Breaking 19:15 Trump announces renewed maritime blockade against Iran amid Strait of Hormuz tensions 19:00 NASA seeks four volunteers for year-long Mars mission simulation 17:30 States challenge Paramount’s $110 billion Warner Bros. Discovery takeover in major antitrust lawsuit 17:15 Bosch launches sample production at first U.S. semiconductor plant to strengthen domestic chip supply 14:30 Williams secures $5.3 billion investment from Blackstone-led consortium for power projects 13:45 Iraqi Prime Minister Ali al-Zaidi seeks major US energy investment during Washington visit 12:31 Jay-Z concert delayed in New York after ticketless fans disrupt Yankee Stadium event 12:00 Wall Street banks accelerate AI assistant adoption in race for productivity gains 11:47 US Military Reveals First Combat Use of New Unmanned Weapons in Strikes on Iran 11:30 US Ebola patient infected in Congo transferred to specialized hospital in Germany 10:56 Morrisons explores £600 million property deal with US investor Realty Income, Sky News reports 10:41 US dollar gains as Middle East tensions fuel inflation concerns 09:00 UN chief urges US and Iran to end renewed hostilities and resume diplomacy 08:35 U.S. military says Strait of Hormuz remains open despite rising tensions with Iran 08:30 France’s World Cup journey links Boston and Dallas, two cities tied to John F. Kennedy’s legacy 08:18 Support grows in U.S. Congress for bill seeking terrorist designation of Polisario Front 07:31 Stellantis reports 10% rise in second-quarter vehicle shipments driven by North American demand

MIT engineers silent artificial muscle fibers for robots

Friday 10 April 2026 - 08:20
By: Dakir Madiha
MIT engineers silent artificial muscle fibers for robots

Researchers at MIT Media Lab and Italy's Politecnico di Bari developed a new class of artificial muscle fibers that operate silently without motors, external pumps or bulky hydraulic gear. The advance could reshape robot movement and portable assistive device design.

The technology, called electrofluidic fiber muscles, appeared in a Science Robotics paper this week. Led by MIT Media Lab doctoral student Ozgun Kilic Afsar and Politecnico di Bari professor Vito Cacucciolo, the work merges miniaturized McKibben actuators, soft fluidic muscles, with millimetric electrohydrodynamic (EHD) pumps. These pumps generate pressure in sealed fluid compartments without moving parts.

EHD pumps at this scale inject charges into dielectric fluid to create ions that pull liquid along. Each weighs grams and measures toothpick-thin. One pump sits between two McKibben actuators in antagonist setup, one contracting as the other relaxes to mimic human biceps and triceps action.

"We chose this setup not just for biomimicry but to store fluid within the muscle itself," Afsar said in an MIT release. Closed-loop fiber circuits eliminate external reservoirs, a key lab-to-real-world barrier for fluidic soft robots.

Fibers bundle into configurations like biological muscle tissue for compact integration into robots or exoskeletons, distributed across structures rather than joint-focused. Tests showed a woven biceps-triceps pair driving a 3D-printed robotic arm and a lever arm launching objects in 100 milliseconds.

Herbert Shea, a professor at Switzerland's EPFL not involved, called it "a major step for fiber-format soft actuators." He noted the pump's lack of moving parts makes them quiet, ideal for prosthetics and assistive garments.

Applications range from exoskeletons for heavy lifting to dexterity aids. "Wherever fluidic actuators operate or engineers want internal over external pumps, these principles suit broad fluid-driven robotic systems," Cacucciolo said. Funding came from the European Research Council and MIT Media Lab's multi-partner consortium.


  • Fajr
  • Sunrise
  • Dhuhr
  • Asr
  • Maghrib
  • Isha

Read more

This website, walaw.press, uses cookies to provide you with a good browsing experience and to continuously improve our services. By continuing to browse this site, you agree to the use of these cookies.