Laser Nanophotonics Group

Sukurta: 10 sausio 2019
Keywords: ultrafast laser 3D nanolithography, multiphoton processing, nanophotonics, microoptics, biomedicine, biomaterials, light-matter interaction, optical 3D printing, 4D printing

The group’s main research topic is direct laser writing (DLW) of 3D micro-nano-structures in transparent media and the applications of such functional structures in microoptics, photonics and tissue engineering.

 

Research group activities

  • Mechanisms of ultrafast laser 3D nano-processing of organic, inorganic and hybrid materials;
  • Optical 3D μ-printing of functional prototypes;
  • Creation and characterization of novel nanophotonic, microoptic, biomedical, microfluidic, and other integrated devices;
  • Hybridization of meso-scale and multi-material laser processing technologies (from nano- to macro-architectures, additive with subtractive, monolith structures of composite materials);
  • Characterization of optical, photonic, and chemical properties of 3D printed micro-objects.

 

Proposal

Long term or project based collaboration with academia and industry towards development of ultrafast direct laser writing (DLW) process and its application for creation of novel 3D micro-/nano-architectured functional devices.

Feasibility studies or small scale batch production are available via open access facility “NAGLIS”.

 

Meet our team

Leading researcher:

Dr. Mangirdas Malinauskas, h-index – 29.

Staff:

Dr. Martynas Peckus

Dr. Sima Rekštytė

Dr. Vytautas Purlys

Mr. Arūnas Čiburys

PhD students:

Darius Gailevičius

Titas Tičkūnas

Linas Jonušauskas

Simonas Varapnickas

G. Kontenis,

D. Mackevičiūtė(industrial withFemtika Ltd.),

E. Skliutas.

 

Research outcomes

5 book Chapters, 4 review papers, > 150 research papers, > 2300 citations.

  • M. Malinauskas et al., Ultrafast laser processing of materials: from science to industry, Light: Sci. Appl. 5, e16133 (2016). [a hot paper in CA-WOS list]
  • S. Rekstyte et al., Nanoscale Precision of 3D Polymerization via Polarization Control, Adv. Opt. Mater. 4(8), 1209-1214 (2016).
  • J. Maciulaitis et al., Preclinical study of SZ2080 material 3D microstructured scaffolds for cartilage tissue engineering made by femtosecond direct laser writing lithography, Biofabrication 7, 015015 (2015).
  • L. Maigyte et al., Flat lensing in visible frequency range by woodpile photonic crystals, Opt. Lett. 38(14), 2376-2378 (2013).
  • T. Tickunas et al., Combination of additive and subtractive laser 3D microprocessing in hybrid glass/polymer microsystems for chemical sensing applications, Opt. Express 25(21), 26280 (2017).

International scientific collaboration:

Swinburne University of Technology (Prof. S. Juodkazis), Universitat Politècnica de Catalunya (Prof. K. Staliunas), Foundation for Research and Technology - Hellas (Dr. Maria Farsari), University of Bordeaux (Dr. Etienne Brasselet), Shizuoka University (Prof. V. Mizeikis), Laser Zentrum Hannover (Prof. B. Chichkov), University of Sheffield (Dr. F. Claeyssens), Belarusian State University (Prof. S. Kostjuk), Tokyo Institute of Technology (Prof. J. Morikawa).

Cooperation with industry:

a spin-off company Femtika, continuous collaboration with Light Conversion, Workshop of Photonics, Ekspla, Prodentum, 3D Creative, BioLabas, AmeraLabs.

Ongoing projects:

Laser Nanophotonics Group’s laboratories are continuously supported by National (Lithuanian Research Council: currently 3 running projects), European (H2020 LaserLab Europe and InterReg EcoLab-Net) and Worldwide (NATO Science for Peace program and US AMRDEC) funding schemes.

 

Resources

  • Automated setups of ultrafast lasers synchronized with linear stages and galvo-scanner for spatio-temporal selective light-matter interaction (DLW setup with widely tunable exposure conditions);
  • Tabletop optical 3D printers, spatial light modulators for beam shaping, UV light sources;
  • Chemistry laboratory for sample pre-/post-exposure preparation, development, vacuuming and/or heating;
  • Access to and expertise in scanning electron microscopy and optical profilometry inspections;
  • Custom optical setups for characterization of nanophotonic, microoptical and microfluidic components.

 

Contacts

 

Dr. Mangirdas Malinauskas

Laser Research Center

Faculty of Physics

E-mail:

More about center: http://www.lasercenter.vu.lt/en

 

Department for Research and Innovation

Vilnius University

Phone: +370 5 268 7006

E-mail:

More information: https://www.vu.lt/verslui/

 

Flyer for printing: Laser_Nanophotonics_Group.pdf