Dr. Thomas Gutberlet

• Studied chemistry at Freie Universität Berlin from 1977-1989
• PhD in Chemistry, Dept. of Chemistry, Freie Universität Berlin in 1995
• Scientific co-worker at Max-Planck-Institut for Colloid and Interface Sciences in Berlin in 1993
• PostDoc at Inst. f. Experimental Physik I, Universität Leipzig from 1995-1998
• Scientific co-worker at Hahn-Meitner-Institut Berlin GmbH from 1999-2002, Assistant ESS Instrumentation Task Group
• Research scientist at Paul Scherrer Institut from 2002-2007, 1^st instrument scientist neutron reflectometer AMOR
• Head of User Office at JCNS and FRM II in Garching from 2007-2011
• Head of User Coordination at HZB in Berlin from 2011-2015
• Head of Project Team HBS at Jülich Centre for Neutron Science in Jülich from 2015-2024

Monte Carlo simulation of proton- and neutron induced radiation damage ina tantalum target irradiated at 70 MeV protons
N. Ophoven et al., Appl. Phys. A, 127, 576 (2021)

Performance of neutron guide systems for low energy accelerator-driven neutron facilities
Z. Ma et al., Nucl. Instr. Meth. A, 1009, 165479 (2021)

Developments of a multiplexer system for the High-Brilliance Neutron Source HBS
M. Rimmler et al. J. Neutr. Res., 23, 143-156 (2021)

Tailoring neutron beam properties by target-moderator-reflector optimisation
P. Zakalek et al., J. Neutr. Res., 23, 185-200 (2021)

Determination of the neutron yield of Be, V and Ta targets irradiated with protons (22-42MeV) by means of prompt gamma neutron activation analysis
J. Baggemann et al., Nucl. Instr. Meth. A, 990, 164989 (2021)

Sustainable neutrons for today and tomorrow—The Jülich High Brilliance neutron Source project
T. Gutberlet et al., Neutron News, 31, 37-43 (2020)

Low energy accelerator-driven neutron facilities—A prospect for a brighter future for research with neutrons
T. Brückel et al., Neutron News, 31, 13-18 (2020)

Conceptual Design Report Jülich High Brilliance Neutron Source (HBS) (PDF, 10 MB)
T. Brückel, T. Gutberlet (Eds.), Schriften des Forschungszentrum Jülich, General, Vol.8 (2020)

Energy and target material dependence of the neutron yield induced by proton and deuteron bombardment
P. Zakalek et al., EPJ Web of Conf., 231, 03006 (2020)

Cryostat for the provision of liquid hydrogen with a variable ortho-para ratio for a low-dimensional cold neutron moderator
S. Eisenhut et al., EPJ Web of Conf., 231, 04001 (2020)

Proton Beam Multiplexer Developments for Multi-Target Operation at the
High-Brilliance Neutron Source HBS
M. Rimmler, et al., EPJ Web of Conf., 231, 02002 (2020)

Recent Extensions of JULIC for HBS Investigations
O. Felden et al., Proc. Cyclotrons'19, Cape Town, South Africa, 195-198 (2019)
High-brilliance neutron source project
P. Zakalek et al., Proc. HIAT'18, Lanzhou, China, 117-121 (2019)
Conceptual Design of the Proton LINAC for the High Brilliance Neutron Source HBS
H. Podlech et al., Proc. IPAC'19, Melbourne, Australia, 910-913 (2019)

The Jülich high brilliance neutron source project
T. Gutberlet et al., Physica B, 570, 345-348 (2019)

Parametric study and design improvements for the target of NOVA ERA
P.-E. Doege et al., J. Neutron Res., 20, 47-54 (2018)

Workhorse scattering instruments for low power compact
accelerator driven neutron sources
P. Zakalek et al., JPS Conf. Proc. 22, 011025 (2018)

Temperature profiles inside a target irradiated with protons or deuterons for the development of a compact accelerator driven neutron source
P. Zakalek et al., Physics B, 551, 484-487 (2018)

Compact and easy to use mesitylene cold neutron moderator for CANS
T. Cronert et al., Physics B, 551, 377-380 (2018)

Spectrometers for compact neutron sources
J. Voigt et al., Nucl. Instr. Meth. A, 884, 59 (2018)

Conceptual Design Report NOVA ERA (PDF, 14 MB)
E. Mauerhofer et al., Schriften des Forschungszentrum Jülich, General, Vol.7 (2017)

Towards Compact Accelerator Driven Neutronsources for Europe
T. Gutberlet et al., Neutron News, 28, 20-25 (2017)

The Jülich high-brilliance neutron source project
U. Rücker et al., Eur. Phys. J. Plus, 131, 19 (2016)