ESSL lab history and main achievements


The Epitaxy and Surface Science (ESSL) lab started its operation as a Molecular Beam Laboratory in year 2000 and has 20 years history of exploratory research on materials and devices for advanced CMOS and post CMOS nanoelectronics. Headed by Dr. A. Dimoulas, the lab raised around 7.5 million Euros from EU and national competitive projects, which allowed building new infrastructure worth of 1.5 million Euro or more and supporting a team of 8-9 members on average consisting of a senior scientist (Dr. A. Dimoulas), postdoctoral research associates and PhD students. Two of the postdoctoral research associates have received prestigious awards from the National Scholarships Foundation (ΙΚΥ) and the national HFRI (ΕΛΙΔΕΚ) to implement their research plans.

The research team has established:

  1. scientific excellence receiving two ERC grants (Advanced and Proof of Concept), as well as Marie Curie and FET grants.  Dr. Dimoulas has also received a Chair of Excellence appointment at CEA and the U. Grenoble Alpes for the development of MBE growth of 2D Materials and,
  2. leadership in European research by coordinating a number of large Industrial leadership (ICT) and Scientific Excellence (FET) European projects

The last ten years, the lab has become a unique facility in Greece for Surface Science encompassing a number of surface analytic techniques such as Scanning Tunneling Microscope (STM), Reflection High Energy Electron Diffraction (RHEED), X-ray and Ultraviolet Photoelectron Spectroscopy (XPS/UPS) and Angle Resolved Photoelectron Spectroscopy (ARPES), all integrated with the MBE chamber for in-situ characterization of the grown thin films. ARPES is the only such technique available in Greece and among the few existing in European labs and around the work (except from the large scale synchrotron facilities), which offers the capability to image the electronic band structure of crystalline solids. The lab is complemented by a CVD system equipped with a 4-inch cold wall chamber for the growth of graphene, a micromanipulator stage for electrical evaluation of devices in the range 4-475 K, a chemical hood for simple device processing and a high performance workstation for first principles calculations based on Density Functional Theory (DFT).

In brief, the main achievements of the lab and its contribution to the worldwide research are:

  1. Development of Germanium MOS technology for the scaling of advanced CMOS (widely cited), which is currently extending to the Ge MFS technology targeting Hf(Zr)O2-based scalable and Si-compatible  ferroelectric nonvolatile memories for IoT and neuromorphic computing
  2. First investigation in Europe of elemental 2D materials silicene and germanene (“cousins” of graphene) as well as the 2D graphitic AlN material (widely cited)
  3. Development of the MBE growth of 2D transition metal dichalchogenide materials, which is currently extended to the investigation of their non trivial topological properties (Weyl and Dirac semimetal properties).