhou gas-filled recoil separator First fusion reaction experiment: 175Lu(40Ar,n)215-xAc First superheavy nuclei experiment: 208Pb(64Ni,n)271Ds New detector system and the performance in the 40Ca+175Lu and 40Ca+169Tm experiments Summary

  3. Introduction Location GFSL Gas-filled recoil separator in Lanzhou HIRFL-CSR

  4. Schematic View Dh : the dipole magnet with horizontally focusing ability Qv and Qh : the vertically and horizontally focusing quadrupole magnets, respectively

  5. Technical Parameters

  6. Comparison Table 2 Comparison of the gas-filled separators The subscripts h and v stand for horizontally and vertically focusing, respectively. * HTM : High Transmission Mode * SIM : Small Image-size Mode

  7. Position Sensitive Silicon Detector Active area:58 mm * 58 mm Strip Number:16 (vertical) Width of one strip:3.6 mm Thickness:300 m Manufacture: CANBERRA • Energy resolution(FWMH): ~50 keV(212Po-8.785MeV) • Position resolution (FWMH): ~1.5 mm(ER-)

  8. First fusion reaction experiment : 175Lu(40Ar, xn)215-xAc 175Lu(40Ar, xn)215-xAc • 实验目的: • 探索谱仪运行最佳条件,为超重核实验做准备 • 反冲余核在焦平面探测器上的分布 • 充气气压对余核平衡电荷态的影响 • 余核211,210Ac传输效率 • 实验条件: • 175Lu靶厚 0.53 mg/cm2 • 40Ar束流能量 177 MeV,靶中心能量175 MeV • 流强 2.8×1011 s-1 • 氦气气压 0.7~1.0 mbar • 磁刚度 ~1.7 Tm

  9. First fusion reaction experiment: 40Ar + 175Lu -> 215Ac* 4n-5n p2n-p3n a2n-a3n 2n-3n 211,210Ac 215Ac* 7.5 MeV, 0.25~0.35 s α1 207,206Fr 6.8 MeV, 15~16 s α2 203,202At 203At 6.1 MeV, 7.4 min 202At 6.2 MeV, 184 s α3

  10. On-line spectra 210,211Ac T1/2=0.24±0.01 s P=0.84 mbar B=1.73 Tm

  11. Equilibrium charge state • 余核平衡电荷态受以下几方面因素的影响: • 余核核电荷数 (Z) • 余核飞行速度 (v) • 余核核外电子排布 (4f, 5f) • 气体种类 (He, H2) • 气体压强 (Pressure) LBNL Exp. Data

  12. Equilibrium charge state “density effect”

  13. Transmission Efficiency 175Lu(40Ar, xn)215-xAc • Beam intensity:1 eA • Helium gas pressure:0.84 mbar • Magnetic rigidity:1.73 Tm • Counting rate of the decay of 211,210Ac:300 counts/min • Detection efficiency:50% • Abundance of 175Lu:97% • Production cross section of 211,210Ac:68.8 b • Transmission efficiency:14% Vermeulen D, et al. Z. Phys. A, 1984, 318(157).

  14. First superheavy nuclei experiment: 208Pb(64Ni, n)271Ds • Beam:64Ni19+ (HIRFL-SFC) • Energy:317.1 MeV Intensity:~100 pnA(6.6×1011 ions/s) • Beam time: 01/15/2011 ~ 01/21/2011 7days • 03/15/2011 ~ 03/26/2011 12days • Total dose:6.4×1017 ions • Beam energy at the centre of target: 313.3 MeV • Excitation energy of the compound nucleus: 14.4 MeV 指导合作: 张焕乔(中国原子能科学研究院) 任中洲(南京大学) 周善贵(中科院理论物理研究所) …… Br=2.01 Tm Helium gas P=0.8 mbar

  15. Rotating Target System • To avoid the melting of 208Pb target, the rotating target system and sandwiched target were prepared in the experiment. • During the irradiation, the target wheel rotated at the speed of 600 rpm.

  16. Schematic Diagram of Data Acquisition N568B Amplifier 1~20 MeV 5~200 MeV Scaler ADC Accelerator Beam Chopper CAMAC

  17. Kinematics 焦平面探测器 充气反冲谱仪 蒸发余核 He 靶 束流 PSD Veto • 64Ni束流在靶中心能量313.3 MeV,在靶中能量损失 ~6.5 MeV • 复合核272Ds*激发能 14.4 MeV • 蒸发余核271Ds反冲能 70.7 MeV,速度 7.1×106 m/s,平衡电荷态qave=9.6~9.7 (经验公式计算) • 蒸发余核271Ds在硅探测器注入能量 ~65 MeV,考虑脉冲幅度亏损(PHD)后的注入能量 ~35 MeV,注入深度 ~10 m • 271Ds衰变产生的a粒子在探测器中射程 ~65 m

  18. One -decay chain assigned to 271Ds 208Pb(64Ni, n)271Ds (Z=110) Known data

  19. Comparison with other laboratory data Decay energy Decay time

  20. Probability of Accidental Coincidence 208Pb(64Ni, n)271Ds (Z=110) • Counting rate: • 25 s-1 in the focal plane detector • 3.5 s-1 in the -decay energy range (7-11 MeV) • Probability of accidental coincidence • 3 mmposition window,309 pixels • EVR-a1: 1.1×10-3 • EVR-a4: 7.1×10-2 • EVR-a5: 2.7×10-1 • EVR-a1-a4-a5: 2.1×10-5

  21. New Detector System Si-box detector stop detectors TOF detector veto detector side detector Recoil flight path Si-box: Stop detector: 50mm×50mm×3 (active area), position-sensitive detectors (each has 16 vertical strips), 300m (thickness) Side detector: 50mm×50mm×8 (active area), non-position-sensitive detectors, Veto detector: 50mm×50mm×3 (active area), non-position-sensitive detectors TOF detector (Multi Wire Proportional Counter): 80mm×180mm (active area), 0.5m mylar window, isobutane gas (2 mbar)

  22. Photos Focal plane detector Silicon-box detector Time-of-flight detector Micro-Channel Plate detector Multi-Wire Proportional Counter

  23. 40Ca+175Lu->215Pa* • Observed in the bombardment 40Ca+175Lu with an energy of 4.83 MeV/u • Without the veto detector • With old beam dump, the total counting rate of stop detector was up to 300 events/s 209,210Ra 206,207Fr 205,206Rn 211,212Ra 207,208Rn, 203At 208,209Fr 210,211Ac 210,211Fr Signals obtained from both MWPCand Si-box Total spectrum of silicon detector -decay spectrum

  24. 40Ca+169Tm->209Ac* • Observed in the bombardment 40Ca+169Tm with an energy of 4.84 MeV/u • Three veto detectors mounted downstream of the stop detector • With the improvement of beam dump, the total counting rate decreased to 120 events/s

  25. 40Ca+169Tm->209Ac* Energy spectrum from the stop detector All E<10 MeV signals E<10 MeV signals obtained from both stop detector and TOF E<10 MeV signals anti-coincident with TOF signals E<10 MeV signals obtained from both stop detector and veto detector with no TOF signals E<10 MeV signals anti-coincident with TOF and veto signals E<10 MeV signals obtained from both stop detector and side detector with no TOF and veto signals

  26. 40Ca+169Tm->209Ac* 204Rn 201At 204Fr 205Fr 205,206Rn 200Po 203mRn 206Fr -decay spectrum The data for Ca+Lu and Ca+Tm experiments are analyzed in progress.

  27. Summary 兰州充气谱仪已成功投入运行,初步具备进行重核和超重核实验研究的能力。 谱仪上首次开展了熔合反应175Lu(40Ar, xn)215-xAc的实验研究,探索了谱仪正常运行的最佳条件,为谱仪上进行超重核实验做准备。 利用兰州充气反冲谱仪首次开展了超重核271Ds(Z=110)的实验研究。采用的反应道为208Pb(64Ni, n)271Ds ,观察到一条271Ds的衰变链,验证了超重核271Ds的衰变性质。 完成了谱仪新焦平面探测系统的研制,并将其成功应用于40Ca+175Lu、 40Ca+169Tm的在线实验中,达到了预期目标。

  28. 下一步工作展望 • 实验技术方面 • 优化谱仪传输光学,提高余核传输效率 • 利用两块TOF探测器,提高时间分辨,得到穿透粒子的质量信息 • 在焦平面探测器周围添加探测器,或进行“反冲衰变标记(RDT)”实验研究,获取余核衰变的谱学信息 • 物理实验方面 • 继续开展Z~110超重核区核素的合成和性质研究 • 开展对重核区质子滴线附近核素的合成和性质研究 • 开展重核区核素衰变谱学研究,得到相关核结构信息

  29. 研究组成员 近代物理研究所超重核研究组 小组成员: 研究员: 甘再国、李君清 黄天衡、黄明辉、马龙、张志远、郁琳、杨华彬

  30. Thank You !

More Related