Abstract: Self-assembling peptides offer great potential as versatile building blocks for developing functional hydrogels suitable for various applications.

This presentation will focus on the mussel inspired design of peptide-based antibacterial hydrogels.

These bioinspired materials combat bacteria through a dual mechanism involving surface-contact membrane disruption and oxidative killing facilitated by hydrogen peroxide (H2O2) production. The leading formulation, MIKA2, has shown its potential as an injectable hydrogel capable of preventing implant-related bacterial infections, effectively reducing bacterial colonization on titanium implants in mice.

From Waste to Worth: Ozone Pretreatment as a Platform for Sustainable Resource Recovery

Monday June 30th 2025 at 14:00 

Wolfson Building of Mechanical Engineering, Room 206

Abstract:

As global pressures mount around waste accumulation and resource scarcity, advanced oxidation processes- particularly ozone-based treatments- offer promising pathways to transform waste into valuable materials. This seminar presents a series of interdisciplinary investigations into ozone-assisted strategies for upgrading lignocellulosic, textile, and plastic waste streams into functional products.

For lignocellulosic waste, a hydrodynamic venturi reactor was engineered using a “Free model” configuration, allowing unrestricted circulation of particles and achieving nearly 100% ozone utilization. This design improved mass transfer, eliminated the need for off-gas treatment, and significantly enhanced enzymatic hydrolysis yields- up to 65%- while enabling valorization of residual solids into materials suitable for adsorption. This approach supports a scalable, near-zero-waste biorefinery model.

In the treatment of textile waste, ozone was implemented as a post-treatment “polishing” and bleaching step in nanocellulose (NC) production. The process improved NC purity and functional surface properties, while enabling recovery and reuse of sulfuric acid- commonly discarded in conventional protocols- thereby reducing operational costs and environmental hazards.

The third case explores an emerging biotechnological frontier: Plastic waste valorization explored the integration of ozone with fungal biodegradation. Ozone pretreatment increased the hydrophilicity and surface reactivity of nylon, promoting colonization by Trametes versicolor. The resulting fungal biomass shows promise as a protein-rich additive for food or feed, presenting an innovative route for transforming recalcitrant polymers into nutritive resources.

Additional innovations include reactor design optimization for energy efficiency, streaming potential surface characterization, and ozone application for pollutant degradation. Together, these findings demonstrate that ozone pretreatment, when coupled with tailored bioprocessing, provides a flexible and scalable platform to advance circular economy goals, integrating waste management, biotechnology, and sustainable engineering.

Bio:

Barak Halpern is a multidisciplinary environmental engineer and biotechnologist specializing in advanced oxidation processes for waste valorization. His doctoral research at Tel Aviv University, conducted in collaboration with the University of Toronto, Oranim College, and Kinneret College, focuses on ozone-based pretreatment technologies to enhance the biodegradation and upcycling of organic and plastic waste. His work integrates reactor engineering, biotechnology, and circular economy principles to convert waste streams.

A hallmark of his Ph.D. research is the design of an innovative hydrodynamic venturi reactor operating in a "Free model" configuration, which achieves nearly 100% ozone utilization and significantly improves enzymatic hydrolysis efficiency. He has demonstrated the reactor’s scalability in a semi-pilot biorefinery producing disinfectant-grade ethanol during the COVID-19 pandemic. In related projects, Barak has developed processes for recovering and reusing sulfuric acid in nanocellulose production and for accelerating fungal degradation of ozone-treated plastic waste.

Barak has published in high-impact journals (e.g., Cellulose, International Journal of Molecular Sciences) and presented at leading conferences in sustainability, food tech, and polymer recycling. He has received multiple awards, including the Teaching Commendation for excellence in education (2023/2024), the KKL Climate Scholarship, and 2nd place in the Falling Walls Israel Lab competition for his work on agri-plastic waste biodegradation, and participating on Coller 2025 contest.

Beyond the lab, he is an experienced mentor, educator, and social entrepreneur, having led sustainability-focused engineering projects through Engineers Without Borders and student-led initiatives addressing pollution, recycling, and environmental resilience.

Design of High Performance Minimally Actuated Robots

Monday June 16th 2025 at 14:00 

Wolfson Building of Mechanical Engineering , Room 206 

Abstract:

From delicate medical procedures to hazardous environment exploration, bio-inspired robots are transforming fields like medicine, search and rescue, maintenance, and security.

Our lab builds versatile bio-inspired robots for medicine, exploration, and environmental tasks. We often draw inspiration from nature's ingenuity but with a minimalist approach. Unlike animals' intricate musculature, our robots achieve impressive capabilities with a small number of motors, leading to innovative designs that can crawl, drive, and fly across diverse environments. From reconfigurable robots that adapt to challenging surfaces to wave-like swimmers, these robotic designs showcase the power of combining biological inspiration with efficient design.

In this talk, we will present the impact of minimalistic actuation on enhancing performance in robotics and explore new actuation concepts that hold the potential to address specific challenges. By reducing the number of actuators and incorporating minimalist approaches, we can reduce the weight and size, improve energy efficiency, and enhance the robots' overall mobility and maneuverability. During the talk, we will showcase a variety of examples of robots that we designed in the last years. (The talk will discuss methods and concepts but will not include analytical models).

Bio:

David Zarrouk is an Associate Professor at the Mechanical Engineering department of Ben Gurion University of the Negev and director of the “Bio-inspired and Medical Robotics” Laboratory. He received his M.Sc. in 2007 (in stochastic mechanics) and Ph.D. in 2011 (in medical robotics) from the faculty of Mechanical Engineering at the Technion. Between Aug. 2011 and Sep. 2013, he was a Fulbright postdoctoral scholar at the EECS Dep. of U.C. Berkeley, working on miniature crawling robots. His research interests are in robotic design, bio-inspired and miniature robotics, flexible and slippery robot-to-surface interaction, space robotics, minimally actuated mechanisms, and medical devices. Prof. Zarrouk received multiple prizes in teaching, research, and innovation.

Multi-scale remote sensing of jellyfish swarms

Monday May 26th 2025 at 14:00 

Wolfson Building of Mechanical Engineering, Room 206 

Abstract:

The study of jellyfish swarms, which comprise large amounts of individuals that spread over broad

areas, is a multi-scale scientific endeavor. Focusing on seasonal swarms of the jellyfish

Rhopilema nomadica in the eastern Mediterranean, we show how integration of remote sensing

observations from multiple platforms enables a broad perspective on the dynamics of jellyfish swarms, providing new insights over a wide range of spatial and temporal scales - from the behavior of individuals to the spatial characteristics and biogeochemical importance of the bloom as a whole.

At the smallest scale, jellyfish swimming behavior is characterized through Lagranian tracking the

trajectories of multiple adjacent individuals as appear in videos taken by drones hovering over the

bloom. At the regional scale, time varying spatial characteristics of the jellyfish bloom are extracted from aerial images taken from light airplanes. Finally, based on comparison with consecutive satellite images of surface chlorophyll concentrations, which is used as a tracer to transport by the currents, we link the displacement of the jellyfish swarm to fine scale (~1-100 km) circulation patterns.

This research sheds new light on the characteristics of Rhopilema nomadica blooms in the

eastern Mediterranean, and emphasizes the advantages of incorporating multi-platform remote

sensing observations in regional studies of jellyfish blooms worldwide.

Bio:

Yoav Lehehn is faculty member at the Charney School of Marine Sciences in the University of Haifa. In his scientific work, Yoav is studying marine systems through synergy between in-situ measurements and remote-sensing data from airplanes, satellites and drones. Yoav’s current research focuses on promoting data-based oceanic research by automating the process of ocean data integration; development and implementation of Lagrangian methods and image analysis tools for interpretation satellite and drone imagery; and harnessing drone technology to support marine research, with emphasis on small-scale ocean dynamics and motion of marine organisms.