Nanofabrication Revolution: NUS and MPI-IS team unlocks light-driven 3D printing technique for new materials beyond polymers.

Unveiling the Optofluidic Breakthrough in Nanofabrication

A groundbreaking collaboration between researchers at Singapore's National University of Singapore (NUS) and Germany's Max Planck Institute for Intelligent Systems (MPI-IS) has shattered longstanding limitations in 3D printing technology. Published in Nature on January 28, 2026, the study introduces an innovative optofluidic three-dimensional microfabrication and nanofabrication method that enables the creation of complex microstructures using materials far beyond traditional polymers. This light-driven technique leverages precise manipulation of fluid flows induced by a femtosecond laser, opening doors to multifunctional devices at the micro- and nanoscale.

At its core, the process addresses the material constraints of conventional two-photon polymerization (2PP), a widely used method confined primarily to photosensitive polymers. By combining 2PP-printed templates with optofluidic assembly, the NUS-MPI-IS team has created a versatile platform for assembling nanoparticles into free-standing 3D structures held together solely by van der Waals forces, without the need for chemical bonding or high-temperature sintering in many cases.

How the Light-Driven Assembly Process Works Step-by-Step

Understanding the optofluidic process requires breaking it down into its fundamental components. First, researchers prefabricate a hollow 3D microtemplate using 2PP lithography. This template, often likened to a microscopic cake mold with a small side opening, is printed on a glass substrate using a polymer resin and serves as a confined space for assembly.

• Immerse the template in a dispersion of micro- or nanoparticles suspended in a liquid medium, such as water with salts or oils with surfactants.
• Direct a femtosecond laser (typically 780 nm wavelength, 80 MHz repetition rate, 50 mW power) near the template's opening to create a localized hot spot.
• The laser-induced heating generates a thermal gradient, triggering convective flows—optofluidic interactions—that propel particles toward and into the template at speeds up to several millimeters per second.
• Particles accumulate inside the mold, guided by precisely controlled flow rates (critical threshold around 300 µm/s) and colloidal interactions governed by DLVO theory (Derjaguin-Landau-Verwey-Overbeek, balancing van der Waals attraction and electrostatic repulsion).
• Once assembled, remove the polymer template via oxygen plasma etching or solvent washing, yielding a stable structure. Optional annealing at 600°C enhances bonding for certain materials.

This sequence achieves assembly rates of approximately 10⁵ particles per minute for silica nanoparticles, enabling rapid fabrication of intricate shapes like cubes, spheres, or even dangling croissants with curved surfaces.

Breaking Material Barriers: Printing Metals, Ceramics, and More

One of the most revolutionary aspects of this light-driven 3D printing technique is its compatibility with a diverse array of materials previously inaccessible to volumetric fabrication methods. Traditional 3D nanoprinting was polymer-bound, limiting applications requiring conductivity, magnetism, or robustness. Now, the optofluidic approach supports:

• Metals and metal nanoparticles: Silver (Ag), gold (Au), platinum (Pt) nanoparticles (<100 nm).
• Metal oxides and ceramics: Silica (SiO₂, 140 nm–10 µm), titania (TiO₂ nanoparticles 90 nm or nanowires 100 nm × 10 µm), iron oxide (Fe₃O₄, 17–195 nm), tungsten oxide (WO₃), alumina (Al₂O₃ nanowires).
• Carbon-based materials: Diamond nanoparticles (<10 nm).
• Semiconductors and quantum dots: CdTe quantum dots (710 nm emission).
• Hybrid combinations: Sequential assembly of dissimilar particles for multifunctional properties.

Dispersions are tuned with ionic strength (e.g., 0.5–1 M NaCl to promote attraction) and surfactants (CTAB, SDS) to optimize flow and prevent unwanted Marangoni effects from bubbles. This material versatility allows for structures with tailored electrical, optical, magnetic, or catalytic properties.

In Singapore's context, where advanced materials research drives innovation in electronics and biomedicine, NUS's expertise in materials science positions the country as a hub for such breakthroughs.

From Microcubes to Microrobots: Demonstrated Innovations

The technique has produced stunning examples, including 10 µm microcubes from SiO₂, helical screws with 320 nm threads from TiO₂, and nanoscale letters 'E' (855 nm height) from Fe₃O₄. More impressively, it fabricates functional devices like size-selective microfluidic valves and multimodal microrobots.

Microvalves embedded in 40 µm channels sort particles by size—rejecting 100 nm PLGA while passing larger ones—using concatenated assemblies for precise sieving. Microrobots integrate up to four materials: Fe₃O₄ for magnetic tumbling (10 mT field, 1–120 Hz), TiO₂-Au for UV-light propulsion (365 nm), and catalytic components for H₂O₂-driven motion.

Photo by Florian Olivo on Unsplash

The Visionary Team: NUS and MPI-IS Collaboration

Leading the effort is first author Xianglong Lyu (formerly MPI-IS, now KIT), with co-corresponding authors Mingchao Zhang (Assistant Professor, NUS Department of Materials Science and Engineering) and Metin Sitti (former MPI-IS Physical Intelligence Department head, now Koç University). Other contributors include Gaurav Gardi, Muhammad Turab Ali Khan, Wenhai Lei, and Shervin Bagheri.

"The key idea is to manipulate optofluidic interactions precisely, guiding 3D assembly within confined spaces," says Zhang. Lyu adds, "We now have a toolbox full of materials." Sitti envisions, "New frontiers for multifunctional micro-robots that sound like science-fiction."

This international partnership highlights NUS's growing role in global nanofabrication, fostering talent through programs like those at the Mechanobiology Institute.

Transforming Micro-Robotics and Beyond

In robotics, these microrobots enable multimodal locomotion—magnetic pulling, light rotation, chemical propulsion—paving the way for swarm robotics in confined environments. Medical applications include targeted drug delivery or minimally invasive surgeries, where devices navigate blood vessels thinner than a hair.

Engineering benefits from catalytic microreactors or photonics components with precise nanoscale features. Simulations via COMSOL confirm flow dynamics, ensuring reproducibility.

Singapore's Strategic Push in Nanofabrication Leadership

NUS's involvement underscores Singapore's investment in higher education and R&D, with initiatives like the National Nanotechnology Initiative supporting such work. Asst. Prof. Zhang's dual affiliation exemplifies cross-border collaboration, boosting local expertise in intelligent systems.

Institutions like NUS equip students with nanofab facilities, preparing them for industry demands in semiconductors and biotech. This aligns with Singapore's Smart Nation vision, where microscale tech drives economic growth.

Challenges, Solutions, and Future Horizons

Challenges include scaling throughput beyond lab demos and optimizing for ultra-fine resolutions (<100 nm). Solutions involve advanced surfactants and laser scanning (5–500 µm/s). Future outlooks predict commercialization for microfluidics and robotics by 2030, with hybrid printing for larger scales.

• Enhance multi-material co-assembly for smart sensors.
• Integrate AI for real-time flow control.
• Explore biomedical implants with biocompatible ceramics.

For more on cutting-edge research, read the full Nature publication.

Photo by Jakub Żerdzicki on Unsplash

Career Pathways in Singapore's Nanotech Ecosystem

Aspiring professionals can find postdoc and faculty positions at NUS, with demand surging for skills in laser optics and colloidal science. Platforms like AcademicJobs list openings in postdoc roles and university jobs.

Students rate NUS faculty on Rate My Professor for insights into programs. Career advice at higher-ed-career-advice helps navigate this dynamic field.

Details from MPI-IS press release: MPI-IS announcement.