DESIREE

1. DESIREE Double Electro- Static Ion Ring Exp- Eriment Albanova Instrumentation Seminar 2003-10-30 HenningSchmidt

2. Timeline: 1997: First electrostatic ion storage ring ELISA at Århus University 1999: Application to NFR for single ring(Larsson, Cederquist, Schmidt) - Not granted. 2001: Application to VR for Double-Ring DESIREE (Skeppstedt, Rensfelt, Danared). Outcome: funding for Design Study. October 2002: Design Report submitted to VR.Decision postponed due to the uncertain future of MSL. June 2003: VR decision to cease funding of MSL October 2003: DESIREE gets funding from Wallenberg and VR Soon: All the questions of who, where, and when finds their answers and, the design is finished and construction commences. 2005 or thereabouts: Inauguration party!

3. Outline • The DESIREE project • Motivation: Mutual Neutralization • Technical description • Planned experiments • AMO Physics • Examples:Mutual NeutralizationInterstellar Ion Chemistry • Biomolecules • Example: ‘Electron Capture Dissociation’ • Summary

4. Plasma environments: • The degree of ionization is a determining factor for the ongoing chemistry. Processes that affect this parameter are therefore crucial. • Electron-Ion recombination: • X+ + e-  X + h (atomic recombination)AB+ + e-  A + B (dissociative recombination) • Mutual Neutralization : • X+ + Y- X + YA- + BC+  A + BC or A + B + C or ...

5. ELISA Ion sources: Plasma Ion Sources Sputter Source (Negative Ions) ESI Source (Biomolecules) ECRIS (Highly Charged Ions) + new ideas…. DESIREE Double Electro-Static Ion Ring ExpEriment • Double-walled vacuum vessel • Outer tank 300K - Inner tank 15K • Cooling by cryogenerators • Expected vacuum in inner part • 300 K: <10-11 mbar • 15 K: Density reduced by order(s) of magnitude 1 m

6. Mutual Neutralization Animation

7. Position-sensitive detector ELISA 1 m DESIREE

8. tan = 0.02 (corresponds to 4 eV transverse on 10 keV beam) Merging / de-merging

9. Count Rate estimates: E v Merged-beams experiments • Longitudinally: Kinematical compression • Transversely: Ion optics determines: < 1 eV seems feasible. • Can beam cooling be developed? • Example: MN H-+H2+E=10 keV/amu, Erel=1 eV, Amax=1 cm2,=1.6.10-14cm2 (COB), I+=I-=100 nA, L=80 cm: 44 s-1 • Background rate is similar - The key point is that in MN there are (at least) two neutrals in coincidence!! • How about experiments with Biomolecules? RN: In above example N=4.106. Feasible for ESI with trap Relative velocity definition: • Longitudinally: Kinematical compression

10. Three special features of DESIREE: • Double-ring structure: • Merged beams positive/negative ion collisions. • Cryogenic system: • Extremely good vacuum  Long storage lifetime. • Internally cold molecular ions. • Electrostatic confinement: • High mass-to-charge ratios (i.e. Biomolecules). • Absence of magnetic-field mixing in lifetime measurements

11. Examples of proposed experiments at the DESIREE facility: • Atoms and ‘Small’ Molecules: • Single-Ring Experiments • Lifetime measurements of metastable ions (He-, C60q+,…) • LASER spectroscopy and lifetime measurements • Atomic ions (Continuation of CRYRING project, Mannervik) • Molecular ions (e.g. Cn-) • Merged-Beams Experiments • Mutual Neutralization Collisions • Fundamental systems (e.g. H-+H2+ … DR below 0 eV) • Atoms and ‘Small’ Molecules: • Single-Ring Experiments • Lifetime measurements of metastable ions (He-, C60q+,…) • LASER spectroscopy and lifetime measurements • Atomic ions (Continuation of CRYRING project, Mannervik) • Molecular ions (e.g. Cn-) • Merged-Beams Experiments • Mutual Neutralization Collisions • Fundamental systems (e.g. H-+H2+ … DR below 0 eV) • Astrophysical plasmas (e.g. Cn-+H3+, H3O+,….)

12. Astrophysics and DESIREE • Diffuse interstellar clouds: • Star formation and ion chemistry. • Formation of polyatomic molecules • (e.g. H2+ + H2 H3+ + H) • Two processes limit positive ion abundance: • Dissociative Recombination (AB+ + e- A + B) • Mutual Neutralization (X+ + Y- X + Y) Are there any negative ions in the interstellar medium?

13. Astrophysics and DESIREE • Old puzzle: Diffuse interstellar absorption bands. • Recent interesting candidates are carbon chain anions: Cn- (n=6,7,8,9) Tulej et al, Astrophys. J, 506, L69 (1998) • Alexander Dalgarno, 1999: Cn- + H2+ H3+ H3O+ CH5+ etc... • ’The negative charges may reside more in the form of anions than electrons and mutual neutralization may replace dissociative recombination as the main mechanism for removing positive ions.”Proc. of the 1999 conf on Dissociative Recombination, eds M. Larsson, J.B.A. Mitchell and I.F. Schneider (2000)

14. Examples of proposed experiments at the DESIREE facility: • Atoms and ‘Small’ Molecules: • Single-Ring Experiments • Lifetime measurements of metastable ions (He-, C60q+,…) • LASER spectroscopy and lifetime measurements • Atomic ions (Continuation of CRYRING project, Mannervik) • Molecular ions (e.g. Cn-) • Merged-Beams Experiments • Mutual Neutralization Collisions • Fundamental systems (e.g. H-+H2+ … DR below 0 eV) • Astrophysical plasmas (e.g. Cn-+H3+, H3O+,….) • Atmospherical ion chemistry. • Collisions involving fullerenes (C60q++C60-, Ar8++C60-,….) • Atoms and ‘Small’ Molecules: • Single-Ring Experiments • Lifetime measurements of metastable ions (He-, C60q+,…) • LASER spectroscopy and lifetime measurements • Atomic ions (Continuation of CRYRING project, Mannervik) • Molecular ions (e.g. Cn-) • Merged-Beams Experiments • Mutual Neutralization Collisions • Fundamental systems (e.g. H-+H2+ … DR below 0 eV) • Astrophysical plasmas (e.g. Cn-+H3+, H3O+,….)

15. Examples of proposed experiments at the DESIREE facility: • Biomolecules: • Production, accumulation, conformere selection • The ELISA injector system:

16. Examples of proposed experiments at the DESIREE facility: • Biomolecules: • Biomolecules: • Single-Ring Experiments (already pursued at ELISA) • Lifetime and stability(J.U.Andersen et al, Eur. Phys. J. D 25, 139 (2003) • LASER spectroscopy(e.g. GFP: S.B.Nielsen et al PRL 87, 228102 (2001))

18. GFP: S.B.Nielsen et al PRL 87, 228102 (2001)

19. Examples of proposed experiments at the DESIREE facility: • Biomolecules: • Biomolecules: • Single-Ring Experiments (already pursued at ELISA) • Lifetime and stability(J.U.Andersen et al, to be published) • LASER spectroscopy(e.g. GFP: S.B.Nielsen et al PRL 87, 228102 (2001)) • Biomolecules: • Single-Ring Experiments (already pursued at ELISA) • Lifetime and stability(J.U.Andersen et al, to be published) • LASER spectroscopy(e.g. GFP: S.B.Nielsen et al PRL 87, 228102 (2001)) • Merged-Beams Experiments • Electron Capture Dissociation in Negative/Positive ion collisions • Coulombic explosions induced by highly charged ions

20. Electron Capture Dissociation • ECD is important in protein sequencing because it breaks other bonds than those accessed in collision-induced dissociation. • ECD is studied by introducing electrons in the plasma of FT-ICR mass spectrometer. No control of electron impact energy. • Using simple negative ion to carry the electron, low (even below zero) and well-controlled relative energy is obtained.

21. Electron-transfer 10 a0 10 a0

22. Area of impact for ’distant’ collisions. • Experimental indication of distant collision: • Detection of neutral at proper time in relation to the arrival of the biomolecule(ar fragments)

23. Summary: • DESIREE can be built! • We can do new AMO physics in single-ring and particularly in merged-beams configuration (Mutual Neutralization) • Spectroscopy and lifetime measurements for biomolecular ions - ELISA • ’ECD’ like processes and HCI-biomolecular ion interaction in merged-beams - DESIREE unique The End!

24. DESIREE People: • Main Applicant: Ö. Skeppstedt (MSL) • Design group: (MSL + SU)K-G Rensfelt, M. Andersson, L. Bagge,H. Danared, J. Jensen, L. Liljeby, H.T. Schmidt, K. Schmidt, A. Simonsson • Contributors to the Scientific Programme: (SU + ..)H. T. Schmidt, H. Cederquist, T. Hansson,J. Jensen, M. Larsson, S. Mannervik,P. vd Meulen, J. Pettersson. P. Royen,E. Uggerud, R. A. Zubarev

25. Mutual Neutralization Animation