Experience

MantiSpectra

• Netherlands
• Semiconductor Manufacturing
• 1 - 100 Employee

• Co-Founder & Chief Technology Officer (CTO)

  • Dec 2020 - Present

  Near-Infrared (NIR) Spectroscopy is based on the absorption of molecules in the near-infrared part of the electromagnetic spectrum. The core principle of our detector solution is simple: light is emitted by a light source such as a tungsten lamp and its spectrum is selectively absorbed by the molecules of a target object resulting in a ‘fingerprint’ of the material. The spectrum of the light that interacts with the object is resolved in real-time by our own integrated… Show more Near-Infrared (NIR) Spectroscopy is based on the absorption of molecules in the near-infrared part of the electromagnetic spectrum. The core principle of our detector solution is simple: light is emitted by a light source such as a tungsten lamp and its spectrum is selectively absorbed by the molecules of a target object resulting in a ‘fingerprint’ of the material. The spectrum of the light that interacts with the object is resolved in real-time by our own integrated multi-pixel spectrometer, a miniaturized, portable and cost-effective detector without the need of bulky, fragile and expensive setups. The detected spectrum is then process by our proprietary machine learning algorithm compared to a calibration set or a database so that the properties of the object can be quantified and/or the its material composition classified. A revolution in the market of real-time optical characterization Show less Near-Infrared (NIR) Spectroscopy is based on the absorption of molecules in the near-infrared part of the electromagnetic spectrum. The core principle of our detector solution is simple: light is emitted by a light source such as a tungsten lamp and its spectrum is selectively absorbed by the molecules of a target object resulting in a ‘fingerprint’ of the material. The spectrum of the light that interacts with the object is resolved in real-time by our own integrated… Show more Near-Infrared (NIR) Spectroscopy is based on the absorption of molecules in the near-infrared part of the electromagnetic spectrum. The core principle of our detector solution is simple: light is emitted by a light source such as a tungsten lamp and its spectrum is selectively absorbed by the molecules of a target object resulting in a ‘fingerprint’ of the material. The spectrum of the light that interacts with the object is resolved in real-time by our own integrated multi-pixel spectrometer, a miniaturized, portable and cost-effective detector without the need of bulky, fragile and expensive setups. The detected spectrum is then process by our proprietary machine learning algorithm compared to a calibration set or a database so that the properties of the object can be quantified and/or the its material composition classified. A revolution in the market of real-time optical characterization Show less



nanoPHAB

• Netherlands
• Semiconductor Manufacturing

• Co-Founder and Chief Executive Officer (CEO)

  • Jan 2016 - Present

  Photonics and nanotechnology are recognized as key enabling technologies (KETs) in view of their potential to drive crucial innovation for our present and future society. Moreover photonics is a major application market, growing very fast and with predicted multi-bilion market volume in the coming future. Nanotechnology is expected to bring breakthroughs in performance, power consumption and functionality, particularly in the fields of solar cells, lighting, sensing and optical… Show more Photonics and nanotechnology are recognized as key enabling technologies (KETs) in view of their potential to drive crucial innovation for our present and future society. Moreover photonics is a major application market, growing very fast and with predicted multi-bilion market volume in the coming future. Nanotechnology is expected to bring breakthroughs in performance, power consumption and functionality, particularly in the fields of solar cells, lighting, sensing and optical interconnects. Many of these applications will require the combination of nanofabrication technologies with different materials like dielectrics (SiN,SiOx,Polymers), metals (Au,Ni,Ge,Ag,Ti,Pt,Cr,Zn,...) and semiconductors including Silicon and especially III-V compounds like InP and GaAs (potentially integrated with silicon), unique materials with specific properties for light generation and detection. However, the development of new nanophotonics technologies and market applications will heavily depend on the availability of low-entry barrier fabrication solutions. Many SMEs and international research institutions aiming at the development and production of nanophotonic components are missing the necessary resources and expertise and face huge investment costs for setting up own nanofabrication facilities, preventing them from accessing this market. Show less Photonics and nanotechnology are recognized as key enabling technologies (KETs) in view of their potential to drive crucial innovation for our present and future society. Moreover photonics is a major application market, growing very fast and with predicted multi-bilion market volume in the coming future. Nanotechnology is expected to bring breakthroughs in performance, power consumption and functionality, particularly in the fields of solar cells, lighting, sensing and optical… Show more Photonics and nanotechnology are recognized as key enabling technologies (KETs) in view of their potential to drive crucial innovation for our present and future society. Moreover photonics is a major application market, growing very fast and with predicted multi-bilion market volume in the coming future. Nanotechnology is expected to bring breakthroughs in performance, power consumption and functionality, particularly in the fields of solar cells, lighting, sensing and optical interconnects. Many of these applications will require the combination of nanofabrication technologies with different materials like dielectrics (SiN,SiOx,Polymers), metals (Au,Ni,Ge,Ag,Ti,Pt,Cr,Zn,...) and semiconductors including Silicon and especially III-V compounds like InP and GaAs (potentially integrated with silicon), unique materials with specific properties for light generation and detection. However, the development of new nanophotonics technologies and market applications will heavily depend on the availability of low-entry barrier fabrication solutions. Many SMEs and international research institutions aiming at the development and production of nanophotonic components are missing the necessary resources and expertise and face huge investment costs for setting up own nanofabrication facilities, preventing them from accessing this market. Show less



Eindhoven University of Technology

• Netherlands
• Research Services
• 700 & Above Employee

• Researcher

  • Nov 2014 - Present

  -Design and Simulation of Photonic devices -Fabrication of micro and nano-devices for classic and quantum photonics in III-V, silicon, dielectrics -Electro-optical Characterization (RF, mPL, time-resolved spectrometry, cryogenic quantum measurments) -Valorization of business related photonics innovation, services and products -Design and Simulation of Photonic devices -Fabrication of micro and nano-devices for classic and quantum photonics in III-V, silicon, dielectrics -Electro-optical Characterization (RF, mPL, time-resolved spectrometry, cryogenic quantum measurments) -Valorization of business related photonics innovation, services and products



Eindhoven University of Technology

• Netherlands
• Research Services
• 700 & Above Employee

• PHD Student

  • Oct 2009 - Jul 2014