Sten Vollebregt

Publications

  1. Infrared absorbance of vertically-aligned multi-walled CNT forest as a function of synthesis temperature and time
    Amir Mirza Gheytaghia; Amir Ghaderi; Sten Vollebregt; Majid Ahmadic; Reinoud Wolffenbuttel; GuoQi Zhang;
    Materials Research Bulletin,
    2020. DOI: https://doi.org/10.1016/j.materresbull.2020.110821

  2. Wafer-scale transfer-free process of multi-layered graphene grown by chemical vapor deposition
    Filiberto Ricciardella; Sten Vollebregt; Bart Boshuizen; F.J.K. Danzl; Ilkay Cesar; Pierpaolo Spinelli; Pasqualina Maria Sarro;
    Material Research Express,
    2020. DOI: https://doi.org/10.1088/2053-1591/ab771e

  3. Toward a Self-Sensing Piezoresistive Pressure Sensor for all-SiC Monolithic Integration
    L.M. Middelburg; H.W. van Zeijl; S. Vollebregt; B. Morana; GuoQi Zhang;
    IEEE Sensors,
    Volume 20, Issue 19, pp. 11265-11274, 2020. DOI: 10.1109/JSEN.2020.2998915

  4. Low-Humidity Sensing Properties of Multi-Layered Graphene Grown by Chemical Vapor Deposition
    Filiberto Ricciardella; Sten Vollebregt; Tiziana Polichetti; Pasqualina M. Sarro; Georg S. Duesberg;
    MDPI Sensors,
    Volume 20, Issue 11, pp. 3174, 2020.
    document

  5. Vertically-Aligned Multi-Walled Carbon Nano Tube Pillars with Various Diameters under Compression: Pristine and NbTiN Coated
    Amir Mirza Gheitaghy; René H. Poelma; Leandro Sacco; Sten Vollebregt; GuoQi Zhang;
    MDPI Nanomaterials,
    Volume 10, Issue 6, pp. 1189, 2020. DOI: https://doi.org/10.3390/nano10061189

  6. Low power AlGaN/GaN MEMS pressure sensor for high vacuum application
    Jianwen Sun; Dong Hu; Zewen Liu; Luke Middelburg; Sten Vollebregt; Pasqualina M.Sarro; GuoqiZhanga;
    Sensors and Actuators A: Physical,
    2020.
    document

  7. Surface-micromachined Silicon Carbide Pirani Gauges for Harsh Environments
    Jiarui Mo; L.M. Middelburg; B. Morana; H.W. Van Zeijl; S. Vollebregt; GuoQi Zhang;
    IEEE Sensors,
    2020.
    document

  8. Wafer-scale Graphene-based Soft Implant with Optogenetic Compatibility
    Andrade Velea; Sten Vollebregt; Gandhika Wardhana; Vasso Giagka;
    In IEEE Int. Conf. on Micro Electro Mechanical Systems (MEMS 2020),
    2020.

  9. Analysis of a calibration method for non-stationary CVD multi-layered graphene-based gas sensors
    Filiberto Ricciardella; Tiziana Polichetti; Sten Vollebregt; Brigida Alfano; Ettore Massera; Lina Sarro;
    IOP Nanotechnology,
    Volume 30, pp. 385501-1-8, 2019. DOI: 10.1088/1361-6528/ab2aac
    document

  10. Growth of multi-layered graphene on molybdenum catalyst by solid phase reaction with amorphous carbon
    Filiberto Ricciardella; Sten Vollebregt; Evgenia Kurganova; A.J.M. Giesbers; Majid Ahmadi; Lina Sarro;
    2D Materials,
    Volume 6, pp. 035012, 2019. DOI: 10.1088/2053-1583/ab1518

  11. Low-friction, wear-resistant, and electrically homogeneous multilayer graphene grown by chemical vapor deposition on molybdenum
    Borislav Vasic; Uros Ralevic; Katarina Cvetanovic Zobenica; Milce Smiljanic; Rados Gajic; Marko Spasenovic; Sten Vollebregt;
    Applied Surface Science,
    pp. 144792, 2019.
    document

  12. Mass measurement of graphene using quartz crystal microbalances
    Robin J Dolleman; Mick Hsu; Sten Vollebregt; John E Sader; Herre SJ van der Zant; Peter G Steeneken; Murali K Ghatkesar;
    Applied Physics Letters,
    Volume 115, Issue 5, pp. 053102, 2019. DOI: https://doi.org/10.1063/1.5111086
    document

  13. Towards an Active Graphene-PDMS Implant
    Wardhana, G. K.; Serdijn, W.; Vollebregt, S.; Giagka, V.;
    In Abstract from 7th Dutch Bio-Medical Engineering Conference,
    2019.
    document

  14. A wafer-scale process for the monolithic integration of CVD graphene and CMOS logic for smart MEMS/NEMS sensors
    Joost Romijn; Sten Vollebregt; Henk W. van Zeijl; Pasqualina M. Sarro;
    In IEEE 32nd International Conference on Micro Electro Mechanical Systems (MEMS). Piscataway: IEEE,
    2019. DOI: https://doi.org/10.1109/MEMSYS.2019.8870741

  15. Flexible, graphene-based acive implant for spinal cord stimulation in rodents
    Andrada Velea; Sten Vollebregt; Vasiliki Giagka;
    In SAFE/ProRISC,
    2019.

  16. Towards a Microfabricated Flexible Graphene-Based Active Implant for Tissue Monitoring During Optogenetic Spinal Cord Stimulation
    Andrada Iulia Velea; Sten Vollebregt; Tim Hosman; Anna Pak; Vasiliki Giagka;
    In Proc. IEEE NMDC,
    2019.

  17. Transfer-free Graphene-based Differential Pressure Sensor
    Raghutham Ramesha; Sten Vollebregt; Lina Sarro;
    In Proc. IEEE NMDC,
    2019.

  18. Free-standing, Transfer-free Graphene-based Differential Pressure Sensors
    R. Ramesha; S. Vollebregt; P.M. Sarro;
    In SAFE/ProRISC,
    2019.

  19. Wafer-scale integration of CVD graphene on CMOS devices using a transfer-free approach
    Sten Vollebregt; Joost Romijn; Henk W. van Zeijl; Pasqualina M. Sarro;
    In Graphene Week,
    2019.

  20. Compressive response of pristine and superconductor coated MWCNT pillars
    A. M. Gheytaghi; S. Vollebregt; R.H. Poelma; H. W. Zeijl; GuoQi Zhang;
    In IEEE MEMS,
    2019.

  21. Graphene pellicle lithographic apparatus
    Evgenia Kurganova; Jos Giesbers; Maria Peter; Maxim Naselevich; Arnoud Notenboom; Alexander Klein; Pieter-Jan van Zwol; David Vles; Pim Voorthuijzen; Sten Vollebregt;
    Patent, WO2019170356, 2019.

  22. Full wafer transfer-free graphene
    Filiberto Ricciardella; Sten Vollebregt; Lina Sarro;
    Patent, WO2019125140; NL2020111, 2019.

  23. Grafeen: een zoektocht naar de toepassing
    Sten Vollebregt; Jos Giesbers; Johan Klootwijk;
    Nederlands Tijdschrift voor Natuurkunde,
    pp. 16-20, September 2018.

  24. Carbon Nanotube Array: Scaffolding Material for Opto, Electro, Thermo, and Mechanical Systems
    Amir M. Gheytaghi; H. van Zeijl; S. Vollebregt; R.H. Poelma; C. Silvestri; R. Ishihara; G. Q. Zhang; P. M. Sarro;
    Innovative Materials,
    Volume 3, pp. 22-25, 2018.

  25. Effects of Conformal Nanoscale Coatings on Thermal Performance of Vertically Aligned Carbon Nanotubes
    Cinzia Silvestri; Michele Riccio; René H. Poelma; Aleksandar Jovic; Bruno Morana; Sten Vollebregt; Andrea Irace; GuoQi Zhang; Pasqualina M. Sarro;
    Small,
    Volume 14, Issue 20, pp. 1800614, 2018. DOI: 10.1002/smll.201800614

  26. A transfer-free approach to wafer-scale graphene deposited by chemical vapour deposition
    Sten Vollebregt; Filiberto Ricciardella; Joost Romijn; Manvika Singh; Shengtai Shi; Lina Sarro;
    In Graphene Conference,
    2018. (invited).
    document

  27. Making large free-standing multi-layer graphene/graphitic membranes
    Evgenia Kurganova; A.J.M. Giesbers; Sten Vollebregt; Arnoud Notenboom; David Vles; Maxim Nasalevich; Peter van Zwol;
    In Graphene Conference,
    2018.

  28. A Miniaturized Low Power Pirani Pressure Sensor Based on Suspended Graphene
    Joost Romijn; Sten Vollebregt; Robin J. Dolleman; Manvika Singh; Herre S.J. van der Zant; Peter G. Steeneken; Pasqualina M. Sarro;
    In Proceedings of IEEE NEMS,
    2018.

  29. Wafer-scale CVD graphene integration: a transfer-free approach
    Sten Vollebregt;
    In GrapChina,
    2018. (invited).

  30. Wafer Level Through-polymer Optical Vias (TPOV) Enabling High Throughput of Optical Windows Manufacturing
    Z. Huang; R.H. Poelma; S. Vollebregt; M.H. Koelink; E. Boschman; R. Kropf; M. Gallouch; GuoQi Zhang;
    In IEEE Electronics System-Integration Technology Conference (ESTC),
    pp. 1-5, 2018.

  31. Effect of droplet shrinking on surface acoustic wave response in microfluidic applications
    Thu Hang Bui; Van Nguyen; Sten Vollebregt; Bruno Morana; Henk van Zeijl; Trinh Chu Duc; P.M. Sarro;
    Applied Surface Science,
    Volume 426, pp. 253-261, 2017.
    document

  32. Effects of Graphene Monolayer Coating on the Optical Performance of Remote Phosphors
    Maryam Yazdan Mehr; S. Vollebregt; W. D. van Driel; GuoQi Zhang;
    Journal of Electronic Materials,
    Volume 46, Issue 10, pp. 5866--5872, 2017. DOI: 10.1007/s11664-017-5592-8
    Keywords: ... graphene, Light-emitting diode, reliability, remote phosphor.

  33. Effects of graphene defects on gas sensing properties towards NO2 detection
    Filiberto Ricciardella; Sten Vollebregt; Tiziana Polichetti; Mario Miscuglio; Brigida Alfano; Maria L. Miglietta; Ettore Massera; Girolamo Di Francia; Pasqualina M. Sarro;
    Nanoscale,
    Volume 9, pp. 6085-6093, 2017.
    document

  34. CVD transfer-free graphene for sensing applications
    Chiara Schiattarella; Sten Vollebregt; Tiziana Polichetti; Brigida Alfano; Ettore Massera; Maria Lucia Miglietta; Girolamo Di Francia; Pasqualina Maria Sarro;
    Beilstein Journal of Nanotechnology,
    Volume 8, pp. 1015-1022, 2017.
    document

  35. Carbon Nanotubes as Vertical Interconnects for 3D Integrated Circuits
    Sten Vollebregt; Ryoichi Ishihara;
    In Carbon Nanotubes for Interconnects,
    Springer International Publishing, 2017.
    document

  36. A transfer-free wafer-scale method for the fabrication of suspended graphene beams for squeeze-film pressure sensors
    S. Vollebregt; R.J. Dolleman; H.S.J. van der Zant; P.G. Steeneken; P.M. Sarro;
    In Graphene Week,
    2017.

  37. An Innovative Approach to Overcome Saturation and Recovery Issues of CVD graphene-Based Gas Sensors
    F. Ricciardella; S. Vollebregt; T. Polichetti; B. Alfano; E. Massera; P. M. Sarro;
    In Proceedings of IEEE Sensors Conference,
    pp. 1224-1226, 2017.

  38. Wafer-scale measurements of the specific contact resistance between different metals and mono- and multi-layer graphene
    S. Vollebregt; M. Singh; D.J. Wehenkel; R. van Rijn; P.M. Sarro;
    In Proc. of the 43rd international conference on Micro and Nanoengineering (MNE),
    pp. 152, 2017.

  39. Low Temperature CVD Grown Graphene for Highly Selective Gas Sensors Working under Ambient Conditions
    Filiberto Ricciardella; Sten Vollebregt; Tiziana Polichetti; Brigida Alfano; Ettore Massera; Pasqualina M. Sarro;
    In Proceedings of Eurosensors 2017,
    pp. 445, 2017.
    document

  40. High sensitive CVD graphene-based gas sensors operating under environmental conditions
    Filiberto Ricciardella; Sten Vollebregt; Tiziana Polichetti; Brigida Alfano; Ettore Massera; Pasqualina M. Sarro;
    In Graphene Conference,
    2017.

  41. Suspended graphene beams with tunable gap for squeeze-film pressure sensing
    S. Vollebregt; R.J. Dolleman; H.S.J. van der Zant; P.G. Steeneken; P.M. Sarro;
    In Proc.of Transducers 2017, the 19th International Conference on Solid-state Sensors, Actuators, and Microsystems,
    pp. 770-773, 2017.

  42. Horizontally aligned carbon nanotube scaffolds for freestanding structures with enhanced conductivity
    Cinzia Silvestri; Federico Marciano; Bruno Morana; Violeta Podranovic; Sten Vollebregt; GuoQi Zhang; Pasqualina M Sarro;
    In Micro Electro Mechanical Systems (MEMS), 2017 IEEE 30th International Conference on,
    pp. 266-269, 2017.

  43. Fabrication and characterization of an Upside-down Carbon Nanotube (CNT) Microelectrode array (MEA)
    Gaio, N.; Silvestri, C.; van Meer, B.; Vollebregt, S.; Mummery, C.; Dekker, R.;
    IEEE Sensors Journal,
    Volume 16, Issue 24, pp. 8685, 2016.

  44. Thermal characterization of carbon nanotube foam using MEMS microhotplates and thermographic analysis
    Cinzia Silvestri; Michele Riccio; Rene Poelma; Bruno Morana; Sten Vollebregt; Fabio Santagata; Andrea Irace; GuoQi Zhang; Pasqualina M. Sarro;
    Nanoscale,
    Volume 8, pp. 8266-8275, 2016.
    document

  45. Stretchable Binary Fresnel Lens for Focus Tuning
    Xueming Li; Lei Wei; Ren� H. Poelma; Sten Vollebregt; Jia Wei; Hendrik Paul Urbach; Pasqualina M. Sarro; GuoQi Zhang;
    Scientific Reports,
    Volume 6, pp. 25348, 2016.

  46. The growth of carbon nanotubes on electrically conductive ZrN support layers for through-silicon vias
    Sten Vollebregt; Sourish Banerjee; Frans D. Tichelaar; Ryoichi Ishihara;
    Microelectronic Engineering,
    Volume 156, pp. 126-130, 2016.
    document

  47. The Direct Growth of Carbon Nanotubes as Vertical Interconnects in 3D Integrated Circuits
    Sten Vollebregt; Ryoichi Ishihara;
    Carbon,
    Volume 96, pp. 332-338, 2016.
    document

  48. High sensitive gas sensors realized by a transfer-free process of CVD graphene
    Filiberto Ricciardella; Sten Vollebregt; Tiziana Polichetti; Brigida Alfano; Ettore Massera; Lina Sarro;
    In Proceedings of the IEEE Sensors conference,
    2016.

  49. A predefined wafer-scale CVD graphene deposition method requiring no transfer
    Sten Vollebregt; Lina Sarro;
    In Graphene Week,
    2016.

  50. A transfer-free wafer-scale CVD graphene fabrication process for MEMS/NEMS sensors
    S. Vollebregt; B. Alfano; F. Ricciardella; A.J.M. Giesbers; Y. Grachova; H.W. van Zeijl; T. Polichetti; P.M. Sarro;
    In Proc. of the 29th IEEE International Conference of Micro Electro Mechanical Systems,
    pp. 17-20, 2016.

  51. Fabrication of Low Temperature Carbon Nanotube Vertical Interconnects Compatible with Semiconductor Technology
    S. Vollebregt; R. Ishihara;
    Journal of Visual Experiments,
    Volume 106, pp. e53260, 2015.
    document

  52. Impact of the atomic layer deposition precursors diffusion on solid-state carbon nanotube based supercapacitors performances
    G Fiorentino; S Vollebregt; FD Tichelaar; R Ishihara; PM Sarro;
    IOP Nanotechnology,
    Volume 26, Issue 6, pp. 064002, 2015.
    document

  53. Doped Carbon Nanotubes for Interconnects
    J. Robertson; S. Esconjauregui; L. D’Arsie; J. Yang; H. Sugime; G. Zhong; Y. Guo; S. Vollebregt; R. Ishihara; C. Cepek; G. Duesberg; T. Hallam;
    In Extended Abstracts of the 2015 International Conference on Solid State Devices and Materials (SSDM),
    2015.

  54. Carbon nanotubes TSV grown on an electrically conductive ZrN support layer
    Sten Vollebregt; Sourish Banerjee; Frans D. Tichelaar; Ryoichi Ishihara;
    In IEEE International Interconnect Technology Conference,
    pp. 281-283, 2015.

  55. Tunable binary fresnel lens based on stretchable PDMS/CNT compsite
    Xueming Li; L. Wei; S. Vollebregt; R. Poelma; Y. Shen; Jia Wei; P. Urbach; P.M. Sarro; GuoQi Zhang;
    In Transducers,
    pp. 2041-2044, 2015.

  56. Molybdenum grown CVD graphene Schottky diodes
    S. Vollebregt; F. Ricciardella; Y. Grachova; T. Polichetti; P.M. Sarro;
    In Graphene Week,
    2015.

  57. Crystallinity variations over the length of vertically aligned carbon nanotubes grown by chemical vapour deposition
    S. Vollebregt; P. Padmanabhan; C. Silvestri; P.M. Sarro;
    In 41st Micro and Nano Engineering conference,
    2015.

  58. The Role of Edge Defects in Liquid Phase Exfoliated and Chemical Vapor Deposited Graphene for NO2 Detection
    F Ricciardella; S Vollebregt; T Polichetti; B Alfano; PM Sarro; ML Miglietta; E Massera; G Di Francia;
    In GraphITA,
    2015.

  59. Upside-down Carbon Nanotube (CNT) Micro-electrode Array (MEA)
    N. Gaio; B. van Meer; C. Silvestri; Saeed Khoshfetrat Pakazad; S. Vollebregt; C.L. Mummery; R. Dekker;
    In IEEE Sensors Conference,
    2015.

  60. Dominant thermal boundary resistance in multi-walled carbon nanotube bundles fabricated at low temperature
    Vollebregt, Sten; Banerjee, Sourish; Chiaramonti, Ann N; Tichelaar, Frans D; Beenakker, Kees; Ishihara, Ryoichi;
    Journal of Applied Physics,
    Volume 116, Issue 2, pp. 023514, 2014.

  61. Carbon nanotube vertical interconnects fabricated at temperatures as low as 350 �C
    Vollebregt, Sten; Tichelaar, FD; Schellevis, H; Beenakker, CIM; Ishihara, R;
    Carbon,
    Volume 71, pp. 249--256, 2014.

  62. Failure Analysis and Reliability of Low-Temperature-Grown Multi-Wall Carbon Nanotube Bundles Integrated as Vias in Monolithic Three-Dimensional Integrated Circuits
    Chiaramonti, Ann N; Vollebregt, Sten; Sanders, Aric W; Ishihara, Ryoichi; Read, David T;
    Microsc. Microanal,
    Volume 20, pp. 1762-1763, 2014.

  63. Tailoring the Mechanical Properties of High-Aspect-Ratio Carbon Nanotube Arrays using Amorphous Silicon Carbide Coatings
    Poelma, RH; Morana, Bruno; Vollebregt, Sten; Schlangen, Erik; van Zeijl, HW; Fan, Xuejun; Zhang, GuoQi;
    Advanced Functional Materials,
    Volume 24, Issue 36, pp. 5737-5744, 2014.
    document

  64. Carbon Nanotube Vertical Interconnects: Prospects and Challenges
    Vollebregt, S; Beenakker, CIM; Ishihara, R;
    In Micro-and Nanoelectronics: Emerging Device Challenges and Solutions,
    CRC Press, 2014.

  65. High Quality Wafer-scale CVD Graphene on Molybdenum Thin Film for Sensing Application
    Yelena Grachova; Sten Vollebregt; Andrea Leonardo Lacaita; Pasqualina M. Sarro;
    In Procedia Engineering 87: EUROSENSORS 2014, the 28th European Conference on Solid-State Transducers,
    pp. 1501-1504, 2014.
    document

  66. 3D solid-state supercapacitors obtained by ALD coating of high-density carbon nanotubes bundles
    Fiorentino, Giuseppe; Vollebregt, Sten; Tichelaar, FD; Ishihara, Ryoichi; Sarro, Pasqualina M;
    In Micro Electro Mechanical Systems (MEMS), 2014 IEEE 27th International Conference on,
    IEEE, pp. 342--345, 2014.

  67. CNT bundles growth on microhotplates for direct measurement of their thermal properties
    C. Silvestri; B. Morana; G. Fiorentino; S. Vollebregt; G. Pandraud; F. Santagata; GuoQi Zhang; P.M. Sarro;
    In 27th IEEE International Conference on Micro Electro Mechanical Systems (MEMS 2014),
    San Francisco, USA, Jan. 2014.
    document

  68. Carbon Nanotubes as Vertical Interconnects in 3D Integrated Circuits
    Sten Vollebregt;
    PhD thesis, Delft University of Technology, 2014.
    document

  69. Size-Dependent Effects on the Temperature Coefficient of Resistance of Carbon Nanotube Vias
    Vollebregt, Sten; Banerjee, Sourish; Beenakker, Kees; Ishihara, Ryoichi;
    Electron Devices, IEEE Transactions on,
    Volume 60, Issue 12, pp. 4085--4089, 2013.

  70. Thermal conductivity of low temperature grown vertical carbon nanotube bundles measured using the three-ω method.
    S. Vollebregt; S. Banerjee; C.I.M. Beenakker; R. Ishihara;
    Applied Physics Letters,
    Volume 102, Issue 19, pp. 1-4, 2013.

  71. Towards the integration of carbon nanotubes as vias in monolithic three-dimensional integrated circuits
    S. Vollebregt; Chiaramonti; AN; J. van der Cingel; C.I.M. Beenakker; R. Ishihara;
    Japanese Journal of Applied Physics. Part 1, Regular Papers Brief Communications & Review Papers,
    Volume 52, Issue 1-5, 2013.

  72. Integrating low temperature aligned carbon nanotubes as vertical interconnects in Si technology
    Sten Vollebregt; Ryoichi Ishihara; Jaber J. Derakhshandehohan van der Cingel; Hugo Schellevis; C.I.M. Beenakker;
    In Nanoelectronic Device Applications Handbook,
    Taylor and Francis, 2013.

  73. Carbon Nanotubes as Interconnects in Integrated Circuits
    Vollebregt, S; Ishihara, R; Beenakker, CIM;
    In Dekker Encyclopedia of Nanoscience and Nanotechnology, Second Edition,
    Taylor and Francis, 2013.

  74. Carbon nanotube vias fabricated at back-end of line compatible temperature using a novel CoAl catalyst
    S. Vollebregt; H. Schellevis; C.I.M. Beenakker; R. Ishihara;
    In S. Ogawa (Ed.), IEEE International Interconnect Technology Conference-technical papers,
    Kyoto, Japan, Jun. 2013.

  75. Carbon Nanotube based heat-sink for solid state lighting
    F. Santagata; G. Almanno; S. Vollebregt; C Silvestri; GuoQi Zhang; P.M. Sarro;
    In 8th IEEE Int. Conf. Nano/Micro Engineered and Molecular Systems (NEMS),
    pp. 1214-1217, Apr 2013. DOI 10.1109/NEMS.2013.6559937.

  76. Influence of the growth temperature on the first and second-order Raman band ratios and widths of carbon nanotubes and fibers
    S. Vollebregt; R. Ishihara; F.D. Tichelaar; Y. Hou; C.I.M. Beenakker;
    Carbon,
    Volume 50, Issue 10, pp. 3542-3554, Aug. 2012. DOI 10.1016/j.carbon.2012.03.026.

  77. Integrating carbon nanotubes as vias in a monolithic 3DIC process
    S. Vollebregt; R. Ishihara; A.N. Chiaramonti; J. van der Cingel; C.I.M. Beenakker;
    In Proc. International Conference on Solid State Devices and Materials (SSDM 2012),
    Kyoto, Japan, pp. 1170-1171, Sep 2012.

  78. Electrical characterization of carbon nanotube vertical interconnects with different lengths and widths
    S. Vollebregt; R. Ishihara; F.D. Tichelaar; J. van der Cingel; C.I.M. Beenakker;
    In IEEE International Interconnect Technology Conference (IITC 2012),
    San Jose, CA, USA, pp. 1-3, Jun. 2012. DOI 10.1109/IITC.2012.6251578.

  79. Low-temperature bottom-up integration of carbon nanotubes for vertical interconnects in monolithic 3D integrated circuits
    S. Vollebregt; R. Ishihara; J. van der Cingel; C.I.M. Beenakker;
    In 3rd IEEE International 3D Systems Integration Conference (3DIC 2011),
    Osaka, Japan, Jan. 2012. DOI 10.1109/3DIC.2012.6262989.

  80. Multilayer conformal coating of highly dense Multi-Walled Carbon Nanotubes bundles
    G. Fiorentino; S. Vollebregt; R. Ishihara; P.M. Sarro;
    In 2012 12th IEEE Conference on Nanotechnology (IEEE-NANO),
    Birmingham, UK, Aug. 2012. ISBN 978-1-4673-2198-3; DOI 10.1109/NANO.2012.6322054.

  81. Contact resistance of low-temperature carbon nanotube vertical interconnects
    S. Vollebregt; A.N. Chiaramonti; R. Ishihara; H. Schellevis; C.I.M. Beenakker;
    In K. Jiang (Ed.), 2012 12th IEEE Conference on Nanotechnology (IEEE-NANO),
    Birmingham, UK, Aug. 2012. ISBN 978-1-4673-2198-3; DOI 10.1109/NANO.2012.6321985.

  82. Electrical characterisation of low temperature aligned carbon nanotubes for vertical interconnects
    S. Vollebregt; R. Ishihara; J. van der Cingel; H. Schellevis; C.I.M. Beenakker;
    In Proc. ICT.OPEN: Micro technology and micro devices (SAFE 2011),
    Veldhoven, The Netherlands, Nov. 2011.

  83. Use of multi-wall carbon nanotubes as an absorber in a thermal detector
    H. Wu; S. Vollebregt; A. Emadi; G. de Graaf; R. R. IshiharaF. Wolffenbuttel;
    In C. Tsamis; G. Kaltas (Ed.), Proc. Eurosensors XXV,
    Athens, Greece, Procedia Engineering, pp. 523-526, Sep. 2011. DOI 10.1016/j.proeng.2011.12.130.

  84. Integrating low temperature aligned carbon nanotubes as vertical interconnects in Si technology
    S. Vollebregt; R. Ishihara; J. J. Derakhshandeh. van der Cingel; H. Schellevis; C.I.M. Beenakker;
    In Proc. 11th IEEE International Conference on Nanotechnology (NANO 2011),
    Portland, OR, pp. 985-990, Aug. 2011.

  85. Patterned aligned carbon nanotubes for vertical interconnects in 3D integrated TFT circuits
    S. Vollebregt; R. Ishihara; J. J. Derakhshandeh. van der Cingel; W.H.A. Wien; C.I.M. Beenakker;
    In 7th International Thin-Film Transistor Conference,
    Cambridge, United Kingdom, Mar. 2011.

  86. Growth of high density aligned carbon nanotubes using palladium as catalyst
    S. Vollebregt; J. Derakhshandeh; R. Ishihara; M. Y. Wu; C. I. M. Beenakker;
    Journal of Electronic Materials,
    Volume 39, Issue 4, pp. 371-375, 2010.

  87. Patterned growth of carbon nanotubes for vertical interconnect in 3D integrated circuits
    S. Vollebregt; R. Ishihara; J. Derakhshandeh; W. Wien; J. van der Cingel; C.E.M. Beenakker;
    In Proc. of SAFE 2010,
    pp. 184-187, 2010.

  88. Investigating Low Temperature High Density Aligned Carbon Nanotube and Nanofilament Growth using Palladium as Catalyst
    S. Vollebregt; J. Derakhshandeh; M.Y. Wu; R. Ishihara; C.I.M. Beenakker;
    In SAFE 2009,
    STW, pp. 125-128, 2009.

  89. Growth of high density aligned carbon nanotubes using palladium as catalyst
    S. Vollebregt; J. Derakhshandeh; R. Ishihara; C.I.M. Beenakker;
    In Proceedings of Electronic Material conference 2009,
    USA, 2009.

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