State research institute Center for Physical Sciences and Technology , Lithuania
Lithuania
My team at the Centre for Physical Sciences and Technology (FTMC) in Vilnius, Lithuania, specialises in device physics and optoelectronic characterisation.
My team at the Center for Physical Sciences and Technology (FTMC) in Vilnius, Lithuania, specializes in device physics, optoelectronic characterization techniques, computational physics, and organic molecule synthesis. We actively seek collaboration with both academic institutions and technological companies.
With nine years of expertise in organic electronics and perovskite device fabrication, synthesis, optoelectronic, and crystallographic characterizations, I am currently researching perovskite LEDs at FTMC. My work focuses on enhancing carrier transport, reducing light outcoupling, and improving external quantum efficiency (EQE) by mitigating ionic transport and advancing interfacial engineering.
Our institute is equipped with a diverse range of optoelectronic and crystallographic analytical techniques, including time-resolved photoluminescence (TRPL), streak camera imaging, coherent anti-Stokes Raman spectroscopy (CARS), pump-probe setups, and second-harmonic generation fluorescence microscopy—providing comprehensive insights into thin films and device performance.
Starting this year, we aim to collaborate on research projects related to thin-film organic/inorganic solar cells, LEDs, and thin-film transistors (TFTs). Our coordinator has contributed significant advancements in perovskite solar cell technology, achieving a maximum power conversion efficiency of 21% in single-junction perovskite solar cells. Additionally, our team has produced high-impact publications on perovskite stability designs, incorporating ISOS and IEC test standards.
We look forward to engaging in fruitful collaborations.
Working in the solid state/semiconductor field since 2016.
My first experience with perovskite thin film electronics started at IMEC, Belgium, and have since then intensively worked with thin-film electronics involving TFTS, exploring all inorganic and organic polymers materials and studying defect states and contact resistance issues at Holst Centre where I was an early stage researcher affiliated to TU/Eindhoven.
I recently worked on perovskite electronics on the topic of highly stable and reliable solar perovskite technologies at Saule Research Institute, where I completed my doctors with affiliation to Poznan Technical University.
I am interested in nanofabrication/lithography, thin film deposition, Perovskite solar cells, organic solar cells, fuel cells, inorganic/organic transistors and Perovskite-based LEDs
My organisation
State research institute Center for Physical Sciences and Technology , Lithuania
My team at the Center for Physical Sciences and Technology (FTMC) in Vilnius, Lithuania, specializes in device physics, optoelectronic characterization techniques, computational physics, and organic molecule synthesis. We actively seek collaboration with both academic institutions and technological companies.
With nine years of expertise in organic electronics and perovskite device fabrication, synthesis, optoelectronic, and crystallographic characterizations, I am currently researching perovskite LEDs at FTMC. My work focuses on enhancing carrier transport, reducing light outcoupling, and improving external quantum efficiency (EQE) by mitigating ionic transport and advancing interfacial engineering.
Our institute is equipped with a diverse range of optoelectronic and crystallographic analytical techniques, including time-resolved photoluminescence (TRPL), streak camera imaging, coherent anti-Stokes Raman spectroscopy (CARS), pump-probe setups, and second-harmonic generation fluorescence microscopy—providing comprehensive insights into thin films and device performance.
Starting this year, we aim to collaborate on research projects related to thin-film organic/inorganic solar cells, LEDs, and thin-film transistors (TFTs). Our coordinator has contributed significant advancements in perovskite solar cell technology, achieving a maximum power conversion efficiency of 21% in single-junction perovskite solar cells. Additionally, our team has produced high-impact publications on perovskite stability designs, incorporating ISOS and IEC test standards.
We look forward to engaging in fruitful collaborations.
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I am interested in the following CETPartnership thematic areas:
develop the optimised, integrated European net-zero emissions energy systemprovide technological cleaner solutions for storage technologiesprovide technological cleaner solutions for hydrogen and renewable fuels