What is transverse optical torque?

Transverse optical torque is a twisting force exerted by light on matter perpendicular to the light's propagation direction, driven by optical helicity rather than angular momentum.

Who led the Hokkaido University study?

Professor Yoshito Y. Tanaka from the Laboratory of Nanosystem Optical Manipulation at RIES, with Ryoma Fukuhara and Tsutomu Shimura.

How was the micro-drone platform developed?

The micro-drone is a cross-shaped microstructure holding a V-shaped gold nanostructure, trapped by four laser beams to amplify and measure tiny torques in 3D.

What journal published the findings?

Nature Physics , DOI: 10.1038/s41567-026-03268-6, on April 20, 2026.

Why is RIES at Hokkaido University significant?

RIES excels in photonics and nanomaterials, securing major MEXT/JSPS funding and training PhD students for Japan's photonics industry.

What are potential applications?

Light-driven nanomachines, chiral molecule sorting, quantum sensors, and biomolecular tweezers for drug delivery and sensing.

How does Japan's photonics research compare globally?

Japan holds 25% market share and leads in patents; Hokkaido contributes via university-industry ties like Fujitsu.

What funding supports such research?

MEXT's science budget (¥400B+), JSPS fellowships, and programs like Moonshot R&D fuel Hokkaido's photonics efforts.

Role of students in the research?

Grad students like Ryoma Fukuhara co-authored, gaining hands-on nanofab and laser skills at RIES facilities.

Future directions for the technology?

Micro-drone arrays for parallel measurements, attonewton precision, and integrations with biotech for chiral analysis.

How does this advance optical tweezers?

Extends Ashkin's Nobel tech from axial to full 3D torque, unlocking new optomechanics phenomena.

Hokkaido U Light Twisting Matter Discovery | Nature Physics

A spiral of rocks in the middle of a body of water — Photo by Steve A Johnson on Unsplash

Revolutionary Discovery at Hokkaido University: Light's Hidden Twisting Power

Researchers at Hokkaido University have uncovered a groundbreaking phenomenon where light exerts a twisting force on matter in a direction perpendicular to its travel path. This transverse optical torque challenges long-held assumptions in photonics and opens new frontiers for nanoscale manipulation. Published today in Nature Physics, the study led by Professor Yoshito Y. Tanaka from the Research Institute for Electronic Science (RIES) demonstrates how light's optical helicity can drive this unexpected rotation, paving the way for advanced nanomachines and sensors.

The experiment involved illuminating V-shaped gold nanostructures with precisely controlled laser beams. Traditional optical tweezers, pioneered by Nobel laureate Arthur Ashkin, measure forces along the light's propagation axis. However, Tanaka's team innovated with a 'micro-drone' platform—a cross-shaped microstructure holding the target nanostructure at its center. Four laser beams trap the arms, amplifying tiny torques into observable motions, allowing full three-dimensional analysis.

The Science Behind Light's Transverse Torque

Light carries both spin angular momentum from its circular polarization and orbital angular momentum from twisted wavefronts, like a vortex. While spin torque is well-known, orbital effects were thought limited to longitudinal twisting. Surprisingly, the Hokkaido team found torque perpendicular to propagation, linked not to angular momentum but to optical helicity—the field's overall twist handedness.

By designing beams that cancel angular momentum yet retain helicity, they confirmed the torque persists. This helicity-driven effect arises from multipolar interactions between light's electromagnetic fields and the nanostructure's geometry. The V-shape enhances this asymmetry, rotating under illumination in ways defying classical predictions.

This builds on decades of photonics research. In Japan, universities like Hokkaido have excelled in structured light studies, with RIES specializing in nanosystem optical manipulation since its founding in 1989.

Innovative Micro-Drone: A Game-Changer in Nanoscale Measurement

The micro-drone is the study's crown jewel. Fabricated via electron beam lithography, this 5-micrometer platform suspends a 200-nanometer gold V-structure. Laser tweezers at each arm create a stable trap, converting nanostructure perturbations into micron-scale deflections trackable by high-speed cameras.

This sidesteps thermal noise overwhelming direct nanoscale measurements. Step-by-step: lasers form an optical cage; light hits the V; torque twists the drone; software analyzes rotation vectors. Results showed torques up to 10 femtonewton-meters, 100 times prior sensitivities.

Micro-drone platform trapping nanostructure for precise optical torque measurement at Hokkaido University

Such precision tools position Hokkaido as a leader in optomechanical instrumentation, training students in nanofabrication and laser physics.

Hokkaido University's Research Institute for Electronic Science: A Photonics Powerhouse

RIES at Hokkaido University integrates materials science, photonics, and life sciences. Home to labs like Tanaka's Nanosystem Optical Manipulation, it pioneers light-matter control for quantum devices and biomedicine. With over 100 researchers, RIES secures major grants from Japan's Ministry of Education, Culture, Sports, Science and Technology (MEXT) and Japan Society for the Promotion of Science (JSPS).

Hokkaido ranks top-10 nationally in physics per QS 2026, bolstered by cold-climate advantages for optics testing. Annual funding exceeds ¥5 billion, supporting 50+ PhD students yearly. This torque study exemplifies RIES's interdisciplinary ethos, blending engineering and advanced life sciences faculties.

Japan invests ¥1.2 trillion yearly in photonics R&D, with universities contributing 40%. Hokkaido's contributions include coherent X-ray optics and biophotonics, fostering startups via the university's venture incubator.

Implications for Nanotechnology and Beyond

Transverse torque enables precise chiral control at nanoscale, crucial for drug delivery rotors, microfluidic mixers, and quantum sensors. Imagine light-powered nanomotors navigating cells without chemicals, or torque-based chirality detectors for biomolecules.

In Japan, this aligns with Society 5.0 goals, integrating cyber-physical systems. Potential applications span semiconductors—Hokkaido collaborates with imec on photonics chips—and healthcare, twisting proteins for study.

Globally, it rivals US/EU efforts; Japan's photonics market hits $10 trillion by 2030, driven by university innovations.

Read the full Nature Physics paper for technical details on helicity calculations.

Japan's Higher Education Landscape in Photonics Research

Japanese universities lead photonics, with Hokkaido, Tokyo, Osaka excelling. MEXT's Top Global University Project funds international collaborations, boosting Hokkaido's profile. Photonics PhDs grew 15% since 2020, supported by JSPS fellowships averaging ¥2 million/year.

Key strengths: Structured light generation, nanofabrication facilities like RIES cleanrooms.
Challenges: Aging faculty; initiatives like tenure-track hires address this.
Industry ties: Fujitsu, Nikon leverage uni research for lasers/optics.

Hokkaido emphasizes student-led projects; Fukuhara, a grad student, co-authored, highlighting mentorship.

Experimental Validation and Theoretical Framework

Tests used Laguerre-Gaussian beams with varying topological charge (OAM quanta). Torque scaled with helicity, vanishing in linear polarization. Finite-difference time-domain simulations matched experiments, confirming multipole origins.

Step-by-step theory: Light's electric field induces oscillating dipoles in gold; magnetic gradients from helicity produce sideways Lorentz torques. This unifies spin/orbital effects under helicity.

RIES's optics suites enabled beam shaping; future upgrades target attonewton precision.

Future Outlook: From Lab to Real-World Applications

Tanaka envisions helicity tweezers for sorting chiral molecules, aiding pharma. In Japan, Moonshot R&D Program (¥1 trillion) funds such optomechanics.

Hokkaido plans micro-drone arrays for parallel measurements, training next-gen researchers. International ties with EU/US expand scope.

Explore RIES's photonics labs for ongoing projects.

This discovery cements Hokkaido's role in Japan's quest for photonics supremacy, inspiring students nationwide.

Stakeholder Perspectives and Broader University Impact

JSPS praises the work for advancing optomechanics. Tanaka: "Our micro-drone unlocks nanoscale mechanics, akin to Ashkin's tweezers revolutionizing biophysics."

For Hokkaido students, RIES offers hands-on training; 80% grads enter industry/academia. Nationally, it bolsters Japan's 20% global photonics patent share.

Challenges like funding competition persist, but MEXT's ¥400 billion science budget supports.