Literaturliste

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1.	Consolidation and characterisation of field-assisted sintered and hot pressed rapidly solidified hypereutectic Al-Si-Fe-X alloy, K.Y.Sastry, L. Froyen, J. Vleugels, O. Van der Biest, R. Schattevoy and K. Hummert, NMD-ATM 2004, 42nd National Metallurgist's Day, 58th Annual Technical Meeting 2004, November 17-19, 2004, The Indian Institute of Metals, Trivandrum, India p.312-313
2.	Field Assisted Sintering Technology ("FAST") for the consolidation of innovative materials, J. Hennicke, H.U. Kessel, cfi/Ber.DKG 81 [11] (2004) E14-E16.
3.	Mechanical milling and field assisted sintering consolidation of nanocrystalline AI-Si-Fe-X alloy powder, K. Y. Sastry, L. Froyen, J. Vleugels, O. Van der Biest, R. Schattevoy and J. Hennicke, Reviews on Advanced Materials Science 8 (2004) p 27-32
4.	Microstructure and Mechanical properties of Spark Plasma sintered ZrO₂-Al₂O₃-TiC0.5N0.5 composites, K. Vanmeensel, S.Y. Kandukuri, J. Hennicke, G. Anné D. Jiang, A. Laptev, J. Vleugels and O. Van der Biest, EMRS 2004, Poland
5.	Densification of nanocrystalline Ti(C,N) powders with nickel aluminide binder phases: Field Assisted Sintering (FAST) vs. Glass Encapsulated HIP, M. Alvarez, J.M. Sánchez, J. Etxeberria, L. Bourgeois, G. Barbier and J. Hennicke,. Proc. of 16th International Plansee Seminar 2005, Eds. G. Kneringer, P. Rödhammer and H. Wildner, vol. 2, HM22, 419-433, (2005).
6.	Development of CDCC Composites by either GE-HIP or Field Assisted Sintering Technology, L. Bourgeois, G. Barbier, J. Hennicke, H.-U. Kessel, V. Martinez, J. Echeberria, J.M. Sanchez and P. Harden, Proc. of 16th International Plansee Seminar 2005, Eds. G. Kneringer, P. Rödhammer and H. Wildner, vol. 2, HM46, 684-698, (2005).
7.	Effect of process parameters on density, structure and properties of field assisted sintered Al-Si-Fe-X alloy, K.Y.Sastry, L.Froyen, J.Vleugels, O.Van der Biest, R.Schattevoy and K.Hummert. Proceedings of the 4th International Conference on Science, Technology and Applications of Sintering, August-September 2005, Grenoble, France, CD-ROM p. 80-84
8.	Field assisted sintering of electro-conductive ZrO₂-based composites, K. Vanmeensel, D. Jiang, J. Vleugels and O. Van der Biest, Submitted to the 9th Conference and Exhibition of the European Ceramic Society, June 2005, Portoroz, Slovenia
9.	Field-assisted sintering technology for the consolidation of nano-structured powders and nano-composites, K. Lambrinou, K. Y. Sastry, K. Vanmeensel, J. Vleugels, L. Froyen, O. Van der Biest, Nanotech Insight 2005, February 2005, Luxor, Egypt, Abstractbook
10.	Finite Element Simulation of Field Assisted Sintering of WC-Co Hardmetals, K.Vanmeensel, A. Laptev, J. Hennicke, G. Anné, J.Vleugels, O.Van der Biest, Proc. of 16th International Plansee Seminar 2005, Eds. G. Kneringer, P. Rödhammer and H. Wildner, vol. 2, HM9, 266-282, (2005).
11.	High-Energy Ball-Milling Synthesis and Densification of Fe-Co Alloy Nanopowders by Field-Activated Sintering, R. Nicula, V.D. Cojocaru, M. Stir, J. Hennicke, E. Burkel, Int. Symp. Metastable Nano Mat. (ISMANAM) July 3-7, 2005, Paris
12.	Hot Pressing and Spark Plasma Sintering of Si₃N₄-SiC Nanocomposites, I. Zalite, N. Zhilinska, J. Grabis, P. Sajgalik, R. Kirchner, G. Kladler, Nano 05, Brno, Nov. 8-10, 2005
13.	Microstructure and Mechanical Properties of Spark Plasma Sintered ZrO₂-Al₂O₃-TiC0.5N0.5 Nanocomposites, K. Vanmeensel, K.Y. Sastry, J. Hennicke, G. Anné, D. Jiang, A. Laptev, J. Vleugels, and O. Van der Biest, Solid State Phenomena, 106 (2005) 153-160.
14.	Modelling of the temperature distribution for improvement of the SPS process, A Laptev, K. Vanmeensel, J. Vleugels, O. Van der Biest. Proceedings of the 4th International Conference on Science, Technology and Applications of Sintering, August-September 2005, Grenoble, France, CD-ROM p. 130-133.
15.	Modelling of the temperature distribution during field assisted sintering, K. Vanmeensel, A. Laptev, J. Hennicke, J. Vleugels and O. Van der Biest, Acta Materialia, 53 (2005) 4379-4388.
16.	Phase assembly and microstructure of CeO₂-doped ZrO₂ ceramics prepared by spark plasma sintering, Tao Xu, Peiling Wang, Pingan Fang, Yanmei Kan, Lidong Chen, Jef Vleugels, Omer Van der Biest, Jef Van Landuyt, Journal of the European Ceramic Society 25 (2005) 3437–3442
17.	Simulation of Temperature Evolution During Field Assisted Sintering of Rapidly Solidified Al-alloy Powder, K.Y. Sastry, K. Vanmeensel, L. Froyen, J. Vleugels, O. Van der Biest, A. Laptev and J. Hennicke, Euro PM2005 Powder Metallurgy Congress & Exhibition, page 99-105
18.	Sintering Behaviour of Low Co Content cBN-WC/Co Composites by Either GEHIP or FAST, J. Echeberria, V. Martínez, J.M. Sánchez, L. Bourgeois,G. Barbier and J. Hennicke, Proc. of 16th International Plansee Seminar 2005, Eds. G. Kneringer, P. Rödhammer and H. Wildner, vol. 2, HM23, 434-448, (2005).
19.	Feldaktives Sintern „FAST“ – ein neues Verfahren zur Herstellung metallischer und keramischer Sinterwerkstoffe, Heinz U. Kessel, Jürgen Hennicke, Jürgen Schmidt, Thomas Weißgräber, Bernd F. Kieback, Matthias Herrmann, Jan Räthel, 2006, Hagener Symposium
20.	Feldaktiviertes Sintern (FAST): Ein neues Verfahren zur Herstellung keramischer Nanowerkstoffe, Heinz U. Kessel, Jürgen Hennicke, DKG Symposium "Keramik aus Nanopulvern" , FA "Verfahrenstechnik"; Erlangen; 28.-29.11.2006
21.	Sintern von nichtoxidischen Nanopulvern, M. Herrmann, I. Schulz, DKG Symposium "Keramik aus Nanopulvern" , FA "Verfahrenstechnik"; Erlangen; 28.-29.11.2006
22.	Field Assisted Sintering and Characterisation of Ultrafine and Nanostructured Aluminium Alloys, Sastry Kandukuri, Thesis, July 2006, KUL Leuven (Belgium)
23.	Field assisted sintering consolidation of Al-Si-Fe-X alloy powder/flakes produced through air atomization/melt spinning, K.Y.Sastry, L.Froyen, J.Vleugels, O.Van der Biest, R.Schattevoy and K.Hummert, Materials Science Forum Vols. 519-521 (2006) pp. 1409-1
24.	Field Assisted Sintering of Cubic Boron Nitride Dispersed Cemented Carbide (CDCC) Composites, K. Vanmeensel, J. Echeberria, J.M. Sanchez, V. Martinez, L. Bourgeois, J. Hennicke, H.-U. Kessel, P. Harden, O. Van der Biest, J. Vleugels, EuroPM 2006
25.	High-energy ball-milling synthesis and densification of Fe-Co alloy nanopowders by field-activated sintering (FAST), R. Nicula, V.D. Cojocaru, M. Stir, J. Hennicke, E. Burkel, Journal of Alloys and Compounds 434-435 (2007) p. 362-366.
26.	Spark plasma sintering of Ti(C,N) cermets with intermetallic binder phases, M. Alvarez, J.M. Sánchez, International Journal of Refractory Metals & Hard Materials, 11 April 2006
27.	Aspects Concerning the Super-fast Sintering of Powder Metallic and Ceramic Materials, H.U. Kessel and J. Hennicke, Interceram vol. 56 (2007) [3] p. 164-166
28.	Aspekte zum superschnellen Sintern von pulvermetallurgischen und keramischen Werkstoffen, H.U. Kessel und J. Hennicke, Keramische Zeitschrift 3-2007 p. 188-190
29.	Characterization of Y₂O₃, CeO₂ and Y₂O₃+CeO₂ Doped FGM Tetragonal, ZrO₂ Ceramics by Spark Plasma Sintering, S.G. Huang, O. Van der Biest, J. Vleugels, K. Vanmeensel and L. Li, (2007) Trans Tech Publications, Switzerland, Key Engineering Materials Vol. 333 (2007) pp. 231-234
30.	Development of ZrO₂–WC composites by pulsed electric current sintering, S.G. Huang, K. Vanmeensel, O. Van der Biest, J. Vleugels, Journal of the European Ceramic Society 27 (2007) p. 3269–3275
31.	Entwicklung langzeitstabiler direkt beheizter Verdampferschiffchen; Herrmann, M.; Räthel, J.; Nürnberger, M.; Hennicke, J.; Müller, T.; Heike, S.; Poster; WING Konferenz; 22.-24.10.2007; Berlin
32.	Feldaktiviertes Sintern (FAST) von keramischen Werkstoffen, H.U. Kessel, M. Herrmann und J.Räthel, DKG Symposium "Thermische Verfahrenstechnik in der Keramik" , FA "Verfahrenstechnik"; Erlangen; 27.-28.11.2007
33.	Field assisted sintering of electro-conductive ZrO₂-based composites, K. Vanmeensel, A. Laptev, O. Van der Biest, J. Vleugels, Journal of the European Ceramic Society 27 (2007) p. 979–985
34.	Field Assisted Sintering of Zirconia-Based, Electrically Conductive Ceramic Composites, K. Vanmeensel, Thesis, May 2007, KUL Leuven (Belgium)
35.	Influence of CeO₂ Reduction on the Microstructure and Mechanical Preperties of Pulsed Electric Current Sintered Y₂O₃-CeO₂ Co-Stabilized ZrO₂ Ceramics, S. G. Huang, K. Vanmeensel, O. Van der Biest, J. Vleugels, Journal of the American Ceramic Society, Vol. 90, No. 5 (May 2007) p. 1420–1426
36.	Microstructure and Electrical Properties of Si₃N₄/TiN Composites Sintered by Hot Pressing and Spark Plasma Sintering. Z. Guo, G Blugan, R Kirchner, M.J. Reece, T Graule and J Kubler, Ceramic International, 33 p. 1223-1229 (2007)
37.	Neue technologische Entwicklungen und Anwendungen von Komponenten aus Siliciumcarbid und Siliciumnitrid, Technologie, G. Wötting, W. Martin, K. Berroth, H. U. Kessel cfi/Ber. DKG 84 (2007) No. 4 D15-D21
38.	Properties of NbC–Co cermets obtained by spark plasma sintering, S.G. Huang, O. Van der Biest, L. Li, J. Vleugels, , Materials Letters 61 (2007) p 574–577
39.	Spark plasma sintering (SPS) of transparent magnesium-aluminate spinel, N. Frage, S. Cohen, S. Meir, S. Kalabukhov, M.P. Dariel, Editorial Manager(tm) for Journal of Materials Science, Manuscript Draft, Manuscript Number: JMSC6553
40.	SPS Technology – A New Range of Possibilities for the FAST Consolidation of Innovative Material, Heinz Kessel, 5th Intl. Symposium on nitrides 2007
41.	Synthesis and microstructural features of ZrB2–SiC-based composites by reactive spark plasma sintering and reactive hot pressing, Wen-Wen Wu, Guo-Jun Zhang, Yan-Mei Kan, Pei-Ling Wang, Kim Vanmeensel, Jozef Vleugelsc and Omer Van der Biest, Scripta Materialia 57 (2007) p. 317–320
42.	Systematic Growth, cfi/Ber. DKG 84 (2007) No. 6 E16-E18
43.	The effect of the electrical properties on the pulsed electric current sintering behavior of ZrO₂ based ceramic composites, K. Vanmeensel, B. Neirinck, S. Huang, S. Salehi, O. Van der Biest, J. Vleugels, Ceramic Engineering and Science Proceedings. Vol. 28, no. 7, pp. 67-78. 2008
44.	The influence of percolation during pulsed electric current sintering of ZrO₂–TiN powder compacts with varying TiN content, K. Vanmeensel, A. Laptev, O. Van der Biest, J. Vleugels, , Acta Materialia 55 (2007) p. 1801–1811
45.	VC, Cr₃C₂ and NbC doped WC–Co cemented carbides prepared, by pulsed electric current sintering, S.G. Huang, L. Li, K. Vanmeensel, O. Van der Biest and J. Vleugels, International Journal of Refractory Metals & Hard Materials 25 (2007) p. 417–422
46.	Wachstum mit System, cfi/Ber. DKG 84 (2007) No. 6 D24-D25
47.	Binderless WC and WC–VC materials obtained by pulsed electric current sintering, S.G. Huang, K. Vanmeensel, O. Van der Biest and J. Vleugels, International Journal of Refractory Metals & Hard Materials 26 (2008) p. 41–47
48.	Densification of electrically conductive composites close to percolation threshold, J. Räthel, M. Herrmann, W. Beckert, M. Nürnberger, Advanced Processing for Novel Functional Materials (APNFM 2008), Dresden, 23 – 25 January 2008, pp.18-21
49.	FAST (SPS) Production Systems for the Powder Metallurgy and Ceramics Insustry, R. Kirchner, Cfi/Ber. DKG 85 (2008) No. 10, E19
50.	Field Activated Sintering Technology (FAST) for Ceramic Materials, J. Räthel, H.U. Kessel and M. Herrmann, cfi/Ber. DKG 85 (2008) No.13 p. 39-42
51.	Influence of starting powder on the microstructure of WC–Co hardmetals obtained by spark plasma sintering, S.G. Huanga, K. Vanmeensel, L. Lib, O. Van der Biest and J. Vleugels, Materials Science and Engineering A 475 (2008) 87–91
52.	Magnesium Aluminate Spinel Consolidated by FAST (Field Assisted Sintering Technique): Grain Growth Phenomena, S. Meir, S. Kalabukhov, N. Frumin, M. P. Dariel, N. Frage, Advanced Processing for Novel Functional Materials (APNFM 2008), Dresden, 23 – 25 January 2008, pp.434-438
53.	Microstructure and properties of boron carbide processed by FAST (Field Assisted Sintering Technology), S. Hayun, M. P. Dariel and N. Frage, Advanced Processing for Novel Functional Materials (APNFM 2008), Dresden, 23 – 25 January 2008, pp.200-205
54.	Nanocomposites consolidated by SPS Technology. O. Zgalat-Lozynskyy, A. Ragulya, M. Herrmann, M. Zamula, A. Deravyanko, Advanced Processing for Novel Functional Materials (APNFM 2008), Dresden, 23 – 25 January 2008, pp.443-449"
55.	NbC as grain growth inhibitor and carbide in WC–Co hardmetals, S.G. Huang, R.L. Liu, L. Li, O. Van der Biest and J. Vleugels, International Journal of Refractory Metals & Hard Materials 26 (2008) p. 389–395
56.	Pulsed electric current sintering of electrically conductive ceramics, K. Vanmeensel, S. G. Huang, A. Laptev, S. A. Salehi, A. K. Swarnakar, O. Van der Biest and J. Vleugels, J Mater Sci (2008) 43: p 6435–6440
57.	Rapid Hot Pressing of Copper Composites for Electronics’ Cooling Applications, Th. Schubert*, T. Weißgärber, B. Kieback, Advanced Processing for Novel Functional Materials (APNFM 2008), Dresden, 23 – 25 January 2008, pp.200-205
58.	Sintering and characterization of WC-NbC-Co hardmetals with VC and Cr₃C₂ additive, S.G. Huang, L. Li, O. Van der Biest, J. Vleugels, Advanced Processing for Novel Functional Materials (APNFM 2008), Dresden, 23 – 25 January 2008, pp.342-349
59.	Spark Plasma Sintering of Advanced Hard Materials, O. Van der Biest, S. Huang, K. Vanmeensel, A. Laptev, J. Vleugels, Advanced Processing for Novel Functional Materials (APNFM 2008), Dresden, 23 – 25 January 2008, pp.7-13
60.	Spark Plasma Sintering of Conductive and Nonconductive Composites (BN-TiB₂), M. Herrmann, J. Raethel, W. Beckert, International Conference on Sintering November 16-20, 2008 La Jolla (California, USA)
61.	Tailored sintering of VC-doped WC–Co cemented carbides by pulsed electric current sintering, S.G. Huang, K. Vanmeensel, L. Li, O. Van der Biest and J. Vleugels, International Journal of Refractory Metals & Hard Materials 26 (2008) p. 256–26
62.	Temperature distribution during Spark Plasma Sintering; J. Raethel, M. Herrmann, W. Beckert, International Workshop on Spark Plasma Sintering; Avignon, France; 06.-07.10.2008
63.	VC- and Cr₃C₂-doped WC–NbC–Co hardmetals, S.G. Huang, L. Li, O. Van der Biest and J. Vleugels, Journal of Alloys and Compounds 464 (2008) p. 205–211
64.	Y₂O₃ and Nd₂O₃ co-stabilized ZrO₂-WC composites, Sedigheh Salehi, Omer Van der Biest and Jef Vleugels, J Materials Science (2008) 43 p 5784–5789
65.	Bulk Nanoceramics and Nanocomposites: Processed by Pulsed Electric Current Sintering (PECS), O. Van der Biest, K. Vanmeensel, S. Huang and J. Vleugels, MS&T 09, Pittsburgh October 25-29, 2009
66.	Temperature distribution for electrically conductive composite material; Räthel, J.; Herrmann, M.; Vortrag; Sintering 2009; 07-11.10.2009; Kiev, Ukraine
67.	Neuartige Stahl-Hartstoff-Verbundwerkstoffsysteme - ein möglicher Schlüssel zur Kraftstoffreduktion, A. Winkelmann, A.M. Huber, R. Oberacker, S. Schwarz, J. Hennicke, A. Nagel, S. Reymann, 2009, Hagener Symposium
68.	Novel Current Induced Short-Time Sintering Processes for the Production of Diamond Tools, W. Tillmann, C. Kronholz, M. Ferreira, EuroPM 2009
69.	Sintered Materials on the Way to Production by Means of Modern SPS Technologies, H.U. Kessel, cfi/Ber.DKG 86 [10] (2009) E145-E154.
70.	Spark Plasma Sintering/ Field Assisted Sintering of Ceramic Materials, M. Herrmann, J. Raethel and I Schulz, Interceram, Vol.58 (2009), No.2-3, pp.109-114
71.	Temperature distribution for electrically conductive and non-conductive materials during Field Assisted Sintering (FAST), J. Räthel, M. Herrmann and W. Beckert, Journal of the European Ceramic Society 29 (2009) p.1419–1425
72.	Y₂O₃–Nd₂O₃ double stabilized ZrO₂–TiCN nanocomposites, S. Salehi, B. Yüksel, K. Vanmeensel, O. Van der Biest and J. Vleugels, Materials Chemistry and Physics 113 (2009) p. 596–601
73.	FAST/SPS - Schnellsintertechnik und ihre Anwendung in Labor und Produktion, H.U.Kessel, J.Hennicke, Handb. Techn. Keram. Werkst. (Ed.: J.Kriegesmann), Kap. 3.6.7.1., Jan. 2010
74.	Spark Plasma Sintering of Novel Materials - taking the next step towards industrial production, H.U.Kessel, J.Hennicke, R.Kirchner, T.Kessel, (ICACC-S8-060-2010), 34th International Conference on Advanced Ceramics and Composites, American Ceramic Society, January 24-29, 2010, Daytona Beach, FL, USA
75.	Rapid Sintering of Novel materials by FAST/SPS – Further Development to the Point of an Industrial Production Process with High Cost Efficiency, H.U.Kessel, J.Hennicke, R.Kirchner, T.Kessel, Februar 2010
76.	Kurzzeitsintern neuer Materialien mittels FAST/SPS - Vom Labor zum kosteneffizienten Produktionsverfahren, H.U.Kessel, J.Hennicke, R.Kirchner, T.Kessel, April 2010
77.	Fast Siliconization of C/C-Preforms via LSI, A. Konschak, R. Schulte, W. Krenkel, J. Hennicke, H.U. Kessel, 7th International Conference on High Temperature Ceramic Matrix Composites HTCMC 20-22 Sept 2010, Bayreuth, Germany
78.	Kurzzeitsintern zur kosteneffektiven Produktion und Werkstoffentwicklung, H.U. Kessel, J. Hennicke, T. Kessel, cfi/Ber. DKG 87 (2010) No. 10, D15-D18
79.	Short-Time Sintering for Cost-Efficient Production and Material Development, H.U. Kessel, J. Hennicke, T. Kessel, cfi/Ber. DKG 87 (2010) No. 10, E23-E26
80.	Kurzzeitsintern als Produktionsverfahren für die Pulvermetallurgie, J. Hennicke, H.U. Kessel, T. Kessel, 2010, Hagener Symposium
81.	2010 Hagen Symposium Reports: Nanostructured PM Materials, G.Schlieper, http://www.ipmd.net/articles/001052.html
82.	2010 Hagen Symposium Reports: Aluminium alloys for demanding applications, G.Schlieper, http://www.ipmd.net/articles/001085.html
83.	2010 Hagen Symposium Reports: Improved material properties with short-time sintering, G.Schlieper, http://www.ipmd.net/articles/001095.html
84.	2011-07 CFI Sonderdruck: Effiziente Sinteranlagen für die Produktion von Ingenieurkeramik, J. Hennicke, H.U. Kessel, R. Kirchner, cfi/Ber. DKG 88 (2011) No. 6-7 D21-D24 2011-07 Reprint from CFI: Efficient Sintering Equipment for the Production of Engineering Ceramics, J. Hennicke, H.U. Kessel, R. Kirchner, cfi/Ber. DKG 88 (2011) No. 6-7 E33-E36