FEL2009 - List of Authors (Wulterkens, G.F.A.J.)

A B C D E F G H I J K L M N O P Q R S T U V W X Y Z

Wulterkens, G.F.A.J.

Paper	Title	Page
TUPC84	Realization of the Nijmegen THz-FEL	435
	R.T. Jongma, A.C.N. Engels, R.W. Lof, F.J.P. Wijnen, G.F.A.J. Wulterkens, V. Zhaunerchyk, P.A.W. van Dael, A.J.A. van Roij, A.P. van Vliet, W.J. van der Zande Radboud University, Nijmegen K. Dunkel, C. Piel RI Research Instruments GmbH, Bergisch Gladbach U. Lehnert, P. Michel, W. Seidel, R. Wünsch FZD, Dresden A.F.G. van der Meer FOM Rijnhuizen, Nieuwegein
	The Radboud University in Nijmegen received funding to realize a narrow-band THz laser system and a 45 T hybrid magnet system. Based on results of predesign studies [1], all review committees agreed to continue the project and enter the realization phase. In this paper we present the technical solutions for realization of the main system components. We present the details of the RI Research Instruments GmbH (a former ACCEL Instruments GmbH activity) LINAC system. Operation of the full system (including the electron source) at 3 GHz is desirable and deemed feasible after first experimental studies. As the Nijmegen FEL will operate at wavelength up to 1.5 mm, the cavity will be fully waveguided, complicating the incorporation of an intra-cavity Fox-Smith interferometer required to induce coherence between micropulses and a Michelson interferometer as most ideal outcoupler. The optical distribution system comprises 150 m of vacuum tubing with 25 cm effective diameter (planar and refocusing) mirrors. A robust yet cost efficient realization taking boundary conditions on optical beam parameters at diagnostics station and user stations into account is foreseen. [1] Design of the Nijmegen high-resolution THz-FEL, R.T. Jongma_, et al. Proc. FEL-08.

Paper

Title

Page

TUPC84

Realization of the Nijmegen THz-FEL

435

R.T. Jongma, A.C.N. Engels, R.W. Lof, F.J.P. Wijnen, G.F.A.J. Wulterkens, V. Zhaunerchyk, P.A.W. van Dael, A.J.A. van Roij, A.P. van Vliet, W.J. van der Zande
Radboud University, Nijmegen
K. Dunkel, C. Piel
RI Research Instruments GmbH, Bergisch Gladbach
U. Lehnert, P. Michel, W. Seidel, R. Wünsch
FZD, Dresden
A.F.G. van der Meer
FOM Rijnhuizen, Nieuwegein

The Radboud University in Nijmegen received funding to realize a narrow-band THz laser system and a 45 T hybrid magnet system. Based on results of predesign studies [1], all review committees agreed to continue the project and enter the realization phase. In this paper we present the technical solutions for realization of the main system components. We present the details of the RI Research Instruments GmbH (a former ACCEL Instruments GmbH activity) LINAC system. Operation of the full system (including the electron source) at 3 GHz is desirable and deemed feasible after first experimental studies. As the Nijmegen FEL will operate at wavelength up to 1.5 mm, the cavity will be fully waveguided, complicating the incorporation of an intra-cavity Fox-Smith interferometer required to induce coherence between micropulses and a Michelson interferometer as most ideal outcoupler. The optical distribution system comprises 150 m of vacuum tubing with 25 cm effective diameter (planar and refocusing) mirrors. A robust yet cost efficient realization taking boundary conditions on optical beam parameters at diagnostics station and user stations into account is foreseen.

[1] Design of the Nijmegen high-resolution THz-FEL, R.T. Jongma_, et al. Proc. FEL-08.