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1 An Introduction to Ion-Optics Series of Five Lectures JINA, University of Notre Dame Sept. 30 – Dec. 9, 2005 Georg P. Berg.

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1 1 An Introduction to Ion-Optics Series of Five Lectures JINA, University of Notre Dame Sept. 30 – Dec. 9, 2005 Georg P. Berg

2 2 The Lecture Series 1 st Lecture: 9/30/05, 2:00 pm: Definitions, Formalism, Examples 2 nd Lecture: 10/7/05, 2:00 pm: Ion-optical elements, properties & design 3 rd Lecture: 10/14/05, 2:00 pm: Real World Ion-optical Systems 4 th Lecture: 12/2/05, 2:00 pm: Separator Systems, Part 1 5 th Lecture: 12/9/05, 2:00 pm: Separator Systems, Part 2

3 3 5 th Lecture 5 th Lecture: 12/2/05, 2:00 pm Separator Systems Electric Dipoles in Recoil Separator Dragon & EMMA Wien Filter in Recoil Separators Recoil separators ERNA and ARES for astrophysics A “no-field” separation method: the Wedge In-flight isotope separators TRI  P and A1900 Gas-filled separators Astrophysics recoil separator St. George

4 4 DRAGON Recoil Separator with Electric Dipoles Ref. Dragon Recoil Separator Optics, The Recoil Group, 1/18/1999,TRIUMF Study of astrophyscis reactions using radioactive beams: e.g. 21 Na  p,  ) 22 Mg in inverse kinematics using a radioactiv 21 Na beam of 4.62 MeV to study NeNa cycle

5 5 DRAGON Ion-optics Ref. J. M. D’Auria et al. TRIUMF MD1ED1MD2ED2

6 6 EMMA Recoil Separator for ISAC-II at TRIUMF B. Davids, TRIUMF & C. Davids, ANL

7 7 ERNA Recoil Separator with Wien Filters Study of the astrophysicial reaction 12 C ,  ) 16 O in inverse kinematics 4 He  12 C,  ) 16 O at E cm = 0.7 MeV WF in beam line to remove 16 O contaminant in 12 C beam ERNA Recoil Separator with 2 Wien Filters WF3, WF4

8 8 ERNA Recoil Separator with Wien Filters Ion-optics of 16 O 3 + and 6 + ions 3 rd order calculations using COSY Infinity 12 C beam mainly stopped in Faraday cup between QS1 and MD  

9 9 ARES Recoil Separator with a Wien Filter Study of astrophyscis reactions using radioctive beams. Example: Hot CNO breakout reaction 19 Ne  p,  ) 20 Na in inverse kinematics using a radioactive 19 Ne beam of 10.1 MeV Ref. M. Couder, PhD Thesis July 2004, Louvain-La-Neuve

10 10 Achromatic magnet separator Figure from Experimental Techniques at NSCL, MSU, Th. Baumann, 8/2/2002 Exercise 4: Assume foci at I & F, i.e. A 12 = B 12 = 0. Derive the first order achromatic condition of the system 0  F and compare with the dispersion matching condition. AB ^ Dispersive Intermediate focal plane, B  = p/q selection using slits ^ Achromatic Final focal plane, small beam spot e.g. for detector system

11 11 Solution of Exercise 4 x I = A 11 x 0 + A 12  0 + A 16  0 | A 12 = 0 = A 11 x 0 + A 16  0 x F = B 11 x I + B 12  I + B 16  0 | B 12 = 0 = B 11 x I + B 16  0 | substitute x I using (33) = B 11 (A 11 x 0 + A 16  0 ) + B 16  0 = B 11 A 11 x 0 + (B 11 A 16 + B 16 )  0 (33) Condition for achromaticity: A 16 = - B 16 / B 11 Note: This is the Dispersion Matching condition for C = T = 1 First order TRANSPORT Matrix R 

12 12 AB ^ 0.1 mm  E Si-detector 20 mm diameter Achromatic magnet separator ^ B  = p/q selection  p/p 0 range selection for similar velocities v m/q selection, for fully stripped ions A/Z selection Example: Production of 21 Na via H( 21 Ne,n) 21 Na with 21 Ne 7+ beam at 43MeV/nucleon using the TRI  P Separator, KVI Groningen Ions after target fully stripped e.g. 21 Ne 10+ ! 21 Ne beam with  10 10 ions/s with B  ( 21 Ne)/ B  ( 21 Na)  is all but eliminated by a slit (SH2) in front of plane I 21 Ne 20 Ne 22 Na 18 F 16 O 19 F 17 O 19 Ne = 2.0  2.1  1.9 A/Z = Note: Ions with A/Z ~ 2 are not separated !  E Si-detector TOF rel. to cyclotron RF

13 13 Achromatic magnet separator with Wedge Figure from Experimental Techniques at NSCL, MSU, Th. Baumann, 8/2/2002 A B ^ E-loss in WEDGE  E ~ Z 2 /v 2 Isotopes with different Z have different velocities v Therefore A/Z selection in B Effect of “Wedge”   “Wedge” = 0.1 mm “Si=detector” Note: For large dp/p) the degrader should be Wedge-shaped to restore achromaticity effected by degrader with constant thickness

14 14 TRI  P an achromatic secondary beam separator meter Design parameters SH = Slits Q = Quadrupoles B = Dipoles Section A Section B Wedge/  E-Si  E-Si detector

15 15 TRI  P ion-optics

16 16 A1900 MSU/NSCL Fragment Separator Ref. B.Sherrill, MSU

17 17 Gas-filled separators Concept M. Paul et al. NIM A 277 (1989) 418 Rays in a magn. dipole field without and with gas-filling Measured spectra as function of gas pressure (e.g. He, Ar) PROBLEM: After target, a distribution of several charge states q exists for low E or large Z, with B  range typically larger than acceptance causing transmission losses. REMEDY: gas-filled separator

18 18 TRI  P ion-optics Section B A “long” achromatic separator system is not suitable for a gas-filled separator that should be “short” to reduce statistical E spread and have “large dispersion” Therefore: The TRI  P separator was Designed to be able operate with Section A as beam line & Section B as short gas-filled separator with large dispersion ^ z = 9.8 m

19 19 Charge state distribution in TRI  P separator with gas-filling Ar gas pressure 5 mbar Vacuum: 10 -6 Torr 206 Pb, 7 MeV/A

20 20 RAYTRACE with gas-filling Modified RAYTRACE code used to calculate the separation of beam to demonstrate particle and beam separation in the TRI  P separator in Gas-Filled Mode Ra Pt RaPb

21 21 Recoil Separator St. George Study of (  ) and (p,  ) of astrophysics importance, for A <  targets, emphasis on low energies, i.e. very small cross sections, max. energy given by KN An overview of reaction result in the following DESIGN PARAMETERS Maximum magnetic rigidity B  : 0.45 Tm Minimum magnetic rigidity B  : 0.10 Tm Momentum acceptance dp: +/- 3.7 % Angle acceptance, horiz & vert.: +/- 40 mrad Further design considerations: Two phase construction Charge selection by B  analysis (typical: 50% Transmission) High mass resolution (  m/m  1 st phase with 2 Wien Filters) Higher mass resolution (  m/m  2nd phase Wien Filters for mass resolution (energy too low for “Wedge” method

22 22 Schematic Floorplan St. George Phase 1 Windowless Gas target Wien Filters 1 & 2 TOF & E-detectors Momentum & charge selection slits KN beam

23 23 Horizontal ion-optics St. George Wien Filters 1 & 2 B1B2B3B4

24 24 Vertical ion-optics St. George

25 25 End Lecture 5

26 26 TRI  P ion-optics 1 st & 2 nd Section

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