Publikationer av Nils Brenning
Refereegranskade
Artiklar
[1]
V. G. Antunes et al., "Influence of the magnetic field on the extension of the ionization region in high power impulse magnetron sputtering discharges," Plasma sources science & technology, vol. 32, no. 7, 2023.
[2]
J. Fischer et al., "Insights into the copper HiPIMS discharge : deposition rate and ionised flux fraction," Plasma sources science & technology, vol. 32, no. 12, 2023.
[3]
H. Hajihoseini et al., "Target ion and neutral spread in high power impulse magnetron sputtering," Journal of Vacuum Science & Technology. A. Vacuum, Surfaces, and Films, vol. 41, no. 1, 2023.
[4]
M. Zanaska et al., "Dynamics of bipolar HiPIMS discharges by plasma potential probe measurements," Plasma sources science & technology, vol. 31, no. 2, s. 025007, 2022.
[5]
M. Rudolph et al., "Influence of the magnetic field on the discharge physics of a high power impulse magnetron sputtering discharge," Journal of Physics D : Applied Physics, vol. 55, no. 1, 2022.
[6]
S. S. Babu et al., "Modeling of high power impulse magnetron sputtering discharges with tungsten target," Plasma sources science & technology, vol. 31, no. 6, s. 065009, 2022.
[7]
M. Rudolph et al., "On the population density of the argon excited levels in a high power impulse magnetron sputtering discharge," Physics of Plasmas, vol. 29, no. 2, s. 023506, 2022.
[8]
M. Rudolph et al., "Operating modes and target erosion in high power impulse magnetron sputtering," Journal of Vacuum Science & Technology. A. Vacuum, Surfaces, and Films, vol. 40, no. 4, s. 043005, 2022.
[9]
H. Du et al., "Bipolar HiPIMS : The role of capacitive coupling in achieving ion bombardment during growth of dielectric thin films," Surface & Coatings Technology, vol. 416, 2021.
[10]
T. Shimizu et al., "Experimental verification of deposition rate increase, with maintained high ionized flux fraction, by shortening the HiPIMS pulse," Plasma sources science & technology, vol. 30, no. 4, 2021.
[11]
N. Brenning et al., "HiPIMS optimization by using mixed high-power and low-power pulsing," Plasma sources science & technology, vol. 30, no. 1, 2021.
[12]
S. Ekeroth et al., "Magnetically Collected Platinum/Nickel Alloy Nanoparticles as Catalysts for Hydrogen Evolution," ACS Applied Nano Materials, vol. 4, no. 12, s. 12957-12965, 2021.
[13]
H. Eliasson et al., "Modeling of high power impulse magnetron sputtering discharges with graphite target," Plasma sources science & technology, vol. 30, no. 11, 2021.
[14]
M. Rudolph et al., "On how to measure the probabilities of target atom ionization and target ion back-attraction in high-power impulse magnetron sputtering," Journal of Applied Physics, vol. 129, no. 3, 2021.
[15]
M. Rudolph et al., "On the electron energy distribution function in the high power impulse magnetron sputtering discharge," Plasma sources science & technology, vol. 30, no. 4, 2021.
[16]
N. Brenning et al., "Optimization of HiPIMS discharges : The selection of pulse power, pulse length, gas pressure, and magnetic field strength," Journal of Vacuum Science & Technology. A. Vacuum, Surfaces, and Films, vol. 38, no. 3, 2020.
[17]
M. Rudolph et al., "Optimizing the deposition rate and ionized flux fraction by tuning the pulse length in high power impulse magnetron sputtering," Plasma sources science & technology, vol. 29, no. 5, 2020.
[18]
H. Hajihoseini et al., "Sideways deposition rate and ionized flux fraction in dc and high power impulse magnetron sputtering," Journal of Vacuum Science & Technology. A. Vacuum, Surfaces, and Films, vol. 38, no. 3, 2020.
[19]
J. Keraudy et al., "Bipolar HiPIMS for tailoring ion energies in thin film deposition," Surface & Coatings Technology, vol. 359, s. 433-437, 2019.
[20]
S. Ekeroth et al., "Catalytic Nanotruss Structures Realized by Magnetic Self-Assembly in Pulsed Plasma," Nano letters (Print), vol. 18, no. 5, s. 3132-3137, 2018.
[21]
R. Gunnarsson et al., "Nucleation of titanium nanoparticles in an oxygen-starved environment. I : experiments," Journal of Physics D : Applied Physics, vol. 51, no. 45, 2018.
[22]
R. Gunnarsson et al., "Nucleation of titanium nanoparticles in an oxygen-starved environment. II : theory," Journal of Physics D : Applied Physics, vol. 51, no. 45, 2018.
[23]
A. Butler et al., "On three different ways to quantify the degree of ionization in sputtering magnetrons," Plasma sources science & technology, vol. 27, no. 10, 2018.
[24]
H. Nilsson et al., "Size of a plasma cloud matters The polarisation electric field of a small-scale comet ionosphere," Astronomy and Astrophysics, vol. 616, 2018.
[25]
D. Lundin et al., "A study of the oxygen dynamics in a reactive Ar/O high power impulse magnetron sputtering discharge using an ionization region model," Journal of Applied Physics, vol. 121, no. 17, 2017.
[26]
N. Brenning et al., "A unified treatment of self-sputtering, process gas recycling, and runaway for high power impulse sputtering magnetrons," Plasma sources science & technology, vol. 26, no. 12, 2017.
[27]
E. Kalered et al., "On the work function and the charging of small (r ≤ 5 nm) nanoparticles in plasmas," Physics of Plasmas, vol. 24, no. 1, 2017.
[28]
C. Huo et al., "Particle-balance models for pulsed sputtering magnetrons," Journal of Physics D : Applied Physics, vol. 50, no. 35, 2017.
[29]
N. Brenning et al., "Radiation from an electron beam in magnetized plasma : excitation of a whistler mode wave packet by interacting, higher-frequency, electrostatic-wave eigenmodes," Plasma Physics and Controlled Fusion, vol. 59, no. 12, 2017.
[30]
J. T. Gudmundsson et al., "An ionization region model of the reactive Ar/O-2 high power impulse magnetron sputtering discharge," Plasma sources science & technology, vol. 25, no. 6, 2016.
[31]
L. T. G. Hurtig, N. Brenning och H. Gunell, "Investigation Into Relativistic Magnetic Flux Amplification," IEEE Transactions on Plasma Science, vol. 44, no. 1, s. 2-6, 2016.
[32]
I. Pilch et al., "Nanoparticle growth by collection of ions : orbital motion limited theory and collision-enhanced collection," Journal of Physics D : Applied Physics, vol. 49, no. 39, 2016.
[33]
R. Gunnarsson et al., "The influence of pressure and gas flow on size and morphology of titanium oxide nanoparticles synthesized by hollow cathode sputtering," Journal of Applied Physics, vol. 120, no. 4, 2016.
[34]
N. Brenning et al., "The role of Ohmic heating in dc magnetron sputtering," Plasma sources science & technology, vol. 25, no. 6, 2016.
[35]
J. T. Gudmundsson et al., "Are the argon metastables important in high power impulse magnetron sputtering discharges?," Physics of Plasmas, vol. 22, no. 11, 2015.
[36]
G. D. Stancu et al., "Argon metastables in HiPIMS : Validation of the ionization region model by direct comparison to time resolved tunable diode-laser diagnostics," Plasma sources science & technology, vol. 24, no. 4, 2015.
[37]
T. Karlsson et al., "On the origin of magnetosheath plasmoids and their relation to magnetosheath jets," Journal of Geophysical Research - Space Physics, vol. 120, no. 9, s. 7390-7403, 2015.
[38]
A. A. Tal et al., "Molecular dynamics simulation of the growth of Cu nanoclusters from Cu ions in a plasma," Physical Review B. Condensed Matter and Materials Physics, vol. 90, no. 16, s. 165421, 2014.
[39]
C. Huo et al., "On the road to self-sputtering in high power impulse magnetron sputtering : particle balance and discharge characteristics," Plasma sources science & technology, vol. 23, no. 2, s. 025017, 2014.
[40]
H. Gunell et al., "Waves in high-speed plasmoids in the magnetosheath and at the magnetopause," Annales Geophysicae, vol. 32, no. 8, s. 991-1009, 2014.
[41]
I. Pilch et al., "Fast growth of nanoparticles in a hollow cathode plasma through orbit motion limited ion collection," Applied Physics Letters, vol. 103, no. 19, s. 193108, 2013.
[42]
M. I. Hasan et al., "Modeling the extraction of sputtered metal from high power impulse hollow cathode discharges," Plasma sources science & technology, vol. 22, no. 3, s. 035006, 2013.
[43]
C. Huo et al., "On sheath energization and Ohmic heating in sputtering magnetrons," Plasma sources science & technology, vol. 22, no. 4, s. 045005, 2013.
[44]
C. Vitelaru et al., "Plasma reactivity in high-power impulse magnetron sputtering through oxygen kinetics," Applied Physics Letters, vol. 103, no. 10, 2013.
[45]
I. Pilch et al., "Size-controlled growth of nanoparticles in a highly ionized pulsed plasma," Applied Physics Letters, vol. 102, no. 3, s. 033108, 2013.
[46]
N. Brenning et al., "Spokes and charged particle transport in HiPIMS magnetrons," Journal of Physics D : Applied Physics, vol. 46, no. 8, s. 084005, 2013.
[47]
J. Olson och N. Brenning, "The magnetospheric clock of Saturn-A self-organized plasma dynamo," Physics of Plasmas, vol. 20, no. 8, s. 082901, 2013.
[48]
D. Lundin et al., "Ti-Ar scattering cross sections by direct comparison of Monte Carlo simulations and laser-induced fluorescence spectroscopy in magnetron discharges," Journal of Physics D : Applied Physics, vol. 46, no. 17, s. 175201, 2013.
[49]
A. Aijaz et al., "A strategy for increased carbon ionization in magnetron sputtering discharges," Diamond and related materials, vol. 23, s. 1-4, 2012.
[50]
N. Brenning och D. Lundin, "Alfven's critical ionization velocity observed in high power impulse magnetron sputtering discharges," Physics of Plasmas, vol. 19, no. 9, s. 093505, 2012.
[51]
C. Vitelaru et al., "Argon metastables in HiPIMS : time-resolved tunable diode-laser diagnostics," Plasma sources science & technology, vol. 21, no. 2, s. 025010, 2012.
[52]
J. Olson och N. Brenning, "Dust-driven and plasma-driven currents in the inner magnetosphere of Saturn," Physics of Plasmas, vol. 19, no. 4, s. 042903, 2012.
[53]
C. Huo et al., "Gas rarefaction and the time evolution of long high-power impulse magnetron sputtering pulses," Plasma sources science & technology, vol. 21, no. 4, s. 045004, 2012.
[54]
J. T. Gudmundsson et al., "High power impulse magnetron sputtering discharge," Journal of Vacuum Science & Technology. A. Vacuum, Surfaces, and Films, vol. 30, no. 3, s. 030801, 2012.
[55]
T. Karlsson et al., "Localized density enhancements in the magnetosheath : Three-dimensional morphology and possible importance for impulsive penetration," Journal of Geophysical Research, vol. 117, s. A03227, 2012.
[56]
N. Brenning et al., "Understanding deposition rate loss in high power impulse magnetron sputtering : I. Ionization-driven electric fields," Plasma sources science & technology, vol. 21, no. 2, s. 025005, 2012.
[57]
M. Raadu et al., "An ionization region model for high-power impulse magnetron sputtering discharges," Plasma sources science & technology, vol. 20, no. 6, s. 065007, 2011.
[58]
D. Lundin et al., "Internal current measurements in high power impulse magnetron sputtering," Plasma sources science & technology, vol. 20, no. 4, s. 045003, 2011.
[59]
J. Olson et al., "On the interpretation of Langmuir probe data inside a spacecraft sheath," Review of Scientific Instruments, vol. 81, no. 10, s. 105106-1-105106-8, 2010.
[60]
V. Yaroshenko et al., "Characteristics of charged dust inferred from the Cassini RPWS measurements in the vicinity of Enceladus," Planetary and Space Science, vol. 57, no. 14-15, s. 1807-1812, 2009.
[61]
N. Brenning et al., "Faster-than-Bohm Cross-B Electron Transport in Strongly Pulsed Plasmas," Physical Review Letters, vol. 103, no. 22, 2009.
[62]
H. Gunell et al., "Numerical experiments on plasmoids entering a transverse magnetic field," Physics of Plasmas, vol. 16, no. 11, 2009.
[63]
D. Lundin et al., "Transition between the discharge regimes of high power impulse magnetron sputtering and conventional direct current magnetron sputtering," Plasma sources science & technology, vol. 18, no. 4, 2009.
[64]
N. Brenning et al., "A bulk plasma model for dc and HiPIMS magnetrons," Plasma sources science & technology, vol. 17, no. 4, 2008.
[65]
D. Lundin et al., "Anomalous electron transport in high power impulse magnetron sputtering," Plasma sources science & technology, vol. 17, no. 2, 2008.
[66]
D. Lundin et al., "Cross-field ion transport during high power impulse magnetron sputtering," Plasma sources science & technology, vol. 17, no. 3, 2008.
[67]
P. Appelgren et al., "Modeling of a small helical magnetic flux compression generator," IEEE Transactions on Plasma Science, vol. 36, no. 5, s. 2662-2672, 2008.
[68]
H. Gunell et al., "Simulations of a plasmoid penetrating a magnetic barrier," Plasma Physics and Controlled Fusion, vol. 50, no. 7, 2008.
[69]
P. Appelgren, N. Brenning och S. E. Nyholm, "Small helical magnetic flux compression generators : experiments and analysis," IEEE Transactions on Plasma Science, vol. 36, no. 5, s. 2673-2683, 2008.
[70]
G. Morfill et al., "The plasma state of soft matter," Europhysics News, vol. 39, no. 3, s. 30-32, 2008.
[71]
N. Brenning et al., "Radiation from an electron beam in a magnetized plasma : Whistler mode wave packets," Journal of Geophysical Research, vol. 111, no. A11, 2006.
[72]
J. Bohlmark et al., "The ion energy distributions and ion flux composition from a high power impulse magnetron sputtering discharge," Thin Solid Films, vol. 515, no. 4, s. 1522-1526, 2006.
[73]
N. Brenning, T. Hurtig och M. A. Raadu, "Conditions for plasmoid penetration across abrupt magnetic barriers," Physics of Plasmas, vol. 12, no. 1, 2005.
[74]
T. Karlsson et al., "On enhanced aurora and low-altitude parallel electric fields," Physica Scripta, vol. 72, no. 5, s. 419-422, 2005.
[75]
T. Hurtig, N. Brenning och M. A. Raadu, "The role of high frequency oscillations in the penetration of plasma clouds across magnetic boundaries," Physics of Plasmas, vol. 12, no. 1, 2005.
[76]
N. Brenning och C.-G. Fälthammar, "Dynamic trapping and skidding of dense plasma clouds," Physica Scripta, vol. 70, no. 03-feb, s. 153-156, 2004.
[77]
J. Bohlmark et al., "Measurement of the magnetic field change in a pulsed high current magnetron discharge," Plasma sources science & technology, vol. 13, no. 4, s. 654-661, 2004.
[78]
T. Hurtig, N. Brenning och M. A. Raadu, "The penetration of plasma clouds across magnetic boundaries : The role of high frequency oscillations," Physics of Plasmas, vol. 11, no. 7, s. L33-L36, 2004.
[79]
T. Hurtig, N. Brenning och M. A. Raadu, "Three-dimensional electrostatic particle-in-cell simulation with open boundaries applied to a plasma beam entering a curved magnetic field," Physics of Plasmas, vol. 10, no. 11, s. 4291-4305, 2003.
[80]
N. Brenning, "Interaction between a dust cloud and a magnetized plasma in relative motion," IEEE Transactions on Plasma Science, vol. 29, no. 2, s. 302-306, 2001.
[81]
H. Gunell, M. Larsson och N. Brenning, "Experiments on anomalous electron currents to a positive probe in a magnetized plasma stream," Geophysical Research Letters, vol. 27, no. 2, s. 161-164, 2000.
[82]
C.-G. Fälthammar och N. Brenning, "Magnetosphere-ionosphere interactions as a key to the plasma Univers," IEEE Transactions on Plasma Science, vol. 23, s. 2-9, 1995.
[83]
M. Bohm, N. Brenning och C.-G. Fälthammar, "Dynamic trapping of electrons in the porcupine ionospheric ion beam experiment," Advances in Space Research, vol. 12, s. 9-14, 1992.
[84]
N. Brenning et al., "Interpretation of the Electric Fields Measured in an Ionospheric Critical Ionization Velocity Experiment," Journal of Geophysical Research, vol. 96, s. 9719-9733, 1991.
[85]
N. Brenning et al., "Critical ionization velocity interaction in the CRIT I rocket experiment," Advances in Space Research, vol. 10, s. 63-66, 1990.
[86]
M. Bohm, N. Brenning och C.-G. Fälthammar, "Dynamic trapping : Neutralization of positive space charge in a collisionless magnetized plasma," Physical Review Letters, vol. 65, s. 859-866, 1990.
[87]
N. Brenning et al., "Electrodynamic interaction between the CRIT I ionized barium streams and the ambient ionosphere," Advances in Space Research, vol. 10, s. 67-70, 1990.
[88]
H. Alfvén et al., "Voyager saturnian ring measurements and the early history of the solar-system," Planetary and Space Science, vol. 34, no. 2, s. 145-154, 1986.
Konferensbidrag
[89]
J. T. Gudmundsson et al., "The current waveform in reactive high power impulse magnetron sputtering," i 2016 IEEE International Conference on Plasma Science (ICOPS), 2016.
[90]
D. Söderström et al., "Computer simulation of the collection probability of ions and neutrals on nanoparticles in a plasma," i 40th EPS Conference on Plasma Physics, EPS 2013 : Volume 2, 2013, s. 1578-1581.
[91]
T. Hurtig, N. Brenning och H. Gunell, "Relativistic magnetic flux amplification," i Digest of Technical Papers-IEEE International Pulsed Power Conference, 2013.
[92]
U. Helmersson et al., "A novel pulsed high-density plasma process for nanoparticle synthesis," i Technical Proceedings of the 2012 NSTI Nanotechnology Conference and Expo, NSTI-Nanotech 2012, 2012, s. 368-370.
[93]
I. Pilch et al., "Synthesis of copper nanoparticles by a high power pulse hollow cathode," i Technical Proceedings of the 2012 NSTI Nanotechnology Conference and Expo, NSTI-Nanotech 2012, 2012, s. 371-373.
[94]
D. Lundin et al., "Deposition rate loss in high power impulse magnetron sputtering : understanding through computational modeling," i 54th Annual Technical Conference Proceedings, Chicago, IL April 16-21,2011, 2011, s. 172-177.
Icke refereegranskade
Kapitel i böcker
[95]
D. Lundin et al., "Physics of high power impulse magnetron sputtering discharges," i High Power Impulse Magnetron Sputtering: Fundamentals, Technologies, Challenges and Applications, : Elsevier, 2019, s. 265-332.
[96]
J. T. Gudmundsson et al., "ON ELECTRON HEATING IN MAGNETRON SPUTTERING DISCHARGES," i 2017 IEEE International Conference on Plasma Science (ICOPS), : IEEE, 2017.
Rapporter
[97]
N. Brenning, "Current Limitation in Alfvén Wings," Stockholm : KTH Royal Institute of Technology, TRITA-ALP, TITA-ALP-1995-02, 1995.
[98]
O. Bolin och N. Brenning, "A Numerical Study of the Electrodynamical Interaction Between Comet Shoemaker-Levy 9 and Jupiter," KTH Royal Institute of Technology, TRITA-ALP, TRITA-ALP-1994-01, 1994.
[99]
O. Bolin och N. Brenning, "One-Dimensional Numerical Simulations of the Low-Frequency Electric Fields in the CRIT I and CRIT II Rocket Experiments," KTH Royal Institute of Technology, TRITA-ALP, TRITA-ALP-1992-01, 1992.
[100]
N. Brenning, C.-G. Fälthammar och M. Bohm, "An Extension of the Boltzmann Relation to Collisionless Magnetized Plasma," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-90-08, 1990.
[101]
M. Bohm, N. Brenning och C.-G. Fälthammar, "Dynamic Trapping of Electrons in the Porcupine Ionospheric Ion Beam Experiment," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-90-06, 1990.
[102]
I. Axnäs och N. Brenning, "Laboratory Experiments on the Magnetic Field and Neutral Density Limits on CIV Interaction," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, 90-01, 1990.
[103]
N. Brenning et al., "The Collective Gyration of a Heavy Ion Cloud in a Magnetized Plasma," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-90-07, 1990.
[104]
N. Brenning, M. Bohm och C.-G. Fälthammar, "Dynamic Trapping of Electrons in Space Plasmas," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, 89-07, 1989.
[105]
N. Brenning, "On the Spoke Structure in Critical Velocity Rotating Plasmas," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, 89-01, 1989.
[106]
I. Axnäs och N. Brenning, "Experiments on the Magnetic Field and Neutral Density Limits on CIV Interaction," , TRITA-EPP, TRITA-EPP-88-08, 1988.
[107]
K. Sauer et al., "A Fluid Simulation of the AMPTE Lithium Gas Releases in the Solar Wind," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, 87-06, 1987.
[108]
G. Marklund et al., "On Transient Electric Fields Observed in Chemical Release Experiments by Rockets," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-86-01, 1986.
[109]
N. Brenning, "On the Role of the Ionization Frequency to Gyrofrequency Ratio in the Critical Ionization Velocity Interaction," KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-86-10, 1986.
[110]
N. Brenning, "Testing a Very Good Microwave Interferometer," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-86-09, 1986.
[111]
H. Alfvén et al., "Further Explorations of Cosmogonic Shadow Effects in the Saturnian Rings," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, 85-03, 1985.
[112]
N. Brenning, "On the Role of the Magnetic Field Strength in Critical Ionization Velocity Interaction," KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-85-01, 1985.
[113]
H. Alfvén et al., "Voyager Saturnian Ring Measurements and the Early History of the Solar System," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, 85-07, 1985.
[114]
I. Axnäs, N. Brenning och G. Gahm, "Plasma processes in the excitation of Herbig-Haro objects," KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-84-09, 1984.
[115]
N. Brenning, "An Improved Microwave Interferometer Technique for Plasma Density Measurements," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, 83-08, 1983.
[116]
N. Brenning, "A Necessary Condition for the Critical Ionization Velocity Interaction," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, 82-01, 1982.
[117]
N. Brenning, "Review of Impact Experiments on the Critical Ionization Velocity," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, 82-14, 1982.
[118]
N. Brenning, "An Appendix to the Paper Te determination in low-density plasmas from the HeI 3889 Å and 5016 Å line intensities," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-81-03, 1981.
[119]
N. Brenning, L. Lindberg och A. Eriksson, "Energization of Electrons in a Plasma Beam Entering a Curved Magnetic Field," KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-80-09, 1980.
[120]
N. Brenning, "Experiments on the Critical Ionization Velocity Interaction in Weak Magnetic Fields," KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-80-10, 1980.
[121]
N. Brenning, "Electron Temperature Determination from the He I 3889Å and 5016Å Line Intensities," KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-79-06, 1979.
[122]
E. Petelski et al., "Enhanced Interaction of the Solar Wind and the Interstellar Neutral Gas by Virtue of a Critical Velocity Effect," KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-79-19, 1979.
[123]
N. Brenning, ""Horizontal" Thermal Equilibrium due to Excitation Transfer Between Excited States of Neutral He in Transient Plasma," , TRITA-EPP, TRITA-EPP-78-02, 1978.
[124]
N. Brenning, "Electron temperature measurements in low density plasmas by helium spectroscopy II - parameter limits for validity of different methods," Stockholm : KTH Royal Institute of Technology, TRITA-EPP, 78-16, 1978.
[125]
N. Brenning, "Electron Temperature Measurements in Low Density Plasmas by Helium Spectroscopy," KTH Royal Institute of Technology, TRITA-EPP, TRITA-EPP-77-24, 1977.
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2024-04-24 00:27:53