TRI  P presentatie voor KVI medewerkers 14 februari 2002 Klaus Jungmann Ad van den Berg Sytze Brandenburg.

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Presentation transcript:

TRI  P presentatie voor KVI medewerkers 14 februari 2002 Klaus Jungmann Ad van den Berg Sytze Brandenburg

Services to external & internal users Projectruimte Others EU € Programs/Projects AGOR Nuclear Structure and its Nuclear Structure and its Implications for Astrophysics Implications for Astrophysics Interacting Hadrons Interacting Hadrons TRI  P TRI  P..... € €... People € € €... The KVI “company” good science* education of people Two main products: * good science * education of people AGOR

project  program 2001   2013 TRI  P T R I  P TRI  P T rapped R adioactive I sotopes:  icrolaboratories for Fundamental P hysics Theory Nuclear Physics Experiment Nuclear Physics Atomic Physics people : people : G. Berg, P. Dendooven, O. Dermois, M. Harakeh, R. Hoekstra, S. Hoekstra, K. Jungmann, S. Kopecky, R. Morgenstern, R. Rogachevsky, R. Timmermans, E. Traykov, S. Umakanth, M. van Veenhuizen, H. Warringa, L. Willmann, H. Wilschut + many morefunding:

TRI  P Goals of TRI  P Goals of TRI  P Study fundamental interactions using radioactive isotopes Study fundamental interactions using radioactive isotopes in traps in traps A facility will be created for in house and outside users A facility will be created for in house and outside users General Time Lines General Time Lines Project started 2001; setup facility in 4 years Project started 2001; setup facility in 4 years TRI  P became a managed program in July 2001 TRI  P became a managed program in July 2001 Exploitation of facility until 2013 Exploitation of facility until 2013 TRI  P will evolve into a 50% user of AGOR TRI  P will evolve into a 50% user of AGOR Midterm review in 2008 Midterm review in 2008

TRI  P Atomic Physics Nuclear Physics Particle Physics

TRI  P Possibilities to Test New Models  Low Energies & Precision Measurement High Energies & direct observations

TRI  P Some Questions related to TRI  P Physics Origin of Parity Violation in Weak Interactions Origin of Parity Violation in Weak Interactions (nature prefers lefthandedness) (nature prefers lefthandedness)  details of  -decays  details of  -decays Na, Ne isotopes Na, Ne isotopes Dominance of Matter over Antimatter in Universe ? Dominance of Matter over Antimatter in Universe ? CP - Violation, Time Reversal Symmetry, Parity Violation CP - Violation, Time Reversal Symmetry, Parity Violation  permanent electric dipole moments ?  permanent electric dipole moments ? Ra isotopes Ra isotopes

TRI  P Experiments on  -Decays in Traps  correlations 6 He, 14 O, 19 Ne, 35 Ar, 38m K GANIL,ANL,LBNL, ISOLDE,TRIUMF, KVI  asymmetry 19 Ne, 20 Na, 21 Na, 37 K, 82 Rb LBNL,TRIUMF, LANL, KVI inclusive 6 He, 32 Ar ISOLDE/Seattle, Leuven, measurements GANIL Experiments on Parity Violation in Traps Atomic parity 210 Fr, 211 Fr Stony Brook, JILA, violation INFN Some Weak Interaction Experiments a lot of activity  concentrate on your strength

TRI  P Precision Experiments different in type from Precision Experiments different in type from most previous Nuclear Physics Experiments most previous Nuclear Physics Experiments  Most difficult part starts after isotopes are produced and trapped produced and trapped Advantages of KVI Advantages of KVI  Sufficient beam made available for  Sufficient beam made available for optimizing experiments optimizing experiments  Unique combination of facilities and experienced people experienced people

TRI  P TRI  P Organization (Physics) TRI  P Organization (Physics) Program leader: K. Jungmann TRI  P management: H. Wilschut Program leader: K. Jungmann TRI  P management: H. Wilschut KVI Staff Experimentalists: KVI Staff Experimentalists: G.P. Berg, P. Dendooven, O. Demois, M.N. Harakeh, R. Hoekstra, K. Jungmann, R. Morgenstern, L. Willmann, H. Wilschut (focus:  -decays, edm‘s; ground work) R. Morgenstern, L. Willmann, H. Wilschut (focus:  -decays, edm‘s; ground work) KVI Staff Theorists: KVI Staff Theorists: A. Dieperink, O. Scholten, R. Timmermans Postdocs: Postdocs: S. Kopecky, + offer + N.N. PhD Students: PhD Students: V. Kravchuk, E. Traykov, D. Umakanth, + N.N. ‘s Master Students: Master Students: A. Rogachewskiy, H. Waringa A. Rogachewskiy, M. van Veenhuizen, H. Waringa External Experimentalists: External Experimentalists: A. Young, NIPNET, ION CATCHER, A. Young, NIPNET (H. Wilschut coordinator), ION CATCHER, new in discussions: NIKHEF, PARIS new in discussions: NIKHEF (neutrino mass), PARIS (parity violation)

TRI  P TRI  P Organization (Technical) TRI  P Organization (Technical) Separator Separator (design stage) (design stage) project leader: Otto Dermois /Georg Berg ass. proj. lead: Harry Kiewiet slow control : Dick Damstra design:Lambertus Slatius vaccum:Harry Timersma

TRI  P TRI  P Organization (Technical) TRI  P Organization (Technical) Separator MOT & Laser Laboratory Separator MOT & Laser Laboratory (design stage) (design stage) (design stage) (design stage) project leader: Otto Dermois /Georg Berg project leader: Lorenz Willmann ass. proj. lead: Harry Kiewiet ass. proj. lead: Jan Mulder slow control : Dick Damstra slow control : Henk van der Duin design:Lambertus Slatius design:Bastian Duinsveld vaccum:Harry Timersma vaccum:Henk Gorter optics&lasers:Hassan Karaer optics&lasers:Hassan Karaer

TRI  P TRI  P Organization (Technical) TRI  P Organization (Technical) Separator MOT & Laser Laboratory Separator MOT & Laser Laboratory (design stage) (design stage) (design stage) (design stage) project leader: Otto Dermois /Georg Berg project leader: Lorenz Willmann ass. proj. lead: Harry Kiewiet ass. proj. lead: Jan Mulder slow control : Dick Damstra slow control : Henk van der Duin design:Lambertus Slatius design:Bastian Duinsveld vaccum:Harry Timersma vaccum:Henk Gorter optics&lasers:Hassan Karaer optics&lasers:Hassan Karaer RFQ cooler and LEB RFQ cooler and LEB (design stage) (design stage) project leader :Lorenz Willmann ass. proj. lead: N.N. slow control : Peter Kroon design:Lambertus Slatius vaccum:Henk Gorter electronics:Marteen Stokroos

TRI  P TRI  P Organization (Technical) TRI  P Organization (Technical) Separator MOT & Laser Laboratory Separator MOT & Laser Laboratory (design stage) (design stage) (design stage) (design stage) project leader: Otto Dermois /Georg Berg project leader: Lorenz Willmann ass. proj. lead: Harry Kiewiet ass. proj. lead: Jan Mulder slow control : Dick Damstra slow control : Henk van der Duin design:Lambertus Slatius design:Bastian Duinsveld vaccum:Harry Timersma vaccum:Henk Gorter optics&lasers:Hassan Karaer optics&lasers:Hassan Karaer RFQ cooler and LEB Infrastructure RFQ cooler and LEB Infrastructure (design stage) (design stage ) (design stage) (design stage ) project leader :Lorenz Willmann project leader: Harry Kiewiet ass. proj. lead: N.N. radiation safety:Hans Beijers slow control : Peter Kroon design:Bastian Duinsveld design:Lambertus Slatius building services: Jans Sijbring vaccum:Henk Gorter cooling:Steven van der Veen electronics:Marteen Stokroos electro-technics:Piet Wieringa

TRI  P TRI  P Organization (Technical) TRI  P Organization (Technical) Separator MOT & Laser Laboratory Separator MOT & Laser Laboratory (design stage) (design stage) (design stage) (design stage) project leader: Otto Dermois /Georg Berg project leader: Lorenz Willmann ass. proj. lead: Harry Kiewiet ass. proj. lead: Jan Mulder slow control : Dick Damstra slow control : Henk van der Duin design:Lambertus Slatius design:Bastian Duinsveld vaccum:Harry Timersma vaccum:Henk Gorter optics&lasers:Hassan Karaer optics&lasers:Hassan Karaer RFQ cooler and LEB Infrastructure RFQ cooler and LEB Infrastructure (design stage) (design stage ) (design stage) (design stage ) project leader :Lorenz Willmann project leader: Harry Kiewiet ass. proj. lead: N.N. radiation safety:Hans Beijers slow control : Peter Kroon design:Bastian Duinsveld design:Lambertus Slatius building services: Jans Sijbring vaccum:Henk Gorter cooling:Steven van der Veen electronics:Marteen Stokroos electro-technics:Piet Wieringa Cryo target Cryo target (orientaton phase) (orientaton phase) project leader :Hans Wilschut N.N.

TRI  P Combined Fragment and Gas Filled Recoil Separator G. Berg O. Dermois L. Slatius

TRI  P Primary beam from AGOR cyclotron target position in fragment separator mode target position in recoil-separatormode beam of radioactive isotopes to decelerator and traps Combined Fragment and Recoil Separator

TRI  P

Separator Hall Cooling and Trapping Hall The Wall variety of traps RFQ

TRI  P TRI  P needs TRI  P needs Setup of the separator, targets and particle deceleration position in hall (solved) position in hall (solved) power supplies power supplies cooling cooling vacuum vacuum beam diagnostics beam diagnostics radiation safety radiation safety Shutdown(s) to install hardware AGOR to provide the right beams at high Setup of the traps and lasers precision optics & electronics precision optics & electronics laser laboratory laser laboratory safety safety Variety of auxiliary experiments spectroscopy spectroscopy gas stopping gas stopping particle production particle production Full design report available soon!

TRI  P A. Rogachevsky, H. Wilschut, S. Kopecky, V. Kravchuk, K. Jungmann + AGOR team First TRI  P Tests with beam 15 N Tl  213 Ra + 7n 213 Fr C Tl C N Ra Fr x-rays x-ray counts [arb.] x-ray energy [channels] raw data fitted x-ray spectra extracted Fr x-rays Au Hg Tl Bi Po At Rn

TRI  P RFQ blueprints - no glossy pictures yet

TRI  P Magneto-Optical Trap (MOT) Laser beam atoms coldatoms ~1 million Na atoms Temperature < 1 mK How works the MOT? How works the MOT?

TRI  P Diode Laser Hardware & Electronics First Laser mechanical parts ready mechanical parts ready precision electronics precision electronics in design stage in design stage First photons from the device expected in laser lab next week

TRI  P

Time Schedule Project started 2001 Program approved July 2001 Separator, Cooler, RFQ, Optics Laboratory Orientation Phase in now in Design Phase Separator ready for bids - contract expected June 2002 Magnet delivery July 2003 Separator Setup and Commisioning 2003/2004     A. van den Berg Ready for Experiments End 2004 In the mean time: Preparatory Experiments, Isotope Production,Gas Stopping,Cooling, RFQ, spectroscopy,... Cyclotron “adjustments” S. Brandenburg

TRI  P TRI  P depends on Your TRI  P depends on Your Expertise Expertise Support Support Input Input Criticism Criticism Ideas Ideas Thank You ! Thank You !

NOW WE REALLY START