Projects at a Glance
ENSEMBLES3 - Centre of ExcelleNce for nanophotonicS, advancEd Materials and novel crystal growth-Based technoLogiEs
Within the project an extensive, detailed and robust Business Plan will be developed for setting-up of the Centre of Excellence ENSEMBLE3, with focus on the research excellence and innovation performance in the area of crystal growth-based technologies, novel functional materials with innovative electromagnetic properties, and applications in nanophotonics, optoelectronics, telecommunication, medicine, and photovoltaics.
DELICE- Device oriented molecular spin filter based interfaces
We live in a constantly changing society in which information and communication are at the basis of our economy. To keep progressing is essential to investigate new feasible ways to control and manipulate information in order to develop faster, smaller and less consuming devices. Organic Spintronics has emerged as a promising field to develop low-cost, mechanically-flexible and multi-functional devices in which information is carried not only by the charge but also by the spin of electrons.ALD4MAX- Atomic Layer deposition For tailored bottom-top growth of MAX and MXene films
Atomic Layer Deposition For tailored bottom-top growth of MAX and MXene films.FEMTOTERABYTE - Spinoptical nanoantenna-assisted magnetic storage at few nanometers on femtosecond timescale
We will develop the conceptually new paradigm for ultra-dense and ultrafast magnetic storage that will exceed the current technology by two orders of magnitude in storage density (going from terabit/inch2 to tens of terabytes/inch2) and by about four orders of magnitude in operation speed (going from low GHz to THz for read/write).FAST TestOM- FAST and accurate Testing of Organic Materials
Organic electronic devices are currently ubiquitous. For example, most mobile phones in the market have screens based on organic light-emitting diodes. These devices have many advantages against their inorganic counterparts, as they have for example lower manufacturing costs, they are typically very light and robust and can built into flexible devices, bendable and foldable.SPM2.0- Scanning probe microscopies for nanoscale fast, tomographic and composition imaging
Advanced Microscopy are widely recognized as one of the pillars onto which the research and manufacture of Nanotechnology based products is sustained. At present, the greatest challenge faced by these techniques is the realization of fast and non-destructive tomographic images with chemical composition sensitivity and with sub-10 nm spatial resolution, in both organic and inorganic materials, and in all environmental conditions.SGPCM- Switching grapheme-plasmon with phase-change materials
Graphene plasmons (GPs), is enable the transport and control of light on an extreme subwavelength scale as well as the dynamic tunability via electric-gate voltage, which can be exploited for numerous applications such as for strong light-matter interactions, tunable infrared biosensing and absorption spectroscopy, subwavelength optical imaging, as well as for the development of tunable transformation optics devices, metamaterials and metasurfaces.
SGPCM - Switching graphene-plasmon with phase-change materials
Graphene plasmons (GPs) enable the transport and control of light on an extreme subwavelength scale as well as the dynamic tunability via electric-gate voltage, which can be exploited for numerous applications such as for strong light-matter interactions, tunable infrared biosensing and absorption spectroscopy, subwavelength optical imaging, as well as for the development of tunable transformation optics devices, metamaterials and metasurfaces.
By funding program
Kontaktua
Yurdana Castelruiz
Projects Manager
+ 34 943574022
y.castelruiz[at]nanogune.eu