Reference List — H.Mk.0 Internal Design Paper

Comprehensive reference listing for the H.Mk.0 Internal Design Paper: 230830: 779; 200105: 202

H. Industries
59 min readJan 5, 2020

This is the comprehensive reference list, most but not all have been skimmed through and archived as they support the notes and references in the ever growing detailed literature review in the technology knowledge document. As of 230830 that knowledge base is over 171k words of peer reviewed reference notes and there are several dense physical textbooks covered in red pen which haven’t made it in yet. Some hotlinks are included from recent research reading though all articles will be linked eventually.

  1. Abrikosov, AA, 2004. Nobel lecture: Type-II superconductors and the vortex lattice.
  2. Abrikosov, A A, 1957. On the magnetic properties of superconductors of the second type.
  3. Ageyev, A I, Andreev, N I, Balbekov, V I, Dolzhenkov, V I, Gertsev, K F, Gridasov, V I, Myznikov, K P, Smirnov, N L, Sychev, V A, Sytnik, V V, Tarakanov, N M, Tkachenko, L M, Vasiliev, L M, Zinchenko, S I & Zlobin, A V, 1992. The development and study of superconducting magnets for the UNK.
  4. Ageyev, A I, Balbekov, V I, Dmitrevsky, Y P, Dunaitsev, A F, Fedotov, Y S,Gridasov, V I, Komarov, V V, Kurnayev, O V, Lebedev, V N, Logunov, A A, Myznikov, K P, Naumov, A A, Rogozinsky, V G, Shembel, B K, Soloviev, L D, Tarakanov, N M, Yarba, V A, Artemov, A D, Dinaburg, L D, Glukhikh, V A, Gusev, O A, Karasev, V G, Kosyakin, M N, Malyshev, I F, Monoszon, N A, Mozalevsky, I A, Mozin, I V, Peregud, V I, Titov, V A, Vasiliev, S N, Gyul’khandanyan, A M, Makeyev, E L, Shiryaev, F Z, Vasiliev, A N, Vorontsov, G P, Kuz’min, A A, Vagin, A I, Yelyan, V V, Belyakov, V P, Butkievich, I K, Filin, N V, Grigorehko, N M, Kovalenko, V D & Morkovkin, I M, 1980. The IHEP accelerating and storage complex (UNK) status report.
  5. Aguglia, D, 2013. Pulse transformer design for magnet powering in particle accelerators.
  6. Aguglia, D, Cravero, J, Rebeschini, R, Iovieno, S & Russo, C, 2015. Design Solutions for Compact High Current Pulse Transformers for Particle Accelerators’ Magnet Powering.
  7. Ahn, HM, Lee, JK & Kim, JK, 2011. Finite-element analysis of short-circuit electromagnetic force in power transformer.
  8. Ahn, HM, Oh, YH & Kimetal, JK, 2012. Experimental verification and finite element analysis of short-circuit electromagnetic force for dry-type transformer.
  9. Ahn, HM, Kim, SY, Kim, JK, Oh, YH & Hang, SC, 2016. Numerical investigation for transient electromagnetic force computation of power transformer during short-circuit condition.
  10. Aird, G, Simkin, J, Taylor, S, Trowbridge, C, Xu, E, 2006. Coupled transient thermal and electromagnetic finite element simulation of quench in superconducting magnets.
  11. Akihama, R, Yasukochi, K & Ogasawara, T, 1977. The effects of indium addition on the properties of internal tin diffusion processed Nb3Sn wires.
  12. Alekseev, P A, Boev, A I, Keilin, V E, Kovalev, I A, Kruglov, S L, Lazukov, V N & Sadikov, I P, 2004. Experimental evidence of considerable stability increase in superconducting windings with extremely high specific heat substances.
  13. Alekseev, P A, Boev, A I, Keilin, V E, Kovalev, I A, Kozub, S S, Kostrov, E A, Kruglov, S L, Lazukov, V N, Sadikov, I P, Shutova, D I, 2006. Influence of high heat capacity substances doping on quench currents of fast ramped superconducting oval windings.
  14. Alekseev, P A, Keilin, V E, Kovalev, I A, Kruglov, S L, Lazukov, V N, Medvedev, M I & Shutova, D I, 2007. Investigation of considerable stability increase of composite superconductors doped with extremely large heat capacity substances.
  15. Algarni, A, Gleason, F & Mohanakumaran, A, 2014. Electromagnetic Ring Launcher.
  16. Ali, A, Ali, H, Mughal M & Reyneri, L, 2012. Components selection for a simple boost converter on the basis of power loss analysis.
  17. Allen, J & Misener, A, 1938. Flow of liquid Helium II.
  18. Al Sakka, M, Gualous, H, Van Mierlo, J, Culcu, H, 2009. Thermal modeling and heat management of supercapacitor modules for vehicle applications.
  19. Ambrosio, G, 2015. Nb3Sn High Field Magnets for the High Luminosity LHC Upgrade Project.
  20. An, B, Liu, SK, Guo, Z & Liu, SK, 2015. Characteristic research of electromagnetic force for mixing suspension electromagnet used in low-speed maglev train.
  21. An, SM, Wu, H, Feng, X & Liu, WX, 1984. Space Flight test of electric thruster system MDT-2A.
  22. Anderson, JL, Ding, J, Welton, T & Armstrong, DW, 2002. Characterizing ionic liquids on the basis of multiple solvation interactions.
  23. Anderson, P W, 1962. Theory of flux creep in hard superconductors.
  24. Anerella, M, Cottingham, J, Cozzolino, J, Dahl, P, Elisman, Y, Escallier, J, Foelsche, H, Ganetis, G, Farber, M, Ghosh, A, Goodzeit, C, Greene, A, Gupta, R C, Harrison, M, Herrera, J, Jain, A, Khan, S, Kelly, E, Killian, E, Lindner, M, Louie, W, Marone, A, Morgan, G, Morgillo, A, Mulhall, S, Muratore, J, Plate, S, Prodell, A, Rehak, M, Rohrer, E, Sampson, W, Schmalzle, J, Schneider, W, Shutt, R, Sintchak, G, Skaritka, J, Thomas, R, Thompson, P, Wanderer, P J & Willen, E, 2003. The RHIC magnet system.
  25. Anouti, M, Couadou, E, Timperman, L & Galiano, H, 2012. Protic ionic liquid as electrolyte for high-densities electrochemical double layer capacitors with activated carbon electrode material.
  26. ANSYS® Academic Research, Release 17.1. Help System, MechanicalTM, ANSYS, Inc.
  27. Anzel, BM, 1995. U.S. Patent no. 5,443,231.
  28. Arbelaez, D, Prestemon, SO, Ferracin, P, Godeke, A, Dietderich, DR & Sabbi, G, 2010. Cable deformation simulation and a hierarchical framework for Nb3Sn Rutherford cables.
  29. Arkadiev, V, 1945. Hovering of a Magnet Over a Superconductor.
  30. Arkadiev, V, 1947. A Floating Magnet.
  31. Askenazy, S, 1998. A Leuven type coilin in a coilex for 100 T non-destructive magnets.
  32. Ašner, F M, 1999. High field superconducting magnets.
  33. Atherton, D & Eastham, A, 1975. Superconducting maglev and LSM development in Canada.
  34. Austin, RE, Dod RE & Grim, D, 1978. Solar Electric Propulsion for the Halley’s Comet Rendezvous Mission: Foundation for Future Missions.
  35. Austin, RE, 1979. Solar Electric Propulsion System (SEPS): Tomorrow’s Propulsion System — Today.
  36. Baba, J, Nitta, T, Shirai, Y, Akita, S, Hayashi, Y & Kobayashi, Y, 2001. Power Converter for SMES by use of ICB energy transfer circuit.
  37. Bacon, JL, Baca, A, Coe, H, Kihara, K, Manzo, M, Schillig, J, Sims, J & Eyssa, Y, 2000. First 100 T non-destructive magnet outer coil set.
  38. Bacon, JL, Ammerman, C, Coe, H, Ellis, G, Lesch, B, Sims, J, Schillig, J & Swenson, C, 2002. The US NHMFL 100 Tesla multishot magnet.
  39. Bahmanyar, H, 1973. Novel transport systems with particular reference to contact free suspension.
  40. Balanis, CA, 1989. Advanced Engineering Electromagnetics.
  41. Balducci, A, Dugas, R, Taberna, P, Simon, P, Plee, D, Mastragostino, M & Passerini, S, 2007. High Temperature Carbon-Carbon Supercapacitor Using Ionic Liquid As Electrolyte.
  42. Ball, MN, Clee, PT, Cunliffe, N & Simkin, J, 1975. A superconducting magnet for a polarised target nuclear physics experiment.
  43. Bamji, PJ, 1974. Some Applications of a Linear Electric Machine for Handling Molten Aluminum.
  44. Bamji, PJ, 1978. Unconventional electrical machine for circulating molten metal.
  45. Bamji, PJ & Pierson, FW Jr, 1983. Electromagnetic Circulation Of Molten Aluminium.
  46. Barzi, E, Andreev, N, Karppinen, M, Lombardo, V, Nobrega, F, Turrioni, D, Yamada, R & Zlobin, A V, 2012. Development and Fabrication of Nb3Sn Rutherford Cable for the 11 T DS Dipole Demonstrator Model.
  47. Barzi, E & Zlobin, AV, 2016. Research and Development of Nb3Sn Wires and Cables for High-Field Accelerator Magnets.
  48. Bayliss, A & Turkel, E, 1980. Radiation boundary conditions for wave-like equations.
  49. Baynham, DE, Edwards, V & Wilson, M, 1981. Transient stability of high current density superconducting wires.
  50. Beattie, JR & Matossian, JM, 1990. Xenon ion sources for space applications.
  51. Bedford, BD, Peer, LHB & Tonks, L, 1939. The Electromagnetic Levitator.
  52. Bednorz, J G & Müller, K A, 1986. Possible High Tc Superconductivity in the Ba-La-Cu-O System.
  53. Bennemann, K H & Ketterson, J B, eds, 2003. The Physics of Superconductors.
  54. Benvenuti, C, 1983. A new pumping approach for the large electron positron collider (LEP).
  55. Beth, R, 1966. Complex representation and computation of two-dimensional fields.
  56. Beth, R, 1967. An integral formula for two-dimensional fields.
  57. Binns, K, Lawrenson, P & Trowbridge, C, 1992. The analytical and numerical solutions of electric and magnetic fields.
  58. Bird, MD, Bole, S, Eyssa, YM, Gao, BJ & Schneider-Muntau, HJ, 2000. Test results and potential for upgrade of the 45 T hybrid insert.
  59. Bird, AD, Dixon, IR & Toth, J, 2004. Design of the next generation of Florida-Bitter magnets at the NHMFL.
  60. Bird, M, Gavrilin, A, Gundlach, S, Han, K, Swenson, C & Eyssa, Y, 2006. Design & Testing of a repetitively pulsed magnet for neutron scattering.
  61. Boattini, F & Genton, C, 2015. Accelerated lifetime testing of energy storage capacitors used in particle accelerator power converters.
  62. Bober, AS, Kim, VP, Koroteev, AS, Latyshev, LA, Morozov, AI, Popov, GA, Rylov, YP & Zhurin, VV, 1991. State of works on electrical thrusters in the USSR.
  63. Bober, AS, Maslennikov, N, Day, M, Popov, G & Rylov, Y, 1993. Development and application of electric propulsion thrusters in Russia.
  64. Boebinger, GS, Lacerda, AH, Schneider-Muntau, HJ & Sullivan, N, 2001. The National High Magnetic Field Laboratory’s pulsed magnetic field facility in Los Alamos.
  65. Bogdanov, I, Kozub, S, Shcherbakov, P & Tkachenko, L, 2004. Study of Electrical Steel Magnetic Properties for Fast Cycling Magnets of SIS100 and SIS300 Rings.
  66. Bogdanov, I, Kozub, S, Shcherbakov, P, Tkachenko, L, Zintchenko, S & Zubko, V, 2004. Study of the Quench Process in Fast-cycling Dipole for the SIS300 Ring
  67. Bogdanov, I, Chirkov, P, Keilin, V, Kozub, S, Shcherbakov, P, Slabod- chikov, P, Sytnik, V, Tkachenko, L M, Zintchenko, S & Zubko, V, 2004. Final Report on the Research and Development Contract: Design of 6T Superconducting Dipoles for SIS 300.
  68. Bohlen, O, Kowal, J & Uwe Sauer, D, 2007. Ageing behaviour of electrochemical double layer capacitor: Part II. Lifetime simulation model for dynamic applications.
  69. Bolton, SJ, Lunine, J, Stevenson, D, Connerney, JEP, Levin, S, Owen, TC, Bagenal, F, Gautier, D, Ingersoll, AP, Orton, GS, Guillot, T, Hubbard, W, Bloxham, J, Coradini, A, Stephens, SK, Mokashi, P, Thorne, R & Thorpe, R, 2017. The Juno Mission.
  70. Boom, F & Livingstone, R, 1962. Proceedings of IRE.
  71. Borcherts, RH & Davis, LC, 1972. Force on a coil moving over a conducting surface including edge and channel effects.
  72. Borcherts, RH, Davis, LC, Reitz, JR & Wilkie, DF, 1973. Baseline specifications for a magnetically suspended high-speed vehicle.
  73. Bordry, F, Burnet, JP & Voelker, F, 2005. CERN-PS Main Power Converter Renovation: How to Provide and Control the Large Flow of Energy for A Rapid Cycling Machine
  74. Borthomieu, Y, Prevot, D & Massot, J, 2011. VES100/140 Lithium-Ion Cells LEO Life-Test Results & Proteus Flight Heritage.
  75. Borthomieu, Y, 2014. Satellite Lithium-Ion Batteries.
  76. Bortis, D, Biela, J & Kolar, J, 2007. Optimal design of a DC reset circuit for pulse transformers.
  77. Bortis, D, Biela, J & Kolar, J, 2008. Design and control of an active reset circuit for pulse transformers.
  78. Bortot, L, Auchmann, B, Cortes Garcia, I, Fernandez Navarro, AM, Maciejewski, M, Prioli, M, Schöps, S & Verweij, AP, 2018.A 2-D finite-element model for electrothermal transients in accelerator magnets.
  79. Bottura, L, 1999. A practical fit for the critical surface of NbTi..
  80. Bottura, L, 2013. Magnet Quench 101.
  81. Brachtendorf, HG, Welsch, G, Laur, R & Bunse-Gerstner, A, 1996. Numerical steady state analysis of electronic circuits driven by multi-tone signals.
  82. Bragin, A, Khrushchev, S, Kubarev, V, Mezencev, N, Tsukanov, V, Sozinov, G, Shkaruba, V, 2016. Superconducting solenoid for superfast Thz spectroscopy.
  83. Brandt, B, Hannahs, S, Schneider-Muntau, H, Boebinger, G & Sullivan, N, 2001. The national high magnetic field laboratory.
  84. Brillouin, L, 1953. Wave Propagation in Periodic Structures.
  85. Brooks, JS, Balicas, L, Tokumoto, M, Terashima, T ,Echizen, Y & Takabatake, T, 2001. First studies in the 45T hybrid magnet at the NHMFL-Tallahassee: the high-field phases of organic and Kondo systems
  86. Brophy, JR, 2022. Perspectives on the success of electric propulsion.
  87. Brophy JR, Friedman, L & Culick, F, 2012. Asteroid retrieval feasibility.
  88. ​​Brophy, JR & Oleson, S, 2012. Spacecraft Conceptual Design for Returning Entire Near-Earth Asteroids.
  89. Brophy, J, Pellegrino S & Lubin, P, 2022. Non-Nuclear Exploration of the Solar System.
  90. Brousse, T, Taberna, P, Crosnier, O, Dugas, R, Guillemet, P, Scudeller, Y & Zhou, Y, 2007. Long-term cycling behavior of asymmetrical activated carbon MnO2 aqueous electrochemical supercapacitor.
  91. Brunk, W & Walz, D, 1975. A new pulse magnet design utilising tape wound cores.
  92. Brüning, OS, Collier, P, Lebrun, P, Myers, S, Ostojic, R, Poole, J & Proudlock, P, 2004. LHC Design Report. CERN-2004–003-V-1
  93. Brüning, O & Fartoukh, S, 2001. Field quality specification for the LHC main dipole magnets.
  94. Bryce Space and Technology, 2017. State of the Satellite Industry Report. 20th Ed.
  95. Buchhold, TA, 1962. Patent US-3044309, Gyroscope.
  96. Buehler, W & Levinstein, H J, 1965. Effect of tensile stress on the transition temperature and current-carrying capacity of Nb3Sn.
  97. Burgess, P, 2009. Variation in Light intensity at different latitudes and seasons, effects of cloud cover and the amounts of direct and diffused light.
  98. Burke, A, 2000. Ultracapacitor: Why, how and where is the technology.
  99. Burlak, GN, Kotsarenko, NY & Koshevaya, SV, 1981. Interaction of electromagnetic and acoustic waves in solids.
  100. Bushyager, N & Tentzeris, MN, 2006. MRTD (Multi Resolution Time Domain) Method in Electromagnetics.
  101. Bussward, RW, 1998. Nuclear Rockets. pp. 179–273 in: Turchi, PJ, 1998. Propulsion Techniques: Action And Reaction.
  102. Buta, T, 2015. The research of the mechanical characteristic of polyimide foil. [M].
  103. Cabanes, J, Garlasche, M, Bordini, B & Dallocchio, A, 2016. Simulation Of The Cabling Process for Rutherford cables: An advanced finite element model.
  104. Cabello, M, Bai, X, Chyrka, T, Ortiz, GF, Lavella, P, Alcantara, P & Tirado, JL, 2017. On the Reliability of Sodium Co-Intercalation in Expanded Graphite Prepared by Different Methods as Anodes for Sodium-Ion Batteries.
  105. Cambell, 2011. An introduction to Numerical Methods in Superconductors.
  106. Campbell, L, Boenig, HJ, Rickel, D, Schillig, JB, Schneider-Muntau, HJ & Sims, JR, 1996. The NHMFL long-pulse magnet system — 60–100 T.
  107. Cappelletti, C, Battistini, S & Malphrus, BK, 2020. CubeSat Handbook: From Mission Design to Operations.
  108. Caspi, S, Chiesa, L, Ferracin, P, Gourlay, SA, Hafalia, R, Hinkins, R, Lietzke, AF & Prestemon, S, 2003. Calculating quench propagation with ANSYS.
  109. Cassedy, E & Oliner, A, 1963. Dispersion relations in time-space periodic media: Part I — Stable interactions.
  110. Castric, A F, Lawson, S & Borthomieu, Y, 2011. High energy lithium-ion VES cells and batteries performance.
  111. Chaboche J L, 1989. Constitutive equations for cyclic plasticity and cyclic viscoplasticity.
  112. Chandrasekharaiah, DS & Debnath, L, 1994. Continuum Mechanics.
  113. Chang, H & Wang, L , 2010. A Simple Proof of Thue’s Theorem on Circle Packing.
  114. Chang, JK, Lee, MT & Tsai, WT, 2007. In situ Mn K-edge X-ray absorption spectroscopic studies of anodically deposited manganese oxide with relevance to supercapacitor applications.
  115. Chao, C & Grantham, C, 2006. Design Optimisation for a Superconducting Solenoid of High Temperature Superconductor Tape for Energy Storage Purposes.
  116. Chao, C & Grantham, C, 2004. Iron Cored High Temperature Superconducting inductors for large Electric Power Applications.
  117. Charifoulline, Z, 2006. Residual resistivity ratio (RRR) measurements of LHC superconducting NbTi cable strands.
  118. Chakrabarty, D, Seth, D, Chakraborty, A & Sarkar, N, 2005. Dynamics of solvation and rotational relaxation of coumarin 153 in ionic liquid confined nanometer-sized microemulsions.
  119. Cheggour, N & Hampshire, D P, 1999. Unifying the strain and temperature scaling laws for the pinning force density in superconducting niobium-tin multifilamentary wires.
  120. Cheggour, N & Hampshire, D P, 2002. The unified strain and temperature scaling law for the pinning force density of bronze-route Nb3Sn wires in high magnetic fields.
  121. Cheggour, N, Goodrich, LF, Stauffer, TC, Splett, JD, Lu, XF, Ghosh, AK & Ambrosio, G, 2010. Influence of Ti and Ta doping on the irreversible strain limit of ternary Nb3Sn superconducting wires made by the restacked-rod process.
  122. Chen, H, Liu, M, Jia, C, Zhang, C & Wang, Z, 2007. Low power IC design of the wireless monitoring system of the orthopedic implants.
  123. Chen, J, Kang, S, Zou, J, Liu, C & Schutt-Ainé, J, 2004. Reduced-order modeling of weakly nonlinear MEMS devices with Taylor-series expansion and Arnoldi approach.
  124. Chen, W & Saleeb, A, 1994. Constitutive Equations for Engineering Materials, Volume II: Plasticity and Modelling.
  125. Cheng, AF, Schwartz, Barnouin, OS, Bagatin, AC, Miller, P, Pravec, P, Richardson, DC, Rivkin, AS, Stickel, S, Tsiganis, K & Ulamec, S, 2017. Asteroid Impact and Deflection Assessment: Double Asteroid Redirection Test.
  126. Cheok, AD & Ertugrul, N, 2001. Computer-Based Automated Test Measurement System for Determining Magnetization Characteristics of Switched Reluctance Motors.
  127. Chien, KR, Hart, SL, Tighe, WG, De Pano, MK, Bond, TA & Spears, R, 2005. L-3 Communications ETI Electric Propulsion Overview.
  128. Cho, H, Kim, C, Lee, J & Han, H, 2011. Design and characteristic analysis of small scale magnetic levitation and propulsion system for maglev train application.
  129. Choi, CTM & Sun, SH, 2006. Numerical performance and applications of the envelope ADI-FDTD method.
  130. Choi, D, Blomgren, GE & Kumta, PN, 2006. Fast and Reversible Surface Redox Reaction in Nanocrystalline Vanadium Nitride Supercapacitors.
  131. Choi, J, Kim, S K, Kim, S, Sim, K, Park, M, & Yu, I K, 2016. Simulation and Experimental Demonstration of a Large Scale HTS AC Induction Furnace for Practical Design.
  132. Chorowski, M, Lebrun, P, Serio, L & Van Weelderen, R, 1998. Thermohydraulics of quenches and helium recovery in the LHC prototype magnet strings.
  133. Choueiri, EY, 2004. A Critical History of Electric Propulsion: The First 50 Years (1906–1956)
  134. Ciaralli, S, Coletti, M & Gabriel, SB, 2016. Results of the Qualification Test Campaign of a Pulsed Plasma Thruster for Cubesat Propulsion (PPTCUP).
  135. Coccoli M, Scanlan RM, Calvi M, Caspi S, Chiesa L, Hafalia R, Higley, H C, Dietderich, D R, Gourlay, S A, Lietzke, A, McInturff, A D & Sabbi, G, 2004. Fabrication and Performance of Nb3Sn Rutherford-Type Cable With Cu Added as a Separate Component.
  136. Cockrell, JJ, 2021. Small Spacecraft Technology Program Guidebook for Technology Development Projects.
  137. Coffey, HT, Hulm, JK, Reynolds, WT, Fox, DK & Span, RE, 1965. A Protected 100kg Superconducting Magnet.
  138. Cohon, J, 1978. Multiobjective programming and planning.
  139. Conway, B, 1999. Electrochemical supercapacitors: Scientific Fundamentals And Technological Applications.
  140. Cook, RD, Malkus, DS, Plesha, ME & Witt, RJ, 2001. Concepts and applications of finite element analysis.
  141. Cooley, L D, Fischer, C M, Lee, P J, & Larbalestier, D C, 2004. Simulations of the effects of tin-composition gradients on the superconducting properties of Nb3Sn conductors.
  142. Coperich, KM, Okhmatovski, JMVI, Cangellaris, AC & Ruehli, AE, 2001. Systematic development of transmission-line models for interconnects with frequency-dependent losses.
  143. Costa, F, Felipe, C & De Andrade, R, 2018. Characterization of levitation force for a superconducting magnetic levitation vehicle.
  144. Costen, RC & Adamson, D, 1965. Three dimensional derivation of the electromagnetic jump condition and momentum–energy laws at a moving boundary.
  145. Crank, J & Nicolson, P, 1996. A practical method for numerical evaluation of solutions of partial differential equations of the heat-conduction type.
  146. Cravero, J, Maire, G & Royer, J, 2007. High current capacitor discharge power converters for the magnetic lenses of a neutrino beam facility.
  147. Cuentas-Gallegos, AK, Lira-Cantú, M, Casan-Pastor, N & Gómez-Romero, P, 2005. Nanocomposite hybrid molecular materials for applications in solid-state electrochemical supercapacitors.
  148. Cui, P, Zhang, K & Li, J, 2010. Calculation of electromagnetic force and torque of suspension electromagnet based on Schwarz- Christoffel transform.
  149. Dahir, AR, 2020. Lost in Space: Autonomous Deep Space Navigation.
  150. Dahlerup-Peterson, K, Kazmine, B, Popov, V, Sytchev, L, Vassiliev, L, Zubko, V, 2000. Energy Extraction Resistors for the Main Dipole and Quadrupole Circuits of the LHC.
  151. Davis, LC, 1972. Drag force on a magnet moving near a thin conductor.
  152. Delgado, JJ, Corey, RL, Murashko, VM, Koryakin, AI & Pridanikov, SY, 2014. Qualification of the SPT-140 for use on western spacecraft.
  153. Deng Z, Zhang W, Zheng J, Ren Y, Jiang D, Zheng X, Zhang J, Gao P, Lin Q, Song B and Deng C. A High-Temperature Superconducting Maglev Ring Test Line Developed in Chengdu.
  154. Deng, Z, Zhang, W, Zheng, J, Wang, B, Ren, Y, Zheng, X & Zhang J, 2017. A High-Temperature Superconducting Maglev–Evacuated Tube Transport (HTS Maglev–ETT) Test System.
  155. Denz, R & Rodriguez-Mateos, F, 2001. Detection of Resistive Transitions in LHC Superconducting Components.
  156. Devered, A, Bredy, P, Durante, M, Gourdin, C, Rey, JM & Reytier, M, 1999. Insulation systems for Nb3Sn accelerator magnet coils fabricated by the “wind and react” technique.
  157. De Gennes, PG, 1966. Superconductivity of Metals and Alloys.
  158. De Gersem, H & Weiland, T, 2004. Finite element models for superconductive cables with finite interwire resistance.
  159. De Grys, KH, Welander, B, Dimicco, J, Wenzel, S, Kay, B, Khayms, V & Paisley, J, 2005. 4.5 kW Hall Thruster System Qualification Status.
  160. De Menezes, LRAX & Hoefer, WJR, 1996. Modeling of general constitutive relationships in SCN TLM.
  161. Diab, Y, Venet, P, Gualous, H & Rojat, G, 2009. Self-Discharge Characterization and modeling of electrochemical capacitor used for power electronics applications.
  162. Ding, H, Ding, T, Jiang, C, Xu, Y, Xiao, H, Li, L, Duan, X & Pan, Y, 2010. Design of Power Supplies for the Pulsed High Magnetic Field Facility at HUST.
  163. Ding, H, Jiang, X, Ding, T, Xu, Y, Li, L, Duan, X, Pan, Y & Herlach, F, 2010. Prototype test and manufacture of a modular 12.5 MJ capacitive pulsed power supply.
  164. Ding, H, Hu, J, Liu, W, Xu, Y, Jiang, C, Ding, T, Xianzhong, D & Pan, Y, 2012. Design of a 135 MW Power Supply for a 50 T Pulsed Magnet.
  165. Ding, H, Liu, W, Duan, X, Li, L & Herlach, F, 2012. Design and analysis of a combined power supply for high-field quasi-continuous magnets,
  166. Ding, H, Jiang, C, Xu, Y, Ding, T, Zou, X, Li, L & Pan, Y, 2013. Test and operation of the WHMFC 12.6 MJ capacitor bank power supply systems.
  167. Ding, H, Yuan, Y, Xu, Y, Jiang, C, Li, L, Duan, X, Pan, Y & Hu, J, 2014. Testing and commissioning of a 135 MW pulsed power supply at the Wuhan National High Magnetic Field Centre.
  168. Ding, H, Ren, T, Xu, Y, Ding, T, Zhao, Z, Peng, T, Li, L, & Hu, J, 2016. Design and analysis of power supplies for the first 100T nondestructive magnet at the WHMFC.
  169. Ding, H, Zhao, Z, Zhou, J, Xie, J, Shi, J, Huan, Y, Wang, J, Wang, Q & Li, L, 2017. A flexible capacitive pulsed power supply to the high magnetic fields for the magnetisation measurement.
  170. Ding, H, Zhao, Z, Jiang, C, Xu, Y, Ding, T, Fang, X, Ren, T, Li, L, Pan, Y & Peng, T, 2018. Construction and Test of Three-Coil Magnet Power Supply System for a High-Pulsed Magnetic Field.
  171. Ding, T, Wang, J, Ding, H, Li, L, Liu, B & Pan, Y, 2012. A 35 kA disc-shaped thyristor DC switch for batteries power supply of flat-top pulsed magnetic field.
  172. Ding, T, Lv, Y, Tang, J, Chen, X, Li, L & Pan, Y, 2013. The design and tests of battery power supply system for pulsed flat top magnets in WHMFC.
  173. Ding, T, Ma, Y, Chen, H, Lv, Y, Han, X, Li, L & Pan, Y, 2014. Analysis & experiment of battery bank power supply system for long pulse helical magnet in WHMFC.
  174. Dixon, I R, Markiewicz, W D, Pickard, K W & Swenson, C A, 1999. Critical current and n-value Nb3Sn conductors for the wide bore 900 MHz.
  175. Dolara, A, Faranda, R & Leva, S, 2009. Energy comparison of seven MPPT techniques for PV systems.
  176. Dresner, L, 1995. Stability of Superconductors. Selected Topics In Superconductivity.
  177. Drost, E, Specking, W & Flükiger, R, 1985. Comparison of superconducting properties and residual resistivities of bronze processed Nb3Sn wires with Ta, Ti and Ni + Zn additives.
  178. Duchemin, OB, Caratge, A, Cornu, N, Sannino, JM, Lassoudière, F & Lorand, A, 2011. Ariane 5-ME and Electric Propulsion: GEO Insertion Options.
  179. Dudley, G, Hendel, B & Borthomieu, Y, 2011. GEO and LEO life tests of SAFT lithium ion batteries after ten years of cycling.
  180. Duncan, CB, Smith, AE & Aguirre, FH, 2014. Iris transponder–Communications and navigation for deep space.
  181. Dunlop, J D, Rao, M & Yi, T, 1993. NASA Handbook for Nickel Hydrogen Batteries.
  182. Du Pasquier, A, Plitz, I, Gural, J, Badway, F & Amatucci, GG, 2004. Power-ion battery: bridging the gap between li-ion and supercapacitor chemistries.
  183. Earnshaw, S, 1842. On the Nature of the Molecular Forces which Regulate the Constitution of the Luminferous Ether.
  184. Eastham, JF & Laithwaite, ER, 1973. Linear-motor topology.
  185. Eastham, JF & Laithwaite, ER, 1974. Linear induction motors as electromagnetic rivers.
  186. Edwards, J, 1983. Exploring Electricity & Electronics With Projects.
  187. Edwards, H T, 1985. The Tevatron energy doubler: a superconducting accelerator.
  188. Ekin, J W, 1977. Mechanisms for critical-current degradation in NbTi and Nb3Sn multifilamentary wires.
  189. Ekin, J W, 1980. Strain scaling law for flux pinning in practical superconductors. Part 1: Basic relationship and application to Nb3Sn conductors.
  190. Ekin, J W, 1981. Strain scaling law for flux pinning in Nbti, Nb3Sn, Nb-Hf/Cu-Sn-Ga, V3Ga and Nb3Ge.
  191. Ekin, J W, 1984. Strain effects in superconducting compounds.
  192. Elachi, C, 1976. Waves in active and passive periodic structures: A review
  193. Elekes, G, 2020. Stress Analysis of High Field Nb3Sn Accelerator Magnets During Thermal Transients.
  194. Elen, JD, van Beijnen, C & van der Klein, C, 1977. Multifilament V3Ga and Nb3Sn superconductors produced by the ECN-technique.
  195. Elsener, K, 1998. The CERN neutrino beam to Gran Sasso (NGS) : conceptual technical design.
  196. Energizer, accessed: 01/2023. Energizer EA91 Advanced Lithium Product Data Sheet.
  197. Energizer, accessed: 01/2022. Energizer NH15–2300 (HR6) Product Data Sheet.
  198. Engquist, B & Majda, A, 1977. Absorbing boundary conditions for the numerical simulation of waves.
  199. Epperly, M, Desai, M, Allegrini, F, Ogasawara, K, George, DE, Christian, E & Murphy, N, 2020. CuSP: The CubeSat Mission for studying Solar Particles.
  200. Erwin, S, 2021. General Atomics Wins DARPA Contract To Develop Nuclear Reactor To Power Missions To The Moon. SpaceNews, Boulder, CO.
  201. European Union 5th Framework program,1999. ‘Advanced Research Magnet Systems’ (ARMS),
  202. Evans, L & Bryant, P, 2008. LHC machine.
  203. Evetts, J E, ed, 1992. Concise encyclopedia of magnetic & superconducting materials.
  204. Eyssa, YM, Bird, MD, Gao, BJ & Schneider-Muntau, HJ, 1998. Design and stress analysis of Florida-bitter resistive magnets.
  205. Eyssa, Y, Markiewicz, W & Pernambuco-Wise, P, 1995. Plastic stress analysis of pulse and resistive magnets.
  206. Eyssa, Y & Pernambuco-Wise, P, 1995. Electrical, Thermal and Mechanical Modeling of Pulsed Magnets.
  207. Eyssa, Y, Walsh, R, Miller, J, Pernambuco-Wise, P, Bird, M, Schneider-Muntau, H, Boeing, H & Robinson, R, 1997. 25–30T water cooled pulsed magnet concept for neutron scattering experiment.
  208. Eyssa, Y, Walsh, R, Miller, J, Pernambuco-Wise, P, Bird, M & Schneider-Muntau, H, 1998. 2 Hz, 30 T Split Pulse Water Cooled Magnet for Neutron Scattering Experiments.
  209. Fabry, C, 1898. Sur le champ magnétique au centre d’une bobine cylindrique et la construction de bobines galvanometers.
  210. Fahrni, C, Rufer, A, Bordy, F & Burnet, J, 2007. A novel 60 MW pulsed power system based on capacitive energy storage for particle accelerators.
  211. Fan, X, Mao, J, Zhu, Y, Luo, C, Suo L, Gao T, Han, F, Lio, SC & Wang, C, 2015. Superior Stable Self-Healing SnP3 Anode for Sodium-Ion Batteries.
  212. Ferracin, P, Ambrosio, G, Anerella, M, Borgnolutti, F, Bossert, R, Cheng, D, Dietderich, DR, Felice, H, Ghosh, A, Godeke, A, Bermudez, SI, Fessia, P, Krave, S, Juchno, M, Perez, JC, Oberli, L, Sabbi, G, Todesco, E & Yu, M, 2014. Magnet Design of the 150 mm Aperture Low-beta Quadrupoles for the High Luminosity LHC.
  213. Ferrero, A & Racati, A, 1990. A digital method for the determination of the magnetic characteristic of variable reluctance motors.
  214. Filip, DS & Petreus, D, 2016. Simulation of an inductive coupled power transfer system.
  215. Fischer, C M, 2002. Investigation of the Relationships Between Superconducting Properties and
    Nb3Sn Reaction Conditions in Powder-in-Tube Nb3Sn Conductors
  216. Fischer, C M, Lee, P J & Larbalestier, D C, 2002. Irreversibility field and critical current density as a function of heat treatment time and temperature for a pure Niobium powder-in-tube conductor.
  217. Fleiter, J, Peggiani, S, Bonasia, A & Ballarino, A, 2018. Characterization of Nb3Sn Rutherford cable degradation due to strands cross-over.
  218. Fletcher, J, Clark, MD, Sutton, FA, Wellings, R & Garas, K, 1999. The cost of MRI: Changing in costs 1989–1996.
  219. Foner, S & Schwartz, B B, eds, 1981. Superconductor Material Science.
  220. Frackowiak, E, 2006. Supercapacitors based on carbon materials and ionic liquids.
  221. Friedman, L, Carroll, W, Goldstein, R, Jacobson, R, Kievit, J, Landel, R, Layman, W, Marsh, E, Polszaj, R & Rowe, W, 1978. Solar Sailing — The Concept Made Realistic.
  222. Frings, PH, Herlach, F, Askenazy, S & Van Bockstal, L, 2000. A two-stage (“coilex-coilin”) pulsed-magnet system with a hybrid supply.
  223. Frings, PH, Witte, H, Jones, H, Beard, J & Hermannsdorfer, T, 2008. Rapid cooling methods for pulsed magnets.
  224. Fu, D, Lee, F, Qiu, Y & Wang, F, 2008. A novel high power density three-level LCC resonant converter with constant power-factor-control for charging applications.
  225. Fuller, R B, 1975. Synergetics: Explorations in the Geometry of Thinking.
  226. Galínski, M, Lewandowski, A & Stępniak, I, 2006. Ionic Liquids As Electrolytes.
  227. Gallagher-Daggit, G, 1973. Superconductor cables for pulsed dipole magnets.
  228. Gardner, T, 2021. CAPSTONE: A CubeSat pathfinder for the Lunar Gateway Ecosystem.
  229. Garner, CE, Brophy, JR, Polk, JE & Pless, LC, 1995. A 5730 Cyclic Endurance Test Of the SPT-100.
  230. Garner, C, Rayman, M, Brophy, J & Mikes, S, 2005. In-Flight Operation of the Dawn Ion Propulsion System Through the Preparations For Escape From Vesta.
  231. Gehring, R, Juengst, KP, Kuperman, G, Bordry, F, Burnet, JP & Voelker, F, 2005. A SMES based power supply for accelerator magnets.
  232. Gersdorf, R, Roeland, LW & Mattens, WCM, 1989. Design of magnet coils for semi-continuous magnetic fields up to 60 T.
  233. Ghaffari, M, Kinsman, W, Zhou, Y, Murali, S, Burlingame, Q, Lin, M, Ruoff, R & Zhang, Q, 2013. High Electrochemical Responses Of Ultra-High-Density Aligned Nano-Porous Microwave Exfoliated Graphite Oxide/Polymer Nano-composites Ionic Actuators.
  234. Ghaffari, M, Kosolwattana, S, Zhou, Y, Lachman, N, Lin, M, Bhattacharya, D, Gleason, K, Wardle, B & Zhang, Q, 2013. Hybrid Supercapacitor Materials From Poly(3,4-ethylenedioxythiophene) Conformally Coated Aligned Carbon Nanotubes.
  235. Ghaffari, M, Zhou, Y, Xu, H, Lin, M, Kim, T, Ruoff, R & Zhang, Q, 2013. Porous Microwave Exfoliated Graphite Oxide.
  236. Gharagheizi, F, Eslamimanesh, A, Mohammadi, AH, Richon, D, 2011. QSPR approach for determination of parachor of non-electrolyte organic compounds.
  237. Ghosh, AK, 2004. Cable design for fast ramped superconducting magnets (Cos-Theta design)
  238. Ghosh, AK, Sampson, WB, Gregory, E, Kreilick, S & Wong, J, 1988. The effect of magnetic impurities and barriers on the magnetization and critical current of fine filament NbTi composities.
  239. Ghovanloo, M & Najafi, K, 2007. A wireless implantable multichanncel microstimulating system-on-a-chip with modular architecture.
  240. Gieras, J, 1990. Linear Induction Motors.
  241. Glogowski, MJm Pilchuk, JW, Kodys, AD, Molinsky, JM, Rahal, GE, Eskenazi, MI & Tam, WH, 2017. Electric Propulsion Systems Development & Integration Activity at Orbital ATK.
  242. Goddard, RH, 1907. The Green Notebooks, vol. 1,
  243. Godeke, A, ten Haken, B & ten Kate, H H J, 1999. Scaling of the critical current in ITER type niobium-tin superconductors in relation to the applied field temperature and uni-axial applied strain.
  244. Godeke, A, Krooshoop, H J G, ten Haken, B & ten Kate, H H J, 2001. Experimental verification of temperature and strain dependence of the critical properties of Nb3Sn wires.
  245. Godeke, A, ten Haken, B & ten Kate, H H J, 2002. Toward an accurate scaling relation for the critical current in niobium-tin conductors.
  246. Godeke, A, ten Haken, B & ten Kate, H H J, 2002. The deviatoric strain description of the critical properties of Nb3Sn conductors.
  247. Godeke, A, Jewell, M C, Golubov, A A, ten Haken, B & Larbalestier, D C, 2003. Inconsistencies between extrapolated and actual critical fields in Nb3Sn wires as demonstrated by direct measurement of Hc2, H* and Tc.
  248. Godeke, A, 2015. Performance boundaries of Nb3Sn superconductors,
  249. Goebel, DM & Katz, I, 2008. Fundamentals of electric propulsion ion and Hall thrusters.
  250. Gogotsi, Y & Simon, P, 2011. True Performance Metrics in Electrochemical Energy Storage.
  251. Goldberg, D, 1989. Genetic algorithms in search, optimisation and machine learning.
  252. Goodenough. J B & Park, KS, 2013. The Li-ion rechargeable battery: a perspective.
  253. Goodzeit, CL, Ball, MJ & Meinke, RB, 2003. The double helix dipole, a novel approach to accelerator magnet design.
  254. Gourlay, S, Ambrosio, G, Andreev, N, Anerella, M, Barzi, E, Bossert, R, Caspi, S, Dietderich, D, Ferracin, P, Gupta, R, Ghosh, A, Hafalia, A, Hannaford, C, Harrison, M, Kashikhin, V.S, Kashikhin, V.V, Lietzke, A, Mattafirri, S, McInturff, A, Nobrega, F, Novitsky, I, Sabbi, G, Schmazle, J, Stanek, R, Turrioni, D, Wanderer, P, Yamada, R & Zlobin, A , 2006. Magnet R&D for the US LHC accelerator research program.
  255. Graineri, P, Calvi, M, Xydi, P, Baudouy, Bocian, D, Bottura, L, Breshi, M, Seikmo, A, 2008. Stability analysis of the LHC cables for transient heat depositions.
  256. Griffiths, D, 1999. Introduction to Electrodynamics, 3rd ed.
  257. Gronland, TA, Palmer, K, Jonsson, K & Bejhed, J, 2016. Miniaturisation enables propulsion also for micro- and nanosatellites.
  258. Grover, F, 1946. Inductance Calculations.
  259. Grössinger, R, Krichmayra, H, Sassik, H, Schwetz, M, Taraba, M, Frings, P, Kasper, G & Raithmayr, W, 1999. Austromag-a new high-field facility.
  260. Gschwendtner, E, 2006. CERN Neutrinos to Gran Sasso (CNGS): First Beam.
  261. Gualous, H, Bouquain, D, Berthon, A, Kauffmann, J, 2003. Experimental study of supercapacitor serial resistance and capacitance variations with temperature.
  262. Gualous, H, Louahlia-Gualous, H, Gallay, R & Miraoui, A, 2009. Supercapacitor thermal modeling and characterization in transient state for industrial applications.
  263. Guangwei, S, Meisinger, R & Gang, S, 2007. Modelling and Simulation of Shanghai Maglev Train Transrapid with Random Track Irregularities.
  264. Guderjahn, CA, Wipf SL, Fink HJ, Boom, RW, MacKenzie, KE, Williams, D & Downey, T, 1969. Magnetic suspension and guidance for high speed rockets by superconducting magnets.
  265. Guillemet, P, Scudeler, Y & Brouse, T, 2006. Multi-level reduced-order thermal modeling of electrochemical capacitors.
  266. Guillemet, P, Pascot, C, Scudeller, Y & Brouse, T, 2008. Compact thermal models of double layer supercapacitors.
  267. Guo, H, Zhu, H, Lin, H, Zhang, J & Yu, L, 2008. Synthesis and characterization of multi-walled carbon nanotube polythiophene composites.
  268. Hagedorn, D & Rodriguez-Mateous, F, 1992. Modelling of the quenching process in complex superconducting magnet systems.
  269. Haghighi, R & Pang, CK, 2016. Distributed Optimal Formation Flying Control of a Group of Nanosatellites.
  270. Hake, R R, 1967. Paramagnetic superconductivity in extreme type II superconductors.
  271. Hale, J R, & Williams, J E C, 1968. The transient stabilization of Nb3Sn composite ribbon magnets.
  272. Hampshire, D P, Jones, H & Mitchell, E J W, 1985. An in depth characterisation of (NbTa)&3Sn filamentary conductor.
  273. Han, K, Ishmaku, A, Xin, Y, Garmestani, H, Toplosky, V, Walsh, R, Swenson, C, Lesch, B, Ledbetter, H, Kim, S, Hundley, M and Sims, J, 2002. Mechanical properties of MP35N as a reinforcement material for pulsed magnets.
  274. Han, K, Toplosky, VJ, Walsh, R, Swenson, C, Lesch, B & Pantsyrnyi, VI, 2002. Properties of high strength Cu-Nb conductor for pulsed magnet applications.
  275. Han, K, Ishmaku, A, Xin, Y, Garmestani, H, Toplosky, VJ, Walsh, R, Swenson, C, Lesch, B, Ledbetter, H, Kim, S, Hundley, M & Sims, JR, 2002. Mechanical properties of MP35N as a reinforcement material for pulsed magnets.
  276. Hanak, J J, Strater, K & Cullen, G W, 1964. Preparation and properties of vapor deposited niobium stannide.
  277. Harding, JT & Tuffias, RH, 1960. The Cryogenic Gyro.
  278. Hardy, G F & Hulm, J K, 1953. Superconducting silicides and germanides.
  279. Harrington, RF, 1968. Field Computation by Moment Methods.
  280. Hashimoto, T, Yamada, T, Otsuki, M, Yoshimitsu, T, Tomiki, A, Torii, W, Toyota, H, Kikuchi, J, Morishita, N, Kobayashi, Y, Ito, T, Tanno, H, Nagamatsu, A & Moritomo, H, 2019. Nano semihard moon lander: OMOTENASHI.
  281. Hashimoto, Y, Yoshizaki K & Tanaka, M, 1974. Processing and properties of superconducting Nb3Sn filamentary wires.
  282. Haverkamp, M, 2003. Decay and Snap-Back in Superconducting Accelerator Magnets.
  283. Hechler, H, Horn, G, Otto, G & Saur, E,1969. Measurements of critical data for some Type II superconductors and comparison with theory
  284. Henning, W, 2004. FAIR — An international accelerator facilitator
  285. Herlach, F, 1999. Pulsed Magnets.
  286. Herlach, F & Miura, F, 2003. High Magnetic Fields Science & Technology — Controlled Waveform Magnets.
  287. Herlach, F, Peng, T & Vanacken, J, 2006. Experimental and theoretical analysis of the heat distribution in pulsed magnets.
  288. Hessel, A & Oliner, A, 1961. Wave propagation in a medium with a progressive sinusoidal disturbance.
  289. Hoefer, WJR, 1985. The transmission-line matrix method — Theory and applications.
  290. Hofer, RR, Randolph, TM, Oh, DY & Snyder, JS, 2006. Evaluation of a 4.5 kW Commercial Hall Thrusters System for NASA Science Missions.
  291. Hofer, RR & Kamhawi, H, 2017. Development Status of the 12.5 kW Hall Effect Rocket with Magnetic Shielding (HERMeS).
  292. Holland, J, 1975. Adaptation in natural and artificial systems.
  293. Holland, J, 1992. Genetic algorithms.
  294. Homer, JG, Rendle, TC, Waiters, CR, Wilson, MN & Bevir, MK, 1977. A new method for stable levitation of an iron body using superconductors.
  295. Hu, CC & Tsou, TW, 2002. Ideal capacitive behavior of hydrous manganese oxide prepared by anodic disposition.
  296. Huang, J, Zhou, X, Shang, L, Wu, Z, Xu, W & Wang, D, 2018. Influence analysis of track irregularity on running comfort of Maglev train.
  297. Huang, Y, Frings, P & Hennes, E, 2002. Mechanical properties of zylon/epoxy composites.
  298. Hung, K, Masarapu, C, Ko, T & Wei, B, 2009. Wide-temperature Range Operation Supercapacitors From Nanostructured Activated Carbon Fabric.
  299. Hurley, W, Duffy, M, Zhang, J, Lope, I, Kunz, B & Wölfle, W, 2015. A Unified Approach To The Calculation Of Self And Mutual Inductance For Coaxial Coils In Air.
  300. Itoh, T, 1989. Numerical Techniques for Microwave and Millimeter-Wave Passive Structures.
  301. Iwasa, Y, 1994. Case studies in superconducting magnets.
  302. Izadi-Najafabadi, A, Yasuda, S, Kobashi, K, Yamada, T, Futaba, D, Hatori, H, Yumura, M, Ilijima, S & Hata, K, 2010. Extracting The Full Potential Of Single-Waller Carbon Nanotubes As Durable Supercapacitor Electrodes Operable At 4V With High Power And Energy Density.
  303. Jackson, JD, Barton, RG & Donaldson, R, 1986. Conceptual design of the superconducting super collider.
  304. Jackson, J, Miller, S, Cassady, J, Soendker, E, Welander, B & Barber, M, 2019. 13kW Advanced Electric Propulsion Flight System Development and Qualification.
  305. Jacob, GM, Yang, QM & Zhitomisky, I, 2009. Electrodes for electrochemical supercapacitors.
  306. Jahn, RG, 1968. Physics of electric propulsion.
  307. Jain, A, Ganetis, G, Louie, W, Marone, A, Thomas, R & Wanderer, P, 2004. Magnetic Field Measurements for Fast-Changing Magnetic Fields.
  308. Jain, A, Ganetis,G, Gosh, A, Wing, L, Marone, A, Thomas, R & Wanderer, P, 2008. Field quality measurements at high ramp rates in a prototype dipole for the FAIR project.
  309. Jayawant, B, Sinha, PK, Wheeler, AR & Willsher, J, 1978. Control and dynamics of magnetically suspended vehicles.
  310. Jayawant, B, 1981. Electromagnetic suspension and levitation.
  311. Jian, L, Xu, G, Gong, Y, Song, J, Liang, J & Chang, M, 2011. Electromagnetic design and analysis of a novel magnetic-gear-integrated wind power generator using time-stepping finite element method.
  312. Jiang, L, Zhao, J, Gao, Y & Zhou, Y, 2021. Geometrical modelling and mechanical behaviour analysis of Nb3Sn Rutherford cable.
  313. Jin, J, 2002. The Finite Element Method in Electromagnetics, 2nd ed.
  314. Jones, H, Jenkins, RG, Van Cleemput, M, Nicholas, RJ, Siertsema, WJ & van der Burgt, M, 1994. Pulsed and high temperature superconducting magnet technology in Oxford.
  315. Jones, H, Frings, P, von Ortenberg, M, Lagutin, A, van Bockstal, L, Portugall, O & Herlach, F, 2004. First experiments in fields about 75T in the European “coilin — coilex” magnet.
  316. Jones, H, Frings, P, Portugall, O, von Ortenberg, M, Lagutin, A, Herlach, F & Van Brockstal, L, 2006. ARMS: A successful european program for an 80T user magnet.
  317. Jorling, J, Wollmann, G, Weise, T, Jung, M, Hofmann, J & Kerschke, R, 2007. 49 MJ pulsed power facility to produce high magnetic fields.
  318. Ju, S, Jung, KY & Kim, H, 2003. Investigation on the characteristics of the envelope FDTD based on the alternating direction implicit scheme.
  319. Kahle, K & Jovcic, D, 2004. Static VAR Compensator for CERN’s Proton Synchrotron Accelerator.
  320. Kaiho, K, Namba, T, Ohara, T & Koyama, K, 1976. Optimisation of Superconducting Solenoid.
  321. Kamerlingh Onnes, H, 1911. The superconductivity of Mercury.
  322. Kang, CG, Seo, PK & Jung, HK, 2002. Numerical Analysis By New Proposed Coil Design Method In Induction Heating Process for Semi-Solid Forming and Its Experimental Verification With Globalisation Evaluation.
  323. Kanithi, HC, Valaris, P & Zeilin, BA, 1991. Superconductors with 2.5 micron NbTi filaments.
  324. Kapitza, P, 1938. Viscosity of liquid helium below the lambda point.
  325. Karhi, R, Wetz, D, Mankowski, J & Giesselmann, M, 2012. Theoretical and experimental analysis of breech fed and 40-distributed energy stage plasma arc railguns.
  326. Karppinen, M, Andreev, N, Apollinari, G, Auchmann, B, Barzi, E, Bossert, R, Kashikhin, VV, Nobrega, A, Novitski, I, Rossi, L, Smekens, D & Zlobin, AV, 2012. Design of 11 T twin-aperture Nb3Sn dipole demonstrator magnet for LHC upgrades.
  327. Kaufmann, A R & Pickett, J J, 1970. Multifilament Nb3Sn superconducting wire.
  328. Kaugerts, J, 2003. Quench Protection System.
  329. Kaugerts, J, Moritz, G, Muehle, C, Ageyev, A, Bogdanov, I, Kozub, Shcherbakov, P, Sytnik, V, Tkachenko, L, Zubko, V, Tommasini, D, Wilson, M & Hassenzahl, W, 2005. Design of a 6T, 1 T/s fast-ramping synchrotron magnet for GSIs planned SIS300 Accelerator.
  330. Kauschke, M & Schroeder, S C, 2004. Cryogenic system for the new international accelerator facility for research with ions and antiprotons at GSI.
  331. Kawagoe, A, Sumiyoshi, F, Mito, T, Chikaraishi, H, Maekawa, R, Seo, K, Baba, T, Hemmi, T, Okumura, K, Iwakuma, M, Hayashi, K & Abe, R, 2005. Stability evaluation of a conduction-cooled prototype LTS pulse coil for UPS-SMES.
  332. Kawagoe, A, Yamamuro, H, Sumiyoshi, F, Mito, T, Chikaraishi, H, Baba, T, Yokota, M, Morita, Y, Ogawa, H, Hemmi, T, Okumura, K, Abe, R & Iwakuma, M, 2006. Heat transfer properties of a conduction cooled prototype LTS pulse coil for UPS-SMES.
  333. Kawagoe, A, Yamamuro, H, Sumiyoshi, F, Mito, T, Chikaraishi, H, Hemmi, T, Baba, T, Yokota, M, Morita, Y, Ogawa, H, Abe, R, Okumura, K, Iwakuma, M, 2006. Optimization of a conduction-cooled LTS pulse coil.
  334. Kawagoe, A, Tsukuda, S, Sumiyoshi, F, Mito, T, Chikaraishi, H, Hemmi, T, Baba, T, Yokota, M, Morita, Y, Ogawa, H, Abe, R, Nakamura, A, Okumura, K, Kuge, A & Iwakuma, M, 2007. The design to downsize a conduction-cooled LTS pulse coil for UPS-SMES as protection from momentary voltage drops
  335. Kawagoe, A, Tsukuda, S, Sumiyoshi, F, Mito, T, Chikaraishi, H, Baba, T, Yokota, M, Ogawa, H, Hemmi, T, Abe, R, Nakamura, A, Okumura, K, Kuge, A & Iwakuma, M, 2008. AC losses in a conduction-cooled LTS pulse coil with stored energy of 1 MJ.
  336. Kawashima, T, Sumiyoshi, F, Kawabata, S & Shintomi, T, 1999. 3D FEM analysis of inter-strand coupling losses in Rutherford cables with composite core.
  337. Keilin, V E, Alekseev, P A, Boev, A I, , Kovalev, I A, Kozub, S S, Kruglov, S L, Lazukov, V N & Sadikov, I P, 2005. Considerable stability increase in superconducting windings doped with extremely high specific heat substances.
  338. Kemper, H, 1937. German Patent 643316 644302
  339. Keys, S A & Hampshire, D P, 2003. A scaling law for the critical current density of weakly- and strongly-coupled superconductors, used to parameterize data from a technological Nb3Sn strand.
  340. Khaligh, A & Li, Z, 2010. Battery, ultra-capacitor, fuel cell, and hybrid energy storage systems for electric, hybrid electric, fuel cell, and plug-in hybrid electric vehicles.
  341. Khan, M, Ali, A, Ali, H, Khattak, M & Ahmad, I, 2016. Designing Efficient Electric Power Supply System for Micro-Satellite.
  342. Khodzhibagiyan, HG & Smirnov, AA, 1988. The concept of a superconducting magnet system for the Nuclotron.
  343. Khodzhibagiyan, HG, Fischer, E, Kovalenko, AD, Moritz, G, Pontanina, LV, Shikov, AK & Vedernikov, GP, 2003. Design and Test of a Hollow Superconducting Cable Based on Keystoned NbTi Composite Wires.
  344. Kim, KB, Levi, E, Zabar, Z & Birenbaum, L, 1997. Mutual inductance of noncoaxial circular coils with constant current density.
  345. Kim, YB, Hempstead, CF & Strnad, AR, 1962. Critical persistent currents in hard superconductors.
  346. Kindo, K, 2001. 100T magnet developed in Osaka.
  347. Kircher, F, Levesy, B, Pabot, Y, Campi, D, Cure, B, Herve, A, Horvath, I, Fabbricatore, P & Musenich, R, 1999. Status report on the CMS superconducting solenoid for LHC.
  348. Kiyoshi, T, Sato, A, Takeuchi, T, Itoh, K, Matsumoto, S, Ozaki, O, Fukushima, K, Wada, H, Yoshikawa, M, Kamikado, T, Ito, S, Miki, T, Hase, T, Hamada, M, Hayashi, S, Kawate, Y & Hirose, R, 2002. Persistent-mode operation of a 920 Mhz high-resolution NMR magnet.
  349. Klesh, A, Baker, J & Krajewski, J, 2019. MarCO:Flight review and lessons learned.
  350. Kobayashi, Y, Ito, T, Mita, M, Takeuchi, H, Funase, R, Tomiki, A, Kobayashi, D, Nonomura, T, Fukushima, Y & Kawakatsu, Y, 2016. Low-cost and ultimately-downsized X-band deep-space telecommunication system for PROCYON mission.
  351. Kohl, WH, 1967. Handbook of Materials and Techniques for Vacuum Devices.
  352. Kolm, H, Lax, B, Bitter, F & Mills, R, 1961. High Magnetic Fields.
  353. Koppel, C & Estublier, D, 2005. The Smart-1 Hall-Effect Thruster Around the Moon: In-Flight Experience.
  354. Kovalenko, AD, 1994. Status of the nuclotron.
  355. Kovalenko AD, Agapov, NN, Bartenev, V, Donyagin, A, Eliseeva, I, Khodzhibagiyan, HG, Kuznetsov, G, Smirnov, A, Voevodin, MA, Fischer, E & Moritz, G, 2004. Design and Study of a Superferric Model Dipole and Quadrupole Magnets for the GSI Fast-pulsed Synchrotron SIS100.
  356. Kötz, R, Hahn, M & Gallay, R, 2006. Temperature Behaviour And Impedance Fundamentals Of Supercapacitors.
  357. Krejci, D, Mier-Hicks, F, Thomas, R, Haag, T & Lozano, PC, 2017. Emission Characteristics of Passively Fed Electrospray Microthrusters with Propellant Reservoirs.
  358. Krempasky, L, 1978. AC Losses in flat twisted superconducting cables.
  359. Krempasky, L & Schmidt, C, 1996. Ramp-rate limitation in large superconducting magnets due to supercurrents.
  360. Kresin, VZ, Morawitz, H & Wolf, SA, 1993. Mechanisms of Conventional and High Tc Superconductivity.
  361. Krishnan, R & Majeru, P, 1989. Measurement and instrumentation of a switched reluctance motor.
  362. Krug, H, Doerr, M, Eckert,D, Eschrig, H, Fischer, F, Fulde, P, Groessinger, R, Handstein, A, Herlach, F, Hinz, D, Kratz, R, Loewenhaupt, M, Muller, KH, Pobell, F, Schultz, L, Siegel, H, Steglich, F & Verges, P, 2001. The Dresden high-magnetic field laboratory — overview and first results.
  363. Krumpholz, M & Katehi, LPB, 1996. MRTD: New time-domain schemes based on multiresolution analysis.
  364. Kuffel, E & Zaengl, WS, 1984. High Voltage Engineering Fundamentals,
  365. Kundert, KS, 1999. Introduction to RF simulation and its application.
  366. Kuninaka, H, Nishiyama, K, Shimizu, Y, Funaki, I, Koizumi, H, Hosoda, S & Nakata, D, 2009. Hayabusa Asteroid Explorer Powered by Ion Engines on the way to Earth.
  367. Kunze, M, Jeong, S, Paillard, E, Winter, M & Passerini, S, 2010. Melting Behaviour Of Pyrrolidinium-Based Ionic Liquids And Their Binary Mixtures.
  368. Kunze, M, Montanino, M, Appetecchi, G, Jeong, S, Schonhoff, M, Winter, M & PAsserini, S, 2010. Melting Behaviour And Ionic Conductivity In Hydrophobic Ionic Liquids.
  369. Kunzler, JE, 1987. Recollection of events associated with the discovery of high field-high current superconductivity.La, J, Bae, K, Lee, S, Song, M, Nam, K and Jung, Y, 2016. Coil Design Optimisation for an Induction Evaporation Process: Simulation and Experiment.
  370. La, J, Bae, K, Lee, S, Song, M, Nam, K and Jung, Y, 2016. Coil Design Optimisation for an Induction Evaporation Process: Simulation and Experiment.
  371. Lackner, F, Bourcey, N, Ferracin, P, Jozwiak, P, Ohnweiler, T, Revilak, P, Savary, F & Triquet, S, 2016. Analysis of Temperature Uniformity During HeatTreatment of Nb3Sn Coils for the High-Luminosity LHC Superconducting Magnets.
  372. Laithwaite, ER, 1965. Differences between series and parallel connection in machines with asymmetric magnetic circuits.
  373. Laithwaite, ER, 1973. Magnetic or electromagnetic? The great divide.
  374. Laithwaite, ER, Eastham, JF, Bolton, H & Fellows, TG, 1971. Linear motors with transverse flux
  375. Lan, Y, Zhou, J, Xu, K, Lu, Y, Zhang, K, Zhu, L & Qian, Y, 2018. Synchronous synthesis of Kirkendall effect induced hollow FeSe2/C nanospheres as anodes for high performance sodium ion batteries.
  376. Lapidus, L & Pinder, GF, 1982. Numerical Solution of Partial Differential Equations in Science and Engineering, 1st ed.
  377. Lebrun, P & Tavian, L, 2004. The technology of superfluid helium.
  378. Lebrun, P, 2007. Advanced technology from and for basic science: superconductivity and superfluid helium at the large hadron collider, CERN.
  379. Lee, DH, Kim, US, Shin, CB, Lee, BH, Kim, BW & Kim, YH, 2008. Modelling of the thermal behaviour of an ultracapacitor for a 42-V automotive electrical system.
  380. Lee, H, Kim, K & Lee, J, 2006. Review of maglev train technologies.
  381. Lee, P J & Larbalestier, D C, 2001. Compositional and microstructural profiles across Nb3Sn filaments produced by different fabrication methods.
  382. Lee, P J & Larbalestier, D C, 2003. Niobium-titanium superconducting wires: Nanostructures by extrusion and wire drawing.
  383. Lee, P J, Squitieri, AA & Larbalestier, D C, 2000. Nb3Sn macrostructures, microstructures and property comparisons for bronze and internal Sn process strands.
  384. Lemmer, K, 2017. Propulsion For CubeSats.
  385. Lev, D, Myers, RM, Lemmer, KM, Kolbeck, J, Koizumi, H & Polzin, K, 2019. The technological and commercial expansion of electric propulsion.
  386. Levison, HF, Olin, CB, Noll, KS, Marchi, S, Bell III, JF, Bierhaus, E, Binzel, R, Bottke, W, Britt, D, Brown, M, Buie, M, Christensen, P, Emery, J, Grundy, W, Hamilton, VE, Howett, C, Mottola, S, Pätzold, M, Reuter, D, Spencer, J, Statler, TS, Stern, SA, Sunshine, J, Weaver, H & Wong, I, 2021. Lucy Mission to the Trojan asteroids: science goals.
  387. Li, G & Aluru, NR, 2002. A Lagrangian approach for electrostatic analysis of deformable conductors.
  388. Li, L, 1998. High performance pulsed magnets: Theory, design and construction.
  389. Li, L & Herlach, F, 1995. Deformation analysis of pulsed magnets with internal and external reinforcement.
  390. Li, L, Van Bockstal, L, Herlach, F & Van Amersfoort, W, 1996. Design study of a 60 T pulsed magnet with µs risetime.
  391. Li, L & Herlach, F, 1998. Magnetic and thermal diffusion in pulsed high field magnets.
  392. Li, Q, Lee, FC & Jovanovic, MM, 1999. Design considerations of transformer dc bias of forward converter with active-clamp reset.
  393. Li, L, Lesch, B, Cochran, V, Staton, R, Tozer, S, Schneider-Muntau, H, Rickel, D, Mielke, C & Boebinger, G, 2000. High performance pulsed magnets with high strength conductors and high modulus internal reinforcement.
  394. Li, L, Ding, H, Peng, T, Han, X, Xia, Z, Chen, J, Duan, X, Wang, C, Pan, Y, Vanacken, J, Herlach, F, 2008. The Pulsed High Magnetic Field Facility at HUST, Wuhan, China and Associated Magnets.
  395. Zhang, L, Jin-Yan, S, Ji-Yan, Z & Wang, N, 2008. High voltage super- capacitors for energy storage devices applications.
  396. Lichtin, DA, Chielli, NV, Henderson, JB, Rauscher, RA, Young, KJ, McKinnon, DV, Bailey, JA, Roberts, CR, Zube, DM & Fisher, JR, 2009. AMC-1 (GE-1) Arcjets at 12-plus Years On-Orbit.
  397. Lienhard, J, 2004. A Heat Transfer Textbook.
  398. Lijesh, KP & Hirani, H, 2015. Design and development of Halbach electromagnet for active magnetic bearing.
  399. Lin, F, Zuo, S, Deng, W & wu, S, 2016. Modeling and analysis of electromagnetic force, vibration and noise in permanent-magnet synchronous motor considering current harmonics.
  400. Littell, J D, Ruggeri, C R, Goldberg, R K, Roberts, G D, Arnold, W A, Binienda W K, 2008. Measurement of epoxy resin tension, compression, and shear stress–strain curves over a wide range of strain rates using small test specimens.
  401. Liu, C, Yu, Z, Neff, D, Zhamu, A & Jang, BZ, 2010. Graphene-Based supercapacitor with an ultrahigh energy density.
  402. Liu, K, Sun, R, Gao, Y & Yan, P, 2015. High voltage repetition-frequency charging power supply for pulsed laser.
  403. Liu, P, Verbrugge, M & Soukiazian, S, 2006. Influence Of Temperature And Electrolyte On The Performance Of Activated Carbon Supercapacitors.
  404. Liu, Q, Bo, H & Qin, B, 2010. Experimental Study & Numerical Analysis On Electromagnetic Force of Direct Action Solenoid Valve.
  405. Liu, Y, Zhang, N, Jiao, L, Tao, Z & Chen, JJAFM, 2015. Ultrasmall Sn Nanoparticles Embedded in Carbon as High-Performance Anode for Sodium-Ion Batteries.
  406. Livingston, J D, 1978. Effect of Ta Additions to Bronze \-Processed Nb3Sn Superconductors.
  407. Lockett, TR, Castillo-Rogez, JC, Johnson, L, Matus, J, Lightholder, JA, Marinan, A & Few, A, 2020. Near-earth asteroid scout flight mission.
  408. Lord, P, Tilley, S, Oh, DY, Goebel, D, Polanskey, C, Snyder, S, Carr, G, Collins, S, Lantoine, G, Landau, D & Elkins-Tanton, L, 2017. Psyche: Journey to a Metal World.
  409. Lu, W, Qu, LT, Henry, K & Dai, LM, 2009. High performance electrochemical capacitors from aligned carbon nanotube electrodes and ionic liquid electrolytes.
  410. Luo, X, Wang, J, Dooner, M & Clarke, J, 2014. Overview of Current Development in Electrical Energy Storage Technologies and the Application Potential in Power System Operation.
  411. Manil, P, Mouzouri, M & Nunio, F, 2012. Mechanical Modeling of Low Temperature Superconducting Cables at the Strand Level.
  412. Manil P, Nunio F, Othmani Y, Aubin V, Buffiere J-Y, Commisso MS, Dokladal, P, Durville, D, Lenoir, G, Lerme, N & Maire, E, 2017. A numerical approach for the mechanical analysis of superconducting Rutherford- type cables using bimetallic description.
  413. Mankins, JC, 2009. Technology Readiness Assessments: A Retrospective.
  414. Manley, J & Rowe, H, 1956. Some general properties of nonlinear elements — Part I. General energy relations.
  415. Manzella, DH, 1993. Stationary Plasma Thruster Plume Emissions.
  416. Manzella, DH, 2007. Low Cost Electric Propulsion Thruster for Deep Space Robotic Missions.
  417. Marken, KR, 1986. Characterization Studies of Bronze-Process Filamentary Nb3Sn Composites.
  418. Markiewicz, WD, Vaghar, MR, Dixon, IR & Garmestani, H, 1994. Generalized plane strain analysis of solenoid magnets.
  419. Markiewicz, W D, Bonney, L A, Dixon, I A, Eyssa, Y M, Swenson, C A & Schneider-Muntau, H J, 1996. Technology of 1 Ghz NMR superconducting magnets.
  420. Markiewicz, WD, Dixon, IR, Marshall, WS & Walsh, R, 2000. Epoxy lead cones for free supported leads.
  421. Marshall, WM, Swenson, C, Gavrilin, A & Schneider-Muntau, H, 2004. Development of fast cool pulse magnet coil technology at NHMFL.
  422. Martinez, A & Duchateau, J L, 1997. Field and temperature dependencies of critical current on industrial Nb3Sn strands.
  423. Masson, PJ & Rouault, VR, 2008. Development o quench propagation models for coated conductors.
  424. Matekovits, L, Colome, G & Orefice, M, 2007. Propagation of electromagnetic waves in a sinusoidally modulated dielectric substrate.
  425. Matthias, BT, 1957. Superconductivity.
  426. Matthias, BT, Geballe, TH, Geller, S & Corenzwit, E, 1954. Superconductivity of Nb3Sn.
  427. Maugain JM, 2003. Magnetic Horns for CERN neutrino beams — from the sixties to 2003.
  428. Mazouffre, S, 2016. Electric propulsion for satellites and spacecraft: established technologies and novel approaches.
  429. Meinke, R, 1991 Superconducting magnet system for HERA.
  430. Meissner, W & Ochsenfeld, R, 1933. Ein neuer Effekt bei Eintritt der Supraleitfähigkeit.
  431. Mel’kumov, TM, ed., 1965. Pioneers of Rocket Technology, Selected Works. Academy of Sciences of the USSR, Institute for the History of Natural Science and Technology, Moscow, 1964; translated from the 1964 Russian text by NASA as NASA TT F-9285, 1965
  432. Merrill, RG, Strange, N, Qu, M & Hatten, N, 2015. Mars conjunction crewed missions with a reusable hybrid architecture.
  433. Meß, K, H, Schmuser, P, Wolff, S, 1996. Superconducting accelerator magnets.
  434. Meyer, D & Flasck, R, 1970. A new configuration for a dipole magnet for use in high energy physics applications.
  435. Michalewicz, Z, 1996. Genetic Algorithms and data structures = evolution programs.
  436. Michielsen, BL, Herman, GC, De Hoop, AT & De Zutter, D, 1981. Three-dimensional relativistic scattering of electromagnetic waves by an object in uniform translational motion.
  437. Mikellides, I, Ira, K, Goebel, DM & Jameson, KK, 2006. Toward the identification of the Keeper Erosion Cause(s): numerical simulations of the Plasma and Neutral Gas using the Global Cathode Model OrCa2D-II.
  438. Mikellides, I, Jorns, B, Katz, I & Ortega, Al, 2016. Hall2De Simulations with a First-principles Electron Transport Model Based on the Electron Cyclotron Drift Instability.
  439. Mikellides, PG, Turchi, PJ & Roderick, NF, 2000. Applied-Field MagnetoPlasmaDynamic Thrusters, Part 1: Numerical Simulations Using the MACH2 Code.
  440. Minkowski, H, 1908. Die Grundgleichungen für die elektromagnetischen Vorgänge in bewegten Körpern.
  441. Mirkhani, SA, Gharagheizi, F, Ilani-Kashkouli, P, Farahani, N, 2012. Determination of the glass transition temperature of ionic liquids: A molecular approach.
  442. Mitchell, N, 2005. Finite element simulations of elasto-plastic processes in Nb3Sn strands.
  443. Mito, T, Kawagoe, A, Chikaraishi, H, Maekawa, R, Okumura, K, Abe, R, Baba, T, Hemmi, T, Iwakuma, M, Yokota, M, Ogawa, H, Morita, Y, Yamauchi, K, Kuge, A & Sumiyoshi, F, 2006. Validation of the high performance conduction-cooled prototype LTS pulse coil for UPS-SMES.
  444. Mito, T, Kawagoe, A, Chikaraishi, H, Maekawa, R, Hemmi, T, Okumura, K, Abe, R, Baba, T, Ogawa, H, Yokota, M, Morita, Y, Yamauchi, K, Iwakuma, M, Kuge, A, Nakamura, A & Sumiyoshi, F, 2007. Development of 1 MJ conduction-cooled LTS pulse coil for UPS-SMES.
  445. Mito, T, Chikaraishi, H, Kawagoe, A, Maekawa, R, Abe, R, Baba, T, Okumura, K, Kuge, A, Iwakuma, M & Sumiyoshi, F, 2009. Summary of a 1 MJ Conduction-Cooled LTS Pulse Coil Developed for 1 MW, 1s UPS-SMES.
  446. Miyagawa, H, Mase, T, Sato, C, Drown, E, Drzal, L & Ikegami, K, 2006. Comparison of experimental and theoretical transverse elastic modulus of carbon fibre.
  447. Miyazaki, T, Murakami, Y, Hase, T, Shimada, M, Itoh, K, Kiyoshi, T, Takeuchi,
    T, Inoue, K & Wada, H, 1999. Development of Nb3Sn Superconductors for a 1 Ghz NMR magnet. Dependence of high-field characteristics on tin content in bronze matrix.
  448. Moghbelli, HH, 1991. Prediction of the instantaneous and steady state torque of the switched reluctance motor using FEM with experimental results comparison.
  449. Montgomery, D & Weggel, R, 1980. Solenoid Magnet Design
  450. Moore, DF, Zubeck, RB, Rowell, JM & Beasley, MR, 1979. Energy gaps of the A — 15 superconductors Nb3Sn, V3Si, and Nb3Ge measured by tunneling.
  451. Morgan, GH, 1970. Theoretical behavior of twisted multicore superconducting wire in a time-varying uniform magnetic field.
  452. Moritz, G, 2004. Fast-pulsed SC magnets.
  453. Moritz, G, Muehle, C, Anerella, M, Ghosh, A, Sampson, W, Wanderer, P, Willen, E, Agapov, N, Khodzhibagiyan, H, Kovalenko, A, Hassenzahl, W & Wilson, MN, 2001. Towards fast pulsed superconducting synchrotron magnets.
  454. Motokawa, M, Hojiri, H, Ishihara, J & Ohnishi, K, 1989. Production of repeating pulsed high magnetic field.
  455. Motokawa, M, Nojiri, H, Uchi, M, Watamura, S, Nishiyama, K & Nagamine, K, 1991. Application of pulsed high magnetic field to (mu)SR Studies.
  456. Mueller, U, Beyer, A & Hoefer, WJR, 1992. Moving boundaries in 2-D and 3-D TLM simulations realized by recursive formulas.
  457. Müller, M & Kastening, B, 1994. The double layer of activated carbon electrodes: Part 1. The contribution of ions in the pores.
  458. Mullins, C, Hruby, V, Pote, V & Blake, K, 2019. Development of a 5kW Class Hall Thruster.
  459. Mur, G, 1981. Absorbing boundary conditions for the finite-difference approximation of the time-domain electromagnetic-field equations.
  460. Murakami, M, Oyama, T, Fujimoto, H, Taguchi, T, Gotoh, S, Shiohara, Y, Koshizuka, N & Tamaka, S, 1991. Large Levitation Force due to Flux Pinning in YBaCuO Superconductors Fabricated by Melt-Powder-Melt-Grouth Process.
  461. Muratore, J, Anerella, M, Cozzolino, J, Ganetis, G, Ghosh, A, Gupta, R, Harrison, M, Jain, A, Marone, A, Plate, S, Schmalzle, J, Thomas, R, Wanderer, P, Willen, E & Wu, KC, 2002. Test results for initial production of LHC insertion region dipole magnets.
  462. Myers, RM, 1993. Electromagnetic Propulsion for Spacecraft.
  463. Myers, RM and Manzella, DH, 1993. Stationary Plasma Thruster Plume Characteristics.
  464. Myers, RM, Oleson, SR, McGuire, M, Meckel, J & Cassady, JR, 1995. Pulsed Plasma Thruster Technology for Small Satellite Missions.
  465. Nagamatsu, J, Nakagawa, N, Muranaka, T, Zenitani, Y & Akimitsu, J, 2001. Superconductivity at 39K in Magnesium diboride.
  466. Nagel, LW, 1975. SPICE2: A computer program to simulate semi-conductor circuits.
  467. Namiki, T, 1999. A new FDTD algorithm based on alternating-direction implicit method.
  468. Namiki, T & Ito, K, 2000. Investigation of numerical errors of the two-dimensional ADI-FDTD method [for Maxwell’s equations solution].
  469. Napolitano, F, Borghetti, A, Nucci, CA, Paolone, M & Rachidi, F, 2013. Use of the full-wave finite element method for the numerical electromagnetic analysis of LEMP and its coupling to overhead lines.
  470. National Academies of Sciences, Engineering, and Medicine, 2022. (2023–2032) Origins, Worlds, and Life: A Decadal Strategy for Planetary Science and Astrobiology.
  471. Neihart, N & Harrison, R, 2005. Micropower circuits for bidirectional wireless telemetry in neural recording applications.
  472. Nelson, W, 2004. Accelerated testing: Statistical models, test plans and data analysis.
  473. Neuringer, LJ & Shapira, Y, 1966. Effect of spin-orbit scattering on the upper critical field of high-field superconductors.
  474. Ngk Insulators. NAS ENERGY STORAGE SYSTEM: Sodium Sulfur Battery.
  475. Ngoya, E & Larchevèque, R, 1996. Envelop transient analysis: A new method for the transient and steady state analysis of microwave communication circuits and systems.
  476. Nguyen, MQ, Woods, P, Hughes, Z, Seo, Y, Rao, S & Chiao, JC, 2014. A mutual inductance approach for optimization of wireless energy transmission.
  477. Nian, S, Tsai, S, Huang, M, Huang, R, Chen, C, 2014. Key Parameters and Optimal Design of a Single Layered Induction Coil for External Rapid Mold Surface Heating.
  478. Nilsson, J & Riedel, S, 2010. Electric Circuits, 9th ed.
  479. Nishiyama, K, Hosoda, S, Ueno, K, Tsukizaki, R & Kuninaka, H, 2015. Development and Testing of the Hayabusa2 Ion Engine System
  480. Nishiyama, K, Kawakatsu, Y, Toyota, H, Funase, R, Arai, T & DESTINY Working Group, 2017. DESTINY+: A Mission Proposal for Technology Demonstration and Exploration of Asteroid 3200 Phaethon.
  481. Nojiri, H, Motokawa, M, Nishiyama, K, Nagamine, K & Shigeoka, T, 1992. MuSR study of PrCo2Si2 in pulsed high magnetic field.
  482. Nojiri, H, Motokawa, M, Takahashi, K & Arai, M, 2000. 30 T repeating pulsed field system for neutron diffraction.
  483. Nomura, S, Shimada, R. Sato, H and Shintomi, T, 2015. Design Study on Pulsed Power Supplies for the J-PARC Main Ring Magnets Using SMES.
  484. Nomura, S, Nitta, T & Shintomi, T, 2020. Mobile Superconducting Magnetic Energy Storage for On-Site Estimations of Electric Power System Stability.Orlando, T P & Delin, K A, 1991. Foundations of Applied Superconductivity.
  485. Oleson, SR, 1997. Electric Propulsion for Low Earth Orbit Communication Satellites.
  486. Oliner, A & Hessel, A, 1959. Guided waves on sinusoidally-modulated reactance surfaces.
  487. Omekanda, A, Broche, C, Crappe, M & Baland, R, 2007. Prediction of the steady state performance of the switched reluctance motor using quadratic biem-FEM field solutions in the linear model.
  488. Oppenheim, AV, Willsky, AS & Nawab, SH, 1997. Signals & Systems, 2nd ed.
  489. Orkress, EC, Wroughton, DM, Coment, ZG, Brace, PH & Kelly, JCR, 1952. Electromagnetic levitation of solid and molten metals.
  490. Orlando, TP, McNiff Jr, EJ, Foner, S & Beasley, MR, 1979. Critical field, Pauli paramagnetic limiting and material parameters of Nb3Sn and V3Si.
  491. Otmani, R, Devred, A & Tixador, P, 2001. Interstrand and AC-loss measurements on Rutherford-type cables for accelerator magnet applications.
  492. Ould Ely, T, Batyrbekuly, D, Sugurbekov, Y, Stambekova, D, Doherty, MF & Bakenov, Z, 2017. Synthesis and Characterization of Silicon Based Anode Materials.
  493. Ozaki, T, Kasai, Y & Nishida, E, 1999. Improvement of 20mN Xenon Ion thruster.
  494. Ozaki, T, Nishida, E, Kasai, Y, Gotoh, Y, Itoh, T & Kajiwara, K, 2015. Development Status of Xenon Ion Engine Subsystem for ETS-VIII.
  495. Ozaki, T, Kasai, Y, Nakagawa, T, Itoh, T, Kajiwara, K & Ikeda, M, 2007. In-Orbit Operation of 20 mN Class Xenon Ion Engine for ETS-VIII.
  496. O’Connor, K & Curry, R, 2010. High Voltage characterisation of high dielectric constant composites.
  497. O’Connor, K & Curry, R, 2014. Recent Results in the Development of composites for High Energy Density Capacitors.
  498. Painter, T, Bole, S, Eyssa, Y, Dixon, I, Williams, V, Maier, S, Gundlach, S, Tozer, S, Hascicek, Y & Ammerman, C, 2000. Design of 30 T split pair pulse coils for LANSCE.
  499. Pandolfo, AG & Hollenkamp, AF, 2009. Carbon properties and their role in supercapacitors.
  500. Pantsyrnyi, V, Shikov, A, Vorobieva, A, Khiebova, N, Kozlenkova, N, Potapenko, I & Polikarpova, M, 2006. Stability aspects of the high strength, high conductivity microcomposite CuNb wires properties.
  501. Parker, J V, 1982. Electromagnetic projectile acceleration utuilizing distributed energy sources.
  502. Parks, R D, ed, 1969. Superconductivity,
  503. Parrell, J A, Field, M B, Zhang, Y & Hong, S, 2004. Nb3Sn conductor development for fusion and particle accelerator applications.
  504. Passerone, C, Tranchero, M, Speretta, S, Reyneri, L, Sansoé, C, Del Corso, D, 2008. Design Solutions for a university nano-satellite.
  505. Patterson, MJ & Benson, S, 2007. NEXT Ion Propulsion System Development Status and Performance.
  506. Patterson, MJ, Rawlin, VK & Sovey, JS, 1995. 2.3 kW Ion Thruster Wear Test.
  507. Pech, D, Brunet, M, Durou, H, Huang, P, Mochalin, V, Gogotsi, Y, Taberna, P & Simon, P, 2010. Ultra high-power micrometer-sized supercapacitors based on onion-like carbon.
  508. Peng, HJ, Hao, GX, Chu, ZH, Lin, YW, Lin, XM & Cai, YP, 2017. Porous carbon with large surface area derived from a metal–organic framework as a lithium-ion battery anode material.
  509. Peng, T & Herlach, F, 2008. Design Principles for Optimised Pulsed Magnets.
  510. Peng, T, Li, L, Vanacken, J & Herlach, F, 2008. Efficient Design of Advanced Pulsed Magnets.
  511. Peng, T, Jiang, F, Sun, Q, Xu, Q, Xiao, H, Herlach, F & Li, L, 2014. Design and test of a 90T nondestructive magnet at Wuhan National High Magnetic Field Centre.
  512. Perenboom, JAAJ, Rosseel, K, Dolron, PAJ, Wiegers, SAJ, Frings, PH & Maan, JC, 2006. Powering multi-coil systems Combining DC and Pulsed Power Supplies.
  513. Perenboom, J, Frings, P, Beard, J, Bansai, B, Herlach, F, Peng, T and Zherlitsyn, S, 2010. Optimisation of large multiple coil systems for pulsed magnets.
  514. Pettit, D, 2013. The tyranny of the rocket equation.
  515. Peyrou, D, Pons, P, Granier, H, Leray, D, Ferrand, A, Yacine, K, Saadaoui, M, Nicolas, A, Tao, J & Plana, R, 2006. Multiphysics softwares benchmark on Ansys / Comsol applied for RF MEMS switches packaging simulations.
  516. Pilat, A & Turnau, A, 2010. Magnetic Levitation.
  517. Pilat, A & Zyla, M, 2013. Propulsion Control of the Semi Magnetically Levitated Cart.
  518. Unable to find — Polk JE et al (1996) A 1000-hour Wear test of the NASA NSTAR ion thruster, AIAA-962717, 32nd Joint Propulsion Conference
  519. Polk, J, Chaplin, V, Yim, J, Soulas, G, Williams, G & Shastry, R, 2021. Modeling grid Erosion in the NEXT ion thruster using the CEX2D and CEX3D codes.
  520. Poole Jr, C P, Farach, H A & Creswick, R J, 1995., Superconductivity.
  521. Potanina, L V, Shikov, A K, Vorobieva, A E, Salunin, N I, Medvedev, M I, Keilin, V E, Kovalev, I A, Kruglov, S L, 2008. Nb3SN And NbTi Multifilamentary Wires With Enhanced Heat Capacity.
  522. Pradhan, J, Bhunia, U, Roy, A, Panda, U, Bhattacharyya, T, Thakur, S, Khare, V, Das, M, Saha, S & Bandari, R, 2013. Basic Design and Test Results of High Temperature Superconductor Insert Coil for High Field Hybrid Magnet.
  523. Prescot, JC & El-Kharashi, AK, 1959. A method for measuring self-inductance applicable to large electrical machines.
  524. Prasad, KR, Koga, K & Miura, N, 2004. Electrochemical deposition of nanostructured indium oxide: high-performance electrode material for redox supercapacitors.
  525. Prescot, JC & El-Kharashi, AK, 1959. A method for measuring self-inductance applicable to large electrical machines.
  526. Proudlock, P, Russenschuck, S & Zerlauth, M, 2004. LHC Magnet Polarities, Engineering Specification.
  527. Pulch, R & Günther, M, 2002. A method of characteristics for solving multirate partial differential equations in radio frequency application.
  528. Pulikowski, D, Lackner, F, Scheuerlein, C & Pajor, M, 2017. Numerical modelling of a superconducting coil winding process with Rutherford type Nb3Sn cable.
  529. Pulikowski, D, 2018. Experimental and numerical investigation of the winding process of superconducting coils made of multi-strand Rutherford-type Nb3Sn cable. [D]
  530. Rabuffi, M & Picci, G, 2012. Status quo and future prospects for metallised polypropylene energy storage capacitors.
  531. Ramachandran, A, 2009. Methodologies for transient simulation of hybrid electromagnetic/circuit systems with multiple time scales.
  532. Ramanarayanan, V, Venkatesha, L & Panda, D, 1996. Flux-linkage characteristics of switched reluctance motor.
  533. Ramrakhyani, A, Mirabbasi, S & Chiao, M, 2011. Design and optimization of resonance-based efficient wireless power delivery systems for biomedical implants.
  534. Rana, A, Chaudhary, A & Karandikar, PB, 2013. Effect of carbon nanotubes on the capacitance of an ultra-capacitor.
  535. Randolph, TM, Dougherty, R, Oleson, SR & Fiehler, DI, 2005. The Prometheus 1 Spacecraft Preliminary Electric Propulsion System Design.
  536. Rao, H, Scarmozzino, R & Osgood, RM, 2002. An improved ADI-FDTD method and its application to photonic simulations.
  537. Ravaioli, E, 2015. CLIQ. A new quench protection technology for superconducting magnets.
  538. Ravaioli, E, Auchmann, B, Maciejewski, M, Ten Kate, H & Verweij, A, 2016. Lumped-element dynamic electrothermal model of a superconducting magnet.
  539. Ravaioli, E, Auchmann, B, Chlachidze, G, Maciejewski, M, Sabbi, G, Stoynev, SE, & Verweij, A, 2017. Modeling of interfilament coupling currents and their effect on magnet quench protection.
  540. Ray, WF & Erfan, E, 1994. A new method of flux or inductance measure- ment for switched reluctance motors.
  541. Rechenberg, I, 1973. Evolutionsstrategie: Optimierung technischer systeme nach prinzipien der biologischen evolution.
  542. Reed, C & Cichanowski, S, 1994. The fundamentals of aging in HV polymer film capacitors.
  543. Reich-Sprenger, H, Bellachioma, MC, Bender, M, Kollmus, H, Kramer, A, Kurdal, J & Spiller, PJ, 2004. R&D Vacuum Issues of the Future GSI Accelerator Facilities.
  544. Rios, J, Roascio, D, Reyneri, L, Sansoé, Passerone, C, Corso, D, Bruno, M, Hernandez, A, Vallan, A, 2011. ARAMIS: A fine grained modular architecture for reconfigurable space missions.
  545. Roeland, L, Gersdorf, R & Mattens, W, 1989. The 40-T facility of the University of Amsterdam.
  546. Rogalla, H & Kes, P H, 2012. 100 years of superconductivity.
  547. Rose-Innes, A C & Rhoderick, E H, 1978. Introduction to Superconductivity.
  548. Rossi, L & Sorbi, M, 2004. QLASA: A computer code for quench simulation in adiabatic multicoil superconducting windings.
  549. Rostand, E, 1897. Cyrano de Bergerac: A play in five acts.
  550. Roychowdhury, J, 2001. Analyzing circuits with widely separated time scales using numerical PDE methods.
  551. Ruehli, AE & Cangellaris, AC, 2001. Progress in the methodologies for the electrical modeling of interconnects and electronic packages.
  552. Runde, M, Magnusson, N, Fulbier, C & Buhrer, C, 2011. Commercial induction heaters with high temperature superconducting coils.
  553. Russenschuck, S, 1999. ROXIE: Routine for the Optimization of Magnet X-Sections, Inverse Field Calculations and Coil End Designs.
  554. Russenschuck, S, 2010. Field Computation for Accelerator Magnets.
  555. Russer, JA, 2010. Methodologies for electromagnetic field modeling for computer aided analysis of multidomain physical interactions. PhD Thesis, Univeristy of Illinois.
  556. Russer, JA, Sumant, PS & Cangellaris, AC, 2007. A Lagrangian approach for the handling of curved boundaries in the finite-difference time-domain method.
  557. Russer, JA, Sumant, PS & Cangellaris, AC, 2008. Modeling of curved boundaries in the finite-difference time-domain method using a Lagrangian approach.
  558. Russer, JA & Cangellaris, AC, 2008. An efficient methodology for the modeling of electromagnetic wave phenomena in domains with moving boundaries.
  559. Russer, P, 2006. Electromagnetics, Microwave Circuit and Antenna Design for Communications Engineering, 2nd ed.
  560. Saccoccia, G, 1999. European Electric Propulsion Activities and Programmes..
  561. Sadiku, MNO, 2000. Numerical Techniques in Electromagnetics, 2nd ed.
  562. Saint-James, D, Sarma, G & Thomas, E, 1969. Type II Superconductivity.
  563. Sarli, BV, Horikawa, M, Yam, CH, Kawakatsu, Y & Yamamoto, T, 2018. DESTINY+ Trajectory Design to (3200) Phaethon
  564. Scanlan, R M, Fietz, F A & Koch, E F, 1975. Flux pinning centers in superconducting Nb3Sn
  565. Schauer, W & Schelb, W, 1981. Improvement of Nb3Sn high field critical current by a two stage reaction.
  566. Scheuerlein, C, Fedelich, B, Alknes, P, Arnau, G, Bjoerstad, R & Bordini, B, 2015. Elastic anisotropy in multifilament Nb3Sn superconducting wires.
  567. Scheuerlein, C, Lackner, F, Savary, F, Rehmer, B, Finn, M & Uhlemann, P, 2017. Mechanical properties of the HL-LHC 11 Tesla Nb3Sn magnet constituent materials.
  568. Schillig, J, Boenig, H, Gordon, M, Mielke, C, Rickel, D & Sims, J, 2000. Operating experience of the United States’ national high magnetic field laboratory 60T long pulse magnet.
  569. Schimpf, P, 2013. A detailed explanation of solenoid force.
  570. Schmidt, R, Giloux, C, Hilaire, A, Ijspeerts, A, Rodriguez-Mateos, F & Sonnemann, F, 2000. Protection of the superconducting corrector magnets for the LHC.
  571. Schneuwly, A, Groning, P & Schlapbach, L, 1998. Breakdown behaviour in oil impregnated polypropylene as dielectric in film capacitors.
  572. Schoerling, D & Zlobin, A V, 2019. Nb3Sn Accelerator Magnets — Designs, Technologies and Performance.
  573. Schultz, L, de Haas, O, Verges, P, Beyer, C, Rohlig, S, Olsen, H, Kuhn, L, Berger, D, Noteboom, U & Funk, U, 2005. Superconductively Levitated Transport System — the SupraTrans project.
  574. Schwefel, H, 1977. Numerische optimierung von computer-modellen mittels der evolutionsstrategie.
  575. Shaw, B J, 1976. Grain size and film thickness of Nb3Sn formed by solid-state diffusion in the range 650–800 C.
  576. Seo, H, Lim, J, Choe, G, Choi, J & Jeong, J, 2018. Algorithm of Linear Induction Motor Control For Low Normal Force Of Magnetic Levitation Train Propulsion System.
  577. She, W, 2011. The Improved Electromagnetic Equations And Superconductivity.
  578. Shi, J, Han, X, Xie, J & Li, L, 2016. Analysis and Design of a Control System for the 100T Pulsed High Magnetic Field Facility at WHMFC.
  579. Sides, C & Martin, C, 2005. Nanostructured Electrodes And The Low-Temperature Performance Of Li-Ion Batteries.
  580. Silvester, P & Ferrari, R, 1996. Finite Elements for Electrical Engineers.
  581. Simon, JC, 1960. Action of a progressive disturbance on a guided electromagnetic wave.
  582. Simon, P & Gogotsi, Y, 2008. Materials For Electrochemical Capacitors.
  583. Simon, P, Gogotsi, Y & Dunn, B, 2014. Where Do Batteries End And Supercapacitors Begin?
  584. Sims, JR, Boeing, HJ, Campbell, LJ, Rockel, DG, Rogers, JD, Schillig, JB, Schneider-Muntau, HJ, 1997. Completion of the US NHMFL 60T quasicontinuous magnet.
  585. Sims, JR, Baca, A, Boebinger, G, Boenig, H, Coe, H, Kihara, K, Manzo, M, Mielke, C, Schillig, J, Eyssa, Y, Lesch, B, Li, L & schneider-Muntau, H, 2000. First 100T non-destructive magnet.
  586. Sims, JR, Schillig, JB, Boebinger, GS, Coe, H, Paris, AW, Gordon, MJ, Pacheco, MD, Abeln, TG, Hoagland, RG, Mataya, MC, Ke Han & Ishmaku, A, 2002. The U.S. NHMFL 60T long pulse magnet failure.
  587. Skourski, Y, Herrmannsdorfer T, Sytcheva, A, Wosnitza, J, Wustmann, B and Zherlitsyn, S, 2008. Finite element simulation and performance of pulsed magnets.
  588. Slater, JC, 1958. Interaction of waves in crystals.
  589. Smith, GD, 1999. Numerical Solution of Partial Differential Equations — Finite Difference Methods, 3rd ed.
  590. P. F. Smith, “Pulsed superconducting magnets for proton synchrotrons,” in Proc MT-2, Oxford, 1967, p. 594
  591. Soika, R, Anarella, MD, Ghosh, AK, Wanderer, P, Wilson, MN, Hassenzahl, WV, Kaugerts, J & Moritz, G, 2003. Inter-strand Resistance Measurements in Cored Rutherford Cables.
  592. Sommerfeld, A, 1912. Die Greensche Funktion der Schwingungsgleichung.
  593. Sommerfeld, A, 1949. Partial Differential Equations in Physics.
  594. Sommerfeld, A, 1950. Mechanics of Deformable Bodies (Lectures on Theoretical Physics, Vol 2)
  595. Song, S, Chen, S & Lin, Y, 2017. Characteristic and performance analysis of SRM with actual B-H curve of electrical steel.
  596. Song, J, Yu, Z, Gordin, ML, Hu, S, Yi, R, Tang, D, Walter, T, Regula, M, Choi, D, Li, X, Manivannan, A & Dong, W, 2014. Chemically bonded phosphorus/graphene hybrid as a high performance anode for sodium-ion batteries.
  597. Song, S, Chen, S & Lin, Y, 2017. Characteristic and performance analysis of SRM with actual B-H curve of electrical steel.
  598. F. Sonnemann and R. Schmidt, “Quench simulations for superconducting elements in the LHC accelerator,” Cryogenics, vol. 40, no. 8–10, pp. 519–529, 2000
  599. Sonnemann, F, 2001. Quench simulation studies: program documentation of SPQR simulation programs for quench research.
  600. Sovey, JS, Rawlins, VK & Patterson, MJ, 1999. A Synopsis of Ion Propulsion Development Projects in the United States — SERT I to Deep Space1
  601. Springer, E, Wilhelm, M, Weisse, H J & Rupp, G, 1984. Properties of (NbTa)3Sn Filamentary Conductors.
  602. Stanley, SB, Chew, G, Rapetti, R, Tofil, T, Herman, DA, Allen, M, Welander, B, Jackson, J & Myers, R, 2017. Development of a 13 kW Hall Thruster Propulsion System Performance Model for AEPS.
  603. Steer, MB, 2004. Multi physics multi scale modeling of microwave circuits and systems hybridizing circuit, electromagnetic and thermal modeling.
  604. Stekly, Z & Zar, J, 1965. Stable superconducting coils.
  605. Stephan, RM, de Andrade Jr, R, Santos, G, Neves, MA & Nicolsky, R. Levitation Force and Stability of Superconducting Linear Bearings Using NdFeB and Ferrite Magnets.
  606. Stephenson, RR, 1995. Electric Propulsion Development and Application in the United States.
  607. Street, A, 2003. Superconducting magnets: at the heart of NMR.
  608. Stuhlinger, E, 1964. Ion propulsion for space flight.
  609. Suenaga, M, Welch, D O, Sabatini, R L, Kammerer, O F & Okuda, S, 1986. Superconducting critical temperatures, critical magnetic fields, lattice parameters, and chemical compositions of “bulk” pure and alloyed Nb3Sn produced by the brone process.
  610. Summers, L T, Guinan, M W, Miller, J R & Hahn, P A, 1991. A model for the prediction of Nb3Sn critical current as a function of field, temperature, strain and radiation damage.
  611. Sun, X, Chen, L, Jiang, H, Yang, Z, Chen, J & Zhang, W, 2016. High-performance control for a bearingless permanent-magnet synchronous motor using neural network inverse scheme plus internal model controllers.
  612. Not found — Sun, C & Juang, J, 2012. Design & implementation of a microsatellite electric power subsystem.
  613. Sutter, DF & Strauss, BP, 2000. Next generation high energy physics colliders: technical challenges and prospects.
  614. Sutton, GP & Biblarz. O, 2017. Rocket Propulsion Elements. John Wiley & Sons.
  615. Not found — C. A. Swenson, B. L. Lesch, J. R. Sims, and H. J. Schneider-Muntau, “Generation of pulsed magnetic fields: Limitations, achievements, and prospects,” IEEE Trans. Appl. Superconduct., vol. 12, no. 1, 2002
  616. Swenson, C, Marshall, W, Gavrilin, A, Han, K, Schillig, J, Sims, J & Schneider-Muntau, H, 2004. Progress of the insert coil for the US-NHMFL 100 T multi-shot pulse magnet.
  617. Swenson, C, Gavrilin, A, Han, K, Walsh, R, Schneider-Muntau, H, Rickel, D, Schillig, J, Ammerman, C & Sims, J, 2006. Performance of 75T prototype pulsed magnet.
  618. Swenson, C, Rickel, D & Sims, J, 2008. 80T magnet operational performance and design implications.
  619. Tachikawa, K, Asano, T and Takeuchi, T, 1981). High‐field superconducting properties of the composite‐processed Nb3Sn with Nb‐Ti alloy cores
  620. Taflove, A & Hagness, S, 2005. Computational Electrodynamics: The Finite- Difference Time-Domain Method.
  621. Takamura, T, Sato, Y & Sato, Y, 2011. Capacitance Improvement Of Supercapacitor Active Material Based On Activated Carbon Fibre Working with A Li-Ion Containing Electrode.
  622. Tamir, T, Wang, H & Oliner, A, 1964. Wave propagation in sinusoidally stratified dielectric media.
  623. Taylor, D, 1984. On the mechanism of aluminium corrosion in metallised film AC capacitors.
  624. Taylor, MGGT, Altobelli, N, Buratti, BJ & Choukroun, M, 2017. The Rosetta mission orbiter science overview: the comet phase.
  625. Ten Haken, B, 1994. Strain effects on the critical properties of high-field superconductors.
  626. Ten Haken, B, Godeke, A & Ten Kate, HHJ, 1994. Calculation of the critical current reduction in a brittle wound multifilamentary wire due to external forces
  627. Ten Haken, B, Zaitseva, T N & Ten Kate, HHJ, 1994. Modeling of strain in multifilamentary wires deformed by thermal contraction and transverse forces.
  628. Ten Haken, B, Godeke, A & Ten Kate, HHJ, 1995. A reversible rise in the critical current of a Nb3Sn-bronze tape due to a transverse pressure
  629. Ten Haken, B, Godeke, A & Ten Kate, HHJ, 1997. Investigation of Microscopic Strain by X-Ray Diffraction in Nb3Sn Tape Conductors Subjected to Compressive and Tensile Strains.
  630. Ten Haken, B, Godeke, A & Ten Kate, HHJ, 1999. The strain dependence of the critical properties of Nb3Sn conductors
  631. Ten Kate, H, Boschman, H & Van de Klundert, L, 1987. Longitudinal propagation velocity of the normal zone in superconducting wires.
  632. Thomas, VC, Makowski, JM, Brown, GM, McCarthy, JF, Bruno, D, Cardoso, JC, Chiville, WM, Meyer, TF, Nelson, KE, Pavri, BE, Termohlen, DA, Violet, MD & Williams, JB, 2011. The Dawn spacecraft. Space Sci Rev 163:175–249.
  633. Thompson W T, 1986. Introduction to space dynamics.
  634. Thornton, R, Clark, T & Perreault, B, 2004. Linear synchronous motor propulsion in small transit vehicles.
  635. Tian, W, Li, M, Niu, J, Li, W & Shi, J, 2019. The research progress and comparisons between lithium-ion battery and sodium-ion battery.
  636. Ticker, R, Gates, M, Manzella, D, Biaggi-Labiosa, A & Lee, T, 2019. The Gateway Power and Propulsion Element: Setting the Foundation for Exploration and Commerce, AIAA Propulsion and Energy Forum, Indianapolis
  637. Tilley, D & Tilley, J, 1990. Superfluidity and Superconductivity.
  638. Timoshenko, S, 1956. Strength of materials, Part II, Elementary Theory and Problems.
  639. Tinkham, M, 1996. Introduction to Superconductivity, 2nd ed.
  640. Tkachenko, LM, Bogdanov, I, Kozub, S, Shcherbakov, P, Slabodchikov, P, Sytnikov, VV, Vasiliy, Z, Kaugerts, J & Gebhard, M, 2004. Comparison of Three Designs of Wide Aperture Dipole for SIS300 Ring
  641. Tkachenko, LM, Bogdanov, I, Kozub, S, Shcherbakov, P, Slabodchikov, P, Vasiliy, Z, Gebhard, M & Sytnikov, VE, 2004. Methods for Reducing Cable Losses in Fast-Cycling Dipoles for the SIS300 Ring.
  642. Toupin, M, Brousse, T & Bélanger, D, 2004. Charge Storage Mechanism of MnO2 Electrode Used in Aqueous Electrochemical Capacitor.
  643. Tsianikas, S, Zhou, J, Birnie III, DP & Coit, DW, 2019. Economic Trends and Comparisons for Optimizing Grid-Outage Resilient Photovoltaic and Battery Systems.
  644. Turchi, PJ, Davis, JF & Roderick, NF, 1990. MPD Thrust Chamber Flow Studies.
  645. Turchi, PJ, 1995. Electric rocket propulsion systems. In: Humble RW, Henry GN, Larson WJ (eds) Space propulsion analysis and design. McGraw-Hill, New York, pp 509–598
  646. Turchi, PJ, Mikellides, IJ, Mikellides, PG & Kanhawi, H, 2000. Pulsed Plasma Thrusters for Microsatellite Propulsion: Techniques for Optimization.
  647. Turchi, P, 2022. An Electric Propulsion Memoir.
  648. U.S. Geological Survey, 2015, Mineral commodity summaries 2015: U.S. Geological Survey, 196 p.,
  649. Vanacken, J, Li, L, Rosseel, K, Boon, W & Herlach, F, 2001. Pulsed Magnet Design Software.
  650. Van Bladel, JG, 2007. Electromagnetic Fields, 2nd ed.
  651. Van Bockstal, L, Heremans, G & Herlach, F, 1991. Coils with fibre composite reinforcement for pulsed magnetic fields in the T50–75 range.
  652. Van Delf, D, 2008. Heike Kamerlingh Onnes and the Quest For Cold.
  653. Van Delft, D, 2011. Heike Kamerlingh Onnes and the road to liquid helium.
  654. Van Sciver, S, 1986. Helium Cryogenics.
  655. Venturini, CC, Braun, BM, Hinkley, D & Berg, GF, 2017. Improving Mission Success of CubeSats.
  656. Verwij, AP, 1995. Electrodynamics of Superconducting Cables in Accelerator Magnets.
  657. Verweij, AP, 1997. Modelling boundary-induced coupling currents in Rutherford-type cables.
  658. Verweij, A, 2006, CUDI: A model for Calculation of Electrodynamic and Thermal Behaviour of Superconducting Rutherford Cables.
  659. Verweij, AP & Ten Kate, HJ, 1993. Coupling currents in Rutherford cables under time varying conditions.
  660. Vinciarelli, P, 1984. Optimal resetting of the transformers core in single ended forward converters.
  661. Vins & Sirovy, 2020. Assessing Suitability of Various Battery Technologies for Energy Storages : Lithium-ion, Sodium-sulfur and Vanadium Redox Flow Batteries
  662. Vladimirescu, A, 1994. The SPICE Book.
  663. Volpini, G, 2009. Quench propagation in 1-D and 2-D Models of High Current Superconductors.
  664. Wake, D, Gross, D, Yamada, R & Blatchley, B, 1979. AC loss in energy doubler magnets.
  665. Walivadekar, VN, Pillai, SK, Sadistap, SS & Bhandari, R, 1996. PC based data acquisition system for measurement of switched reluctance motor (SRM).
  666. Walker, M, Carr, W & Murphy, J, 1975. Loss behavior in twisted filamentary superconductors.
  667. Walter, M, Sommer-Dittrich, T & Zimmermann, J, 2011. Evaluating volume flexibility instruments by design-of-experiments methods.
  668. Walters, CR, 1975. Magnetization and design of multistrand superconducting conductors.
  669. Wanderer, P, Anerella, M, Ganetis, G, Ghosh, A, Joshi, P, Marone, A, Muratore, J, Schmalle, J, Soika, R, Thomas, R, Kaugerts, J, Moritz, G, Hessenzahl, W & Wilson, M, 2003. Initial test of a fast-ramped superconducting model dipole for GSIs proposed SIS200 accelerator.
  670. Wang, G, Liu, W, Sivaprakasam, M, Zhou, M, Weiland, JD & Humayun, MS, 2006. A dual band wireless power and data telemetry for retinal prosthesis.
  671. Wang, SF, Chen, T, Zhang, ZL, Pang, DW & Wong, KY, 2007. Effects of hydrophilic room-temperature ionic liquid 1-butyl-3-methylimidazolium tetrafluoroborate on direct electrochemistry and bioelectrocatalysis of heme proteins entrapped in agarose hydrogel films.
  672. Wang, S, Wang, J,Wang, X, Ren, Z, Zeng, Y, Deng, C, Jiang, H, Zhu, M, Lin, G, Xu, Z, Zhu, D & Song H, 2003. The Man-Loading High-Temperature Superconducting MagLev Test Vehicle.
  673. Wang X, Gao Y, 2016. Tensile behavior analysis of the Nb3Sn superconducting strand with damage of the filaments.
  674. Wang, X, Gao, Y & Zhou, Y, 2016. Electro-mechanical behaviors of composite superconducting strand with filament breakage.
  675. Wang, Y, Shi, Z, Huang, Y, Ma, Y, Wang, C, Chen, M & Chen, Y, 2009. Supercapacitor Devices Based On Graphene Materials.
  676. Weiglhofer, WS & Lakhtakia, A, 2003. Introduction to Complex Mediums for Optics and Electromagnetics.
  677. Unable to find this — Weise, T, Hofmann, J, Anderson, R, Jorling, J, Kerschke, R, Hermannsdorfer, T & Krug, H, 2004. The capacitive 49 MJ pulsed power supply system for the high magnetic field laboratory at FZ-Rossendorf.
  678. Weisend, J G, 1998. Handbook of cryogenic engineering.
  679. Welch, D.O, 1980. Alteration of the Superconducting Properties of A15 Compounds and Elementary Composite Superconductors by Nonhydrostatic Elastic Strain
  680. Welsby, V, 1950. The Theory and Design of Inductance Coils.
  681. Wenham, SR, Green, MA, Watt, ME and Corkish, R, 2007. Applied photovoltaics.
  682. West, A W & Rawlings, R D, 1977. A transmission electron microscopy investigation of filamentary superconducting composites
  683. White, MW, 2006. Viscous fluid flow.
  684. Williams, T & Carter, R, 1972. Measurement of machine inductances using an operational amplifier integrator.
  685. Wilson, MN, 1968. Computer simulation of the quenching of a superconducting magnet.
  686. Wilson, MN, 1972. Rate dependent magnetization in flat twisted superconducting cables.
  687. Wilson, M N, 1983. Superconducting magnets.
  688. Wilson, M N, 2004. Calculation of loss in the SIS300 dipole.
  689. Wilson, M N, 2004. Further Loss Calculation for Dipole 001.
  690. Wilson, M N, 2008. NbTi superconductors with low ac losses: a review.
  691. Wilson, M N, 2012. 100 years of superconductivity and 50 years of superconducting magnets.
  692. Wilson, M N, Anerella, M, Ganetis, G, Ghosh, A K, Joshi, P, Marone, A, Muehle, C, Muratore, J, Schmalzle, J, Soika, R, Thomas, R, Wanderer, P, Kaugerts, J, Moritz, G & Hassenzahl, W V, 2004. Measured and calculated losses in model dipole for GSI’s heavy ion synchrotron.
  693. Wilson, M N, Ghosh, A, Ten Haken, B, Hassenzahl, W, Kaugerts, J, Moritz, G, Muehle, C, Den Ouden, A, Soika, R, Wanderer, P & Wessel, W, 2003. Cored Rutherford cables for the GSI fast-ramping synchrotron.
  694. Wilson, M N, Moritz, G, Anerella, M, Ganetis, G, Ghosh, A K, Hassenzahl, W V, Jain, A, Joshi, P, Kaugerts, J, Muehle, C, Muratore, J, Thomas, R, Walter, G & Wanderer, P, 2002. Design studies on superconducting Cos theta Magnets for a fast pulsed synchrotron.
  695. Wilson, MN & Wolf, JR, 1997. Calculation of minimum quench energies in Rutherford cables.
  696. Wolf, F, Ebermann, P, Lackner, F, Mosbach, D, Scheuerlein, C, Schladitz, K & Schoerling, D, 2018. Characterization of the stress distribution on Nb3Sn Rutherford cables under transverse compression.
  697. Wolf F, Scheuerlein C, Lorentzon M, Katzer B, Hofmann M, Gan W, Lackner, F, Schoerling, D, Tommasini, D, Savary, F & Bottura, L, 2019. Effect of applied compressive stress and impregnation material on internal strain and stress state in Nb3Sn Rutherford cable stacks.
  698. Wright, J, Lee, D, Mohan, A, Papou, A, Smeys, P & Wang, S, 2010. Analysis of Integrated Solenoid Inductor With Closed Magnetic Core.
  699. Wu, H & Li, A, 1999. An Overview of Electric Propulsion Activities in CSSAR
  700. Wu, IW, Dietderich, DR, Holthuis, JT, Hong, M, Hassenzahl, WV & Morris Jr, JW, 1983. The microstructure and critical current characteristic of a bronze‐processed multifilamentary Nb3Sn superconducting wire.
  701. Wu, L, Lu, K & Xia, Y, 2018. Mutual Inductance Calculation Of Two Coaxial Solenoid Coils With Iron Core.
  702. Wu, MK, Ashburn, JR, Torng, CJ, Hor, PH, Meng, RL, Gao, L, Huang, ZJ, Quang, YQ & Chu, CW, 1987. Superconductivity at 93K in a New Mixed-Phase Y-Ba-Cu-O Compound System at Ambient Pressure.
  703. Xie, J, Zhao, P, Jing, Z, Zhang, C, Xia, N & Fu, J, 2018. Research on the sensitivity of magnetic levitation (Maglev) devices.
  704. Xie X, Su D, Chen S, Zhang J, Dou S, Wang G, 2014. SnS2 nanoplatelet graphene nanocomposites as high-capacity anode materials for sodium-ion batteries.
  705. Xiong, G, Meng, C, Reifenberger, R, Irazoqui, P & Fisher, T, 2014. A Review Of Graphene Based Electrochemical Microsupercapacitors
  706. Xiong, G, Kundu, A & Fisher, TS, 2015. Thermal Effects In Supercapacitors.
  707. Xu, C, Li, B, Du, H, Kang, F & Zeng, Y, 2008. Supercapacitive studies on amorphous MnO2 in mild solutions.
  708. Xu, J, Chen, C, Gao, D, Luo, S & Qian, Q, 2017. Nonlinear dynamic analysis on maglev train system with flexible guideway and double time-delay feedback control.
  709. Xu, J, Li, J & Guo, Z, 2015. Design and preliminary prototype test of a high temperature superconducting suspension electromagnet.
  710. Yagai T, Okubo T, Hira M, Kamibayashi M, Jimbo M, Kuwabara Y, Takao, T, Makida, Y, Shintomi, T, Hirano, N, Komagome, T, Tsukada, K, Onji, T, Arai, Y, Ishihara, A, Tomita, M, Miyagi, D, Tsuda, M & Hamajima, T, 2019. Stability Analysis of MgB2 Coils for SMES Application Consisting of Large-Scale Rutherford Cables.
  711. Yao, Y, Ni, G & Fang, Y, 2007. The computation of mechanical dynamic characteristic in EMS-Maglev system by electro- mechanical equations coupled finite element analysis.
  712. Yee, KS, 1966. Numerical solution of initial boundary value problems involving Maxwell’s equations in isotropic media.
  713. Yeh, C, Casey, K & Kaprielian, Z, 1965. Transverse magnetic wave propagation in sinusoidally stratified dielectric media.
  714. Yoon, CS, Park, KJ, Kim, UH, Kang, KH, Ryu, HH & Sun, YK, 2017. High-Energy Ni-Rich Li[NixCoyMn1-x-y]O2 Cathodes via Compositional Partitioning for Next-Generation Electric Vehicles
  715. Yu, C, Zhang, L, Shi, J, Zhao, J, Gao, J & Yan, D, 2008. A Simple Template-Free Strategy to Synthesize Nanoporous Manganese and Nickel Oxides with Narrow Pore Size Distribution, and Their Electrochemical Properties.
  716. Yuan, C, Zhang, X, Wu, Q & Gao, B, 2006. Effect Of Temperature On The Hybrid Supercapacitor Based On NiO And Activated Carbon With Alkaline Polymer Gel Electrolyte.
  717. Zeng, S, Liu, Y and Li, J, 2018. Meta model for 2D magnet-rail relationship based on step wise regression.
  718. Zhang, F, Zhang, T, Yang, X, Zhang, L, Leng, K, Huang, Y & Chen, Y, 2013. A High Performance Supercapacitor-Battery Hybrid Energy Storage Device Based On Graphene-Enhanced Electrode Materials With ultrahigh Energy Density.
  719. Zhang, H, 2013. Concepts of linear regulator and switching mode power supplies.
  720. Zhao, L, Hu, Y, Li, H, Wang, Z & Chen, L, 2011. Porous Li(4)Ti(5)O(12) Coated With N-Doped Carbon From Ionic Liquids For Li-Ion Batteries.
  721. Zherlitsyn, S, Bianchi, A, Hermannsdorfer, T, Pobell, F, Skourski, Y, Sytcheva, A, Zvyagin, S & Wosnitza, J, 2006. Coil design for non destructive pulsed-field magnets targeting 100T.
  722. Zherlitsyn, S, Herrmannsdorfer, T, Skourski, Y, Sytcheva, A & Wosnitza, J, 2007. Design of non-destructive pulsed magnets at the HLD.
  723. Zherlitsyn, S, Herrmannsdorfer, T, Wurstmann, B & Wosnitza, J, 2010. Design and performance of nondestructive pulsed magnets at the Dresden High Magnetic Field Laboratory.
  724. Zherlitsyn, S, Wurstmann, B, Herrmannsdorfer, T & Wosnitza, J, 2012. Status of the Pulsed-Magnet-Development Program at the Dresden High Magnetic Field Laboratory.
  725. Zhou, J, Ding, H, Liu, Y, Zhao, Z, Huang, Y, Fang, X & Wang, Q, 2017. A High Power Charging Power Supply For Capacitor in Pulsed Power System.
  726. Zhou, Y, Ghaffari, M, Lin, E, Parsons, E, Liu, Y, Wardle, B & Zhang, Q, 2013. High Volumetric Electrochemical Performance Of Ultra-High Density Aligned Carbon Nanotube Supercapacitors With Controlled Nanomorphology.
  727. Zhou, Y, Lachman, N, Ghaffari, M, Xu, H, Bhattacharya, D, Fattahi, P, Abidian, M, Wu, S, Gleason, K & Wardle, B, 2014. A High Performance Hybrid Asymmetric Supercapacitor Via Nano-Scale Morphology Control Of Graphene, Conducting Polymer And Carbon Nanotube Electrodes.
  728. Zhou, Y, Xu, H, Lachman, N, Ghaffari, M, Wu, S, Liu, Y, Ugur, A, Gleason, K, Wardle, B & Zhang, Q, 2014. Advanced Asymmetric Supercapacitor Based On Conducting Polymer And Aligned Carbon Nanotubes With Controlled Nanomorphology.
  729. Zhou, Y, Ghaffari, M, Lin, M, Xu, H, Xie, H, Koo, C & Zhang, M, 2015. High Performance Supercapacitor Under Extremely Low Environmental Temperature.
  730. Zimmerman, WBJ, 2006. Multiphysics Modelling with Finite Element Methods.
  731. Zou, H, Li, S, Wu, X, McDonald, MJ & Yang, Y, 2015. Spray-drying synthesis of pure Na2CoPO4F as cathode material for sodium ion batteries.
  732. Zube, D, Lichon, P, Cohen, D, Lichtin, D, Bailey, J & Chielli, N, 1999. Initial on-orbit performance of hydrazine arcjets on A2100 satellites.
  733. Životić-Kukolj, V, Soong, WL & Ertugrul, N, 2005. Modelling of saturation and cross-saturation effects in an interior PM automotive alternator.

Thanks for flicking through!


Founder /
Youtube / Podcast / Pitch Deck / White Paper
6 Industries Ready For Interorbital Transport

Angel donations help to continue startup activities and research!
BTC: 1MkkavrLCwvqDbohXeGGtTzfab5FVbEiF4

For any enquiries, please reach out to: