ARTEMIS

ARTEMISAdvanced Renewable Technologies for Energy & Materials Integrated Systems

ARTEMISAdvanced Renewable Technologies for Energy & Materials Integrated Systems

Mission

The mission of the Laboratory of Advanced Renewable Technologies & Environmental Materials in Integrated Systems (ARTEMIS), established in November 2022, is to conduct cutting-edge basic and applied sustainable research with emphasis on solar heat, novel hydrogen fuels, as well as innovative materials, with a special focus on ceramics. The aim is to achieve optimum integration in the context of the green transformation of industrial applications and address the relevant social challenges and priorities of the national and European research and technology policy.

Scientific objectives

The core scientific objectives of the ARTEMIS Laboratory include:

  • Materials and subsystems for production of energy carriers from solar-thermal/thermochemical processes
  • Hydrogen technologies
  • Combustion processes and emission control technologies
  • Simulation of physical, chemical, biological and biochemical processes with the use of innovative computational engineering methods.
  • Aerosol technologies and methods of exposure/assessment of the impact of particles’ dispersion in biological systems.

The ARTEMIS Laboratory treats areas that are clearly related to the Sectors “Clean Energy”, “Environment” and “Sustainable Industry” while its emerging activities cover very specific sub-areas that can be considered to be part of the “Biosciences” Sector.

History

The ARTEMIS Laboratory is the result of a restructuring decision made by the Board of Directors of the Centre for Research & Technology Hellas (CERTH) aiming to unify and strengthen the activities of the Chemical Processes & Energy Resources Institute (CPERI) on relevant scientific areas and align with the specific GSRI recommendations as came up after CPERI’s latest (2022) evaluation.

Based on that decision, the former Aerosol and Particle Technology Laboratory (APTL) joined forces with 3 other Research Groups of CPERI to form the newest, to date, laboratory of CPERI/CERTH.

Projects & Activities

ARTEMIS

SolarHub

/GA 101086110 

ARTEMIS

HySelect

/GA 101101498 

ARTEMIS

ABraytCSPfuture

/GA 101084569 

ARTEMIS

En3DSyst

/MIS 5136520 

ARTEMIS

Minefield

/MIS 5136543 

ARTEMIS

VessOil

/MIS 5136489 

Personnel

ARTEMIS

Anagnostara Ioanna-Marina

Scientific Personnel
, Chemical Engineer
ARTEMIS

Asimakopoulou Akrivi

Collaborating Researcher PhD
, Chemical Engineer, PhD
ARTEMIS

Bakratsa Alexandra

Technical Staff
, Technician
ARTEMIS

Baltsavia Ismene

Scientific Personnel
, Biologist, MSc
ARTEMIS

Baltzopoulou Penelope

Scientific Personnel
, Chemical Engineer, MSc
ARTEMIS

Bampaou Michael

PhD Candidate
, Chemical Engineer
ARTEMIS

Chasapidis Leonidas

Scientific Personnel
, Mechanical Engineer, MSc
ARTEMIS

Chrysikopoulou Marina

Scientific Personnel
, Chemical Engineer, MSc
ARTEMIS

Daskalos Emmanuel

Scientific Personnel
, Materials Engineer, MSc
ARTEMIS

Deloglou Daniel

Scientific Personnel
, Chemical Engineer
ARTEMIS

Dimopoulos Toursidis Panagiotis

Scientific Personnel
, Chemist
ARTEMIS

Fotiadis Kyriakos

Scientific Personnel
, Mechanical Engineer
ARTEMIS

Galatsopoulos Charalampos

Scientific Personnel
, Automation Engineer
ARTEMIS

Garagounis Ioannis

Scientific Personnel
, Chemical Engineer
ARTEMIS

Kafetzis Alexandros

PhD Candidate
, Mechanical Engineer
ARTEMIS

Karagiannakis George

Member of SC, Researcher
, Principal Researcher
, Chemical Engineer, PhD
ARTEMIS

Karani Maria

Scientific Personnel
, MSc, Physicist
ARTEMIS

Karantonis Demetrios

Technical Staff
, Technician
ARTEMIS

Kardaras George

Scientific Personnel
, Environmental Engineer
ARTEMIS

Kazangas Demetrios

Scientific Personnel
, Naval Architect & Marine Engineer

Publications

Pantoleontos G., Anagnostara I., Syrigou M., Konstandopoulos A. 

Solutions of the mass continuity equation in hollow fibers for fully developed flow with some notes on the Lévêque correlation

2022

Carbon Capture Science & Technology, 2022, 2

Grekou T., Koutsonikolas D., Karagiannakis G., Kikkinides E.

Tailor-Made Modification of Commercial Ceramic Membranes for Environmental and Energy-Oriented Gas Separation Applications

2022

Membranes 2022, 12(3), 307

Nikolakopoulos T., Steriotis G., Charalambopoulou G., Karagiannakis G., Dimitrakis D., Konstandopoulos A., Michalis V., Katsiotis M.

Solar-aided calcination of limestone: First modeling of the SOLCEMENT process

2022

AIP Conference Proceedings 2445, 130007

Damartzis T., Asimakopoulou A., Koutsonikolas D., Skevis G., Georgopoulou C., Dimopoulos G., Nikolopoulos L., Bougiouris K., Richter H., Lubenau U.

Solvents for Membrane-Based Post-Combustion CO2 Capture for Potential Application in the Marine Environment

2022

Appl. Sci. 2022, 12, 6100

Tsimpanogiannis I., Stamatakis E., Stubos A. 

Study of the Critical Pore Radius that Results in Critical Gas Saturation during Methane Hydrate Dissociation at the Single–Pore Scale: Analytical Solution for Small Pores and Potential Implications to Methane Production from Geological Media

2022

Energies, 2022, 15, 210

Bampaou M., Panopoulos K., Seferlis P., Voutetakis S. 

Evaluation of novel hydrogen integration options in bio-oils introduction to petrochemical refineries

2022

Energy, 254, art. no. 124353

Mohr S., Pétuya R., Sarria J., Purkayastha N., Bodnar S., Wylde J., Tsimpanogiannis I.

Assessing the Effect of a Liquid Water Layer on the Adsorption of Hydrate Anti-Agglomerants using Molecular Simulations

2022

J. Chem. Phys., 2022, 157, 094703

Zoladek M., Kafetzis A., Figaj R., Panopoulos K. 

Energy-Economic Assessment of Islanded microgrid with wind turbine, photovoltaic field, wood gasifier, battery, and hydrogen energy

2022

Sustainability, 14, 19, 12470

Tsimpanogiannis I., Stamatakis E., Stubos A. 

Study of the Critical Pore Radius that Results in Critical Gas Saturation during Methane Hydrate Dissociation at the Single–Pore Scale: Analytical Solution for Small Pores and Potential Implications to Methane Production from Geological Media

2022

Energies, 2022, 15, 210

Bampaou M., Panopoulos K., Seferlis P., Voutetakis S. 

Evaluation of novel hydrogen integration options in bio-oils introduction to petrochemical refineries

2022

Energy, 254, art. no. 124353

Mohr S., Pétuya R., Sarria J., Purkayastha N., Bodnar S., Wylde J., Tsimpanogiannis I.

Assessing the Effect of a Liquid Water Layer on the Adsorption of Hydrate Anti-Agglomerants using Molecular Simulations

2022

J. Chem. Phys., 2022, 157, 094703

Zoladek M., Kafetzis A., Figaj R., Panopoulos K. 

Energy-Economic Assessment of Islanded microgrid with wind turbine, photovoltaic field, wood gasifier, battery, and hydrogen energy

2022

Sustainability, 14, 19, 12470

Tsimpanogiannis I., Moultos O.

Is Stokes-Einstein Relation Valid for the Description of Intra-Diffusivity of Hydrogen and Oxygen in Liquid Water?

2022

Fluid Phase Equilib., 2022, 563, 113568

Bampaou M., Panopoulos K., Seferlis P., Sasiain A., Haag S., Wolf-zoellner P., Lehner M., Rog L., Rompalski P., Kolb S., Kieberger N., Dettori S., Matino I., Colla V. 

Economic Evaluation of Renewable Hydrogen Integration into Steelworks for the Production of Methanol and Methane

2022

Energies, 15 (13), 4650

Michalis V., Economou I., Stubos A., Tsimpanogiannis I.

Phase Equilibria Molecular Simulations of Hydrogen Hydrates via the Direct Phase Coexistence Approach

2022

J. Chem. Phys., 2022, 157, 154501

Hauser A., Wolf-Zoellner P., Haag, S., Dettori S., Tang X., Mighani M., Matino I., Mocci C., Colla V., Kolb S., Bampaou M., Panopoulos K., Kieberger N., Rechberger K., Karl J. 

Valorizing Steelworks Gases by Coupling Novel Methane and Methanol Synthesis Reactors with an Economic Hybrid Model Predictive Controller

2022

Metals, 12 (6), 1023

Charitopoulou M., Stefanidis S., Lappas A., Achilias D.

Catalytic pyrolysis of polymers with brominated flame-retardants originating in waste electric and electronic equipment (WEEE) using various catalysts

2022

Sustain Chem Pharm. 26, pp. 100612

Osatiashtiani A., Zhang J., Stefanidis S., Zhang X., Bridgwater A.

The mechanism for catalytic fast pyrolysis of levoglucosan, furfural and furan over HZSM-5: An experimental and theoretical investigation

2022

Fuel. 328 pp. 125279

MINOAN – Smart Sustainable
Energy Conversion and Management

GREEN – Geo-Resources, Energy
& Environmental Management

GrEnEA – Green Energy
& Environmental Applications

LIM – Laboratory
of Inorganic Materials

ARTEMIS – Advanced Renewable
Technologies for Energy & Materials
Integrated Systems

NRRE – Natural Resources
& Renewable Energies

PSDI – Laboratory of Process
Systems Design and Implementation

LPRE – Laboratory of Polymer
Reaction Engineering

NICE – Novel materIals
for Clean Energy Applications

LEFH – Laboratory of Environmental
Fuels/Biofuels and Hydrocarbons

HydPro – Hydroprocessing

BCPL – Biological Computation
& Process Laboratory

LEET – Laboratory of Environmental & Energy Transition technologies
(GrEnEA, Green & Minoan Groups)