Matt Landreman
Matt Landreman
Associate Research Scientist, University of Maryland
Verified email at - Homepage
Cited by
Cited by
Overview of first Wendelstein 7-X high-performance operation
T Klinger, T Andreeva, S Bozhenkov, C Brandt, R Burhenn, B Buttenschön, ...
Nuclear Fusion 59 (11), 112004, 2019
Major results from the first plasma campaign of the Wendelstein 7-X stellarator
RC Wolf, A Ali, A Alonso, J Baldzuhn, C Beidler, M Beurskens, ...
Nuclear Fusion 57 (10), 102020, 2017
Bright quasi-phase-matched soft-x-ray harmonic radiation from argon ions
M Zepf, B Dromey, M Landreman, P Foster, SM Hooker
Physical review letters 99 (14), 143901, 2007
Performance and properties of the first plasmas of Wendelstein 7-X
T Klinger, A Alonso, S Bozhenkov, R Burhenn, A Dinklage, G Fuchert, ...
Plasma Physics and Controlled Fusion 59 (1), 014018, 2016
Confirmation of the topology of the Wendelstein 7-X magnetic field to better than 1: 100,000
TS Pedersen, M Otte, S Lazerson, P Helander, S Bozhenkov, ...
Nature communications 7 (1), 13493, 2016
Comparison of particle trajectories and collision operators for collisional transport in nonaxisymmetric plasmas
M Landreman, HM Smith, A Mollén, P Helander
Physics of Plasmas 21 (4), 2014
Magnetic fields with precise quasisymmetry for plasma confinement
M Landreman, E Paul
Physical Review Letters 128 (3), 035001, 2022
Numerical calculation of the runaway electron distribution function and associated synchrotron emission
M Landreman, A Stahl, T Fülöp
Computer Physics Communications 185 (3), 847-855, 2014
Generation of a train of ultrashort pulses from a compact birefringent crystal array
B Dromey, M Zepf, M Landreman, K O'keeffe, T Robinson, SM Hooker
Applied optics 46 (22), 5142-5146, 2007
Improved understanding of physics processes in pedestal structure, leading to improved predictive capability for ITER
RJ Groebner, CS Chang, JW Hughes, R Maingi, PB Snyder, XQ Xu, ...
Nuclear Fusion 53 (9), 093024, 2013
Electrostatic potential variation on the flux surface and its impact on impurity transport
JM García-Regańa, CD Beidler, R Kleiber, P Helander, A Mollén, ...
Nuclear Fusion 57 (5), 056004, 2017
An improved current potential method for fast computation of stellarator coil shapes
M Landreman
Nuclear Fusion 57 (4), 046003, 2017
Spheromak merging and field reversed configuration formation at the Swarthmore Spheromak Experiment
CD Cothran, A Falk, A Fefferman, M Landreman, MR Brown, MJ Schaffer
Physics of Plasmas 10 (5), 1748-1754, 2003
Kinetic modelling of runaway electrons in dynamic scenarios
A Stahl, O Embréus, G Papp, M Landreman, T Fülöp
Nuclear Fusion 56 (11), 112009, 2016
Core radial electric field and transport in Wendelstein 7-X plasmas
NA Pablant, A Langenberg, A Alonso, CD Beidler, M Bitter, S Bozhenkov, ...
Physics of Plasmas 25 (2), 2018
Omnigenity as generalized quasisymmetry
M Landreman, PJ Catto
Physics of Plasmas 19 (5), 2012
SIMSOPT: A flexible framework for stellarator optimization
M Landreman, B Medasani, F Wechsung, A Giuliani, R Jorge, C Zhu
Journal of Open Source Software 6 (65), 3525, 2021
Generalized Ohm's law in a 3‐D reconnection experiment
CD Cothran, M Landreman, MR Brown, WH Matthaeus
Geophysical research letters 32 (3), 2005
Synchrotron radiation from a runaway electron distribution in tokamaks
A Stahl, M Landreman, G Papp, E Hollmann, T Fülöp
Physics of Plasmas 20 (9), 2013
Direct construction of optimized stellarator shapes. Part 1. Theory in cylindrical coordinates
M Landreman, W Sengupta
Journal of Plasma Physics 84 (6), 905840616, 2018
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