ΜEMBERS - RESEARCH ACTIVITIES

Yiannis Deligiannakis
  • Α.1 Structure-property relationships
  • Α.3 Study of thermal properties.
  • Α.4 Study and characterization of optical properties.
  • A.5 Properties of surfaces and interfaces.
  • A.6 Study of physical, chemical processes and physicochemical mechanisms of new materials.
  • Β.1 Power generation and storage (flexible electronics - photovoltaics, hybrid organic - inorganic photovoltaics, batteries, fuel cells, catalytic fuel production, photocatalysts, artificial photosynthesis of H2, O2, CO2 ).
  • Β.2 Bio-energy (energy recovery from organic waste and biomass).
  • Β.3 Development of catalytic materials and sensors.
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
  • Β.7 Smart / functional materials (shape memory alloys, self-healing materials, thermoelectric, ferroelectric, piezoelectric, electro-rheological / magneto-rheological, micro-electromechanical, responsive to chemical stimuli, etc.).
  • Β.9 Hybrid materials (organic/inorganic).
  • Β.11 Magnetic materials.
  • Β.12 Semiconductive nanomaterials and molecular materials with electronic, optoelectronic, optoelectronic and photonic functionalities.
  • Β.13 Plasmonic, photonic, phononic and meta-materials.
  • Β.17 Production of materials with scale methods.
Alexios P. Douvalis
  • Α.1 Structure-property relationships
  • A.5 Properties of surfaces and interfaces.
  • A.6 Study of physical, chemical processes and physicochemical mechanisms of new materials.
  • Β.1 Power generation and storage (flexible electronics - photovoltaics, hybrid organic - inorganic photovoltaics, batteries, fuel cells, catalytic fuel production, photocatalysts, artificial photosynthesis of H2, O2, CO2 ).
  • Β.3 Development of catalytic materials and sensors.
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
  • Β.7 Smart / functional materials (shape memory alloys, self-healing materials, thermoelectric, ferroelectric, piezoelectric, electro-rheological / magneto-rheological, micro-electromechanical, responsive to chemical stimuli, etc.).
  • Β.9 Hybrid materials (organic/inorganic).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.11 Magnetic materials.
  • Β.12 Semiconductive nanomaterials and molecular materials with electronic, optoelectronic, optoelectronic and photonic functionalities.
  • Β.13 Plasmonic, photonic, phononic and meta-materials.
  • Β.15 Composite and construction materials.
George Evangelakis
  • Α.1 Structure-property relationships
  • Α.3 Study of thermal properties.
  • A.5 Properties of surfaces and interfaces.
  • Β.1 Power generation and storage (flexible electronics - photovoltaics, hybrid organic - inorganic photovoltaics, batteries, fuel cells, catalytic fuel production, photocatalysts, artificial photosynthesis of H2, O2, CO2 ).
  • Β.3 Development of catalytic materials and sensors.
  • Β.4 Study of mechanical properties (machining, welding, durability, degradation of materials) of metals, ceramics, polymers, composites and advanced materials.
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.13 Plasmonic, photonic, phononic and meta-materials.
  • C.1 Theory, optimization and simulation of materials on multiple scales (computations from first principles, atomistic, molecular, mesoscopic simulation as well as continuum computational methods). Design and optimization of functional devices.
Evangelos K. Evangelou
  • Α.2 Development of electrical devices and study of electronic properties.
  • Α.4 Study and characterization of optical properties.
  • A.5 Properties of surfaces and interfaces.
  • Β.1 Power generation and storage (flexible electronics - photovoltaics, hybrid organic - inorganic photovoltaics, batteries, fuel cells, catalytic fuel production, photocatalysts, artificial photosynthesis of H2, O2, CO2 ).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.11 Magnetic materials.
George Floudas
  • Α.1 Structure-property relationships
  • Α.3 Study of thermal properties.
  • A.5 Properties of surfaces and interfaces.
  • Β.1 Power generation and storage (flexible electronics - photovoltaics, hybrid organic - inorganic photovoltaics, batteries, fuel cells, catalytic fuel production, photocatalysts, artificial photosynthesis of H2, O2, CO2 ).
  • Β.4 Study of mechanical properties (machining, welding, durability, degradation of materials) of metals, ceramics, polymers, composites and advanced materials.
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
  • Β.8 Soft matter (polymers, colloids, liquid crystals, etc.).
  • Β.9 Hybrid materials (organic/inorganic).
Demosthenes Fokas
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
Achilleas Garoufis
  • Α.1 Structure-property relationships
  • Β.1 Power generation and storage (flexible electronics - photovoltaics, hybrid organic - inorganic photovoltaics, batteries, fuel cells, catalytic fuel production, photocatalysts, artificial photosynthesis of H2, O2, CO2 ).
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
Leonidas N. Gergidis
  • Α.1 Structure-property relationships
  • Α.2 Development of electrical devices and study of electronic properties.
  • Α.3 Study of thermal properties.
  • A.6 Study of physical, chemical processes and physicochemical mechanisms of new materials.
  • Β.3 Development of catalytic materials and sensors.
  • Β.4 Study of mechanical properties (machining, welding, durability, degradation of materials) of metals, ceramics, polymers, composites and advanced materials.
  • Β.5 Development of non-destructive control and signal processing techniques.
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
  • Β.7 Smart / functional materials (shape memory alloys, self-healing materials, thermoelectric, ferroelectric, piezoelectric, electro-rheological / magneto-rheological, micro-electromechanical, responsive to chemical stimuli, etc.).
  • Β.8 Soft matter (polymers, colloids, liquid crystals, etc.).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.11 Magnetic materials.
  • Β.15 Composite and construction materials.
  • C.1 Theory, optimization and simulation of materials on multiple scales (computations from first principles, atomistic, molecular, mesoscopic simulation as well as continuum computational methods). Design and optimization of functional devices.
Dimosthenis L. Giokas
  • Α.7 Development of sensors and biosensors.
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.11 Magnetic materials.
Dimitrios Gournis
  • A.5 Properties of surfaces and interfaces.
  • A.6 Study of physical, chemical processes and physicochemical mechanisms of new materials.
  • Α.7 Development of sensors and biosensors.
  • Β.1 Power generation and storage (flexible electronics - photovoltaics, hybrid organic - inorganic photovoltaics, batteries, fuel cells, catalytic fuel production, photocatalysts, artificial photosynthesis of H2, O2, CO2 ).
  • Β.3 Development of catalytic materials and sensors.
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
  • Β.9 Hybrid materials (organic/inorganic).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.12 Semiconductive nanomaterials and molecular materials with electronic, optoelectronic, optoelectronic and photonic functionalities.
Sotiris K. Hadjikakou
  • Α.1 Structure-property relationships
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
  • Β.8 Soft matter (polymers, colloids, liquid crystals, etc.).
  • Β.9 Hybrid materials (organic/inorganic).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
Angelos G. Kalampounias
  • Α.1 Structure-property relationships
  • Α.3 Study of thermal properties.
  • A.5 Properties of surfaces and interfaces.
  • A.6 Study of physical, chemical processes and physicochemical mechanisms of new materials.
  • Β.5 Development of non-destructive control and signal processing techniques.
  • Β.8 Soft matter (polymers, colloids, liquid crystals, etc.).
  • C.1 Theory, optimization and simulation of materials on multiple scales (computations from first principles, atomistic, molecular, mesoscopic simulation as well as continuum computational methods). Design and optimization of functional devices.
Michael A. Karakassides
  • Α.1 Structure-property relationships
  • Α.3 Study of thermal properties.
  • Β.3 Development of catalytic materials and sensors.
  • Β.9 Hybrid materials (organic/inorganic).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.15 Composite and construction materials.
  • Β.17 Production of materials with scale methods.
Angeliki G. Lekatou
  • A.5 Properties of surfaces and interfaces.
  • A.6 Study of physical, chemical processes and physicochemical mechanisms of new materials.
  • Β.4 Study of mechanical properties (machining, welding, durability, degradation of materials) of metals, ceramics, polymers, composites and advanced materials.
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.15 Composite and construction materials.
Christina Lekka
  • Α.1 Structure-property relationships
  • Α.2 Development of electrical devices and study of electronic properties.
  • A.5 Properties of surfaces and interfaces.
  • Β.4 Study of mechanical properties (machining, welding, durability, degradation of materials) of metals, ceramics, polymers, composites and advanced materials.
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
  • Β.9 Hybrid materials (organic/inorganic).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.11 Magnetic materials.
  • Β.12 Semiconductive nanomaterials and molecular materials with electronic, optoelectronic, optoelectronic and photonic functionalities.
  • C.1 Theory, optimization and simulation of materials on multiple scales (computations from first principles, atomistic, molecular, mesoscopic simulation as well as continuum computational methods). Design and optimization of functional devices.
Elefterios Lidorikis
  • Β.1 Power generation and storage (flexible electronics - photovoltaics, hybrid organic - inorganic photovoltaics, batteries, fuel cells, catalytic fuel production, photocatalysts, artificial photosynthesis of H2, O2, CO2 ).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.11 Magnetic materials.
  • Β.13 Plasmonic, photonic, phononic and meta-materials.
  • C.1 Theory, optimization and simulation of materials on multiple scales (computations from first principles, atomistic, molecular, mesoscopic simulation as well as continuum computational methods). Design and optimization of functional devices.
Maria Louloudi
  • Α.1 Structure-property relationships
  • A.5 Properties of surfaces and interfaces.
  • A.6 Study of physical, chemical processes and physicochemical mechanisms of new materials.
  • Β.1 Power generation and storage (flexible electronics - photovoltaics, hybrid organic - inorganic photovoltaics, batteries, fuel cells, catalytic fuel production, photocatalysts, artificial photosynthesis of H2, O2, CO2 ).
  • Β.2 Bio-energy (energy recovery from organic waste and biomass).
  • Β.3 Development of catalytic materials and sensors.
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
  • Β.7 Smart / functional materials (shape memory alloys, self-healing materials, thermoelectric, ferroelectric, piezoelectric, electro-rheological / magneto-rheological, micro-electromechanical, responsive to chemical stimuli, etc.).
  • Β.9 Hybrid materials (organic/inorganic).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.15 Composite and construction materials.
Emmanouil (Manolis) J. Manos
  • Α.1 Structure-property relationships
  • Β.3 Development of catalytic materials and sensors.
  • Β.9 Hybrid materials (organic/inorganic).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.11 Magnetic materials.
  • Β.15 Composite and construction materials.
Alkiviadis S. Paipetis
  • Α.1 Structure-property relationships
  • Α.2 Development of electrical devices and study of electronic properties.
  • A.5 Properties of surfaces and interfaces.
  • Α.7 Development of sensors and biosensors.
  • Β.1 Power generation and storage (flexible electronics - photovoltaics, hybrid organic - inorganic photovoltaics, batteries, fuel cells, catalytic fuel production, photocatalysts, artificial photosynthesis of H2, O2, CO2 ).
  • Β.4 Study of mechanical properties (machining, welding, durability, degradation of materials) of metals, ceramics, polymers, composites and advanced materials.
  • Β.5 Development of non-destructive control and signal processing techniques.
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
  • Β.7 Smart / functional materials (shape memory alloys, self-healing materials, thermoelectric, ferroelectric, piezoelectric, electro-rheological / magneto-rheological, micro-electromechanical, responsive to chemical stimuli, etc.).
  • Β.9 Hybrid materials (organic/inorganic).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.12 Semiconductive nanomaterials and molecular materials with electronic, optoelectronic, optoelectronic and photonic functionalities.
  • Β.14 Development of model devices.
  • Β.15 Composite and construction materials.
  • Β.16 Control of operation of materials and devices
Ioannis Panagiotopoulos
  • Α.2 Development of electrical devices and study of electronic properties.
  • Β.11 Magnetic materials.
  • Β.12 Semiconductive nanomaterials and molecular materials with electronic, optoelectronic, optoelectronic and photonic functionalities.
  • C.1 Theory, optimization and simulation of materials on multiple scales (computations from first principles, atomistic, molecular, mesoscopic simulation as well as continuum computational methods). Design and optimization of functional devices.
Periklis Papadopoulos
  • Α.1 Structure-property relationships
  • A.5 Properties of surfaces and interfaces.
  • A.6 Study of physical, chemical processes and physicochemical mechanisms of new materials.
  • Β.8 Soft matter (polymers, colloids, liquid crystals, etc.).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • C.1 Theory, optimization and simulation of materials on multiple scales (computations from first principles, atomistic, molecular, mesoscopic simulation as well as continuum computational methods). Design and optimization of functional devices.
George Z. Papageorgiou
  • Α.1 Structure-property relationships
  • Α.3 Study of thermal properties.
  • A.6 Study of physical, chemical processes and physicochemical mechanisms of new materials.
  • Β.2 Bio-energy (energy recovery from organic waste and biomass).
  • Β.4 Study of mechanical properties (machining, welding, durability, degradation of materials) of metals, ceramics, polymers, composites and advanced materials.
  • Β.7 Smart / functional materials (shape memory alloys, self-healing materials, thermoelectric, ferroelectric, piezoelectric, electro-rheological / magneto-rheological, micro-electromechanical, responsive to chemical stimuli, etc.).
John C. Plakatouras
  • Α.1 Structure-property relationships
  • Α.3 Study of thermal properties.
  • Α.4 Study and characterization of optical properties.
  • Β.3 Development of catalytic materials and sensors.
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
  • Β.7 Smart / functional materials (shape memory alloys, self-healing materials, thermoelectric, ferroelectric, piezoelectric, electro-rheological / magneto-rheological, micro-electromechanical, responsive to chemical stimuli, etc.).
  • Β.8 Soft matter (polymers, colloids, liquid crystals, etc.).
  • Β.9 Hybrid materials (organic/inorganic).
  • Β.11 Magnetic materials.
Mamas Prodromidis
  • Α.7 Development of sensors and biosensors.
  • Β.3 Development of catalytic materials and sensors.
  • Β.7 Smart / functional materials (shape memory alloys, self-healing materials, thermoelectric, ferroelectric, piezoelectric, electro-rheological / magneto-rheological, micro-electromechanical, responsive to chemical stimuli, etc.).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
Dimitrios Tasis
  • A.6 Study of physical, chemical processes and physicochemical mechanisms of new materials.
  • Β.3 Development of catalytic materials and sensors.
  • Β.9 Hybrid materials (organic/inorganic).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
Alexandros D. Tselepis
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
Andreas Tzakos
  • Α.1 Structure-property relationships
  • Α.7 Development of sensors and biosensors.
  • Β.6 Biomaterials (biologically inspired, biomimetic, biomedical, implants, drug delivery, biological tissues, biomechanics, etc.).
  • Β.7 Smart / functional materials (shape memory alloys, self-healing materials, thermoelectric, ferroelectric, piezoelectric, electro-rheological / magneto-rheological, micro-electromechanical, responsive to chemical stimuli, etc.).
  • Β.9 Hybrid materials (organic/inorganic).
  • Β.10 Nanomaterials (nano-carbons, low dimensional, nanocomposites).
  • Β.13 Plasmonic, photonic, phononic and meta-materials.