Synthetic gelatin-like material mimics lobster underbelly’s stretch and strength
The membrane’s structure could provide a blueprint for robust artificial tissues.
The membrane’s structure could provide a blueprint for robust artificial tissues.
A collaboration between MIT and CNRS has yielded a cement that conducts electricity and generates heat.
Deterministic lateral displacement assay can rapidly assess host inflammatory response, identifying a potentially life-threatening hyper-aggressive immune response.
MIT research combines machine learning with nanoparticle design for personalized drug delivery.
A new approach to identifying useful formulations could help solve the degradation issue for these promising new lightweight photovoltaics.
Using an ordinary light microscope, researchers can now obtain images with unprecedented accuracy.
Study finds the wettability of porous electrode surfaces is key to making efficient water-splitting or carbon-capturing systems.
The startup Transaera is using a class of materials, advanced by MIT Professor Mircea Dinca for over a decade, to create a more energy-efficient air conditioner.
Use of a novel electrolyte could allow advanced metal electrodes and higher voltages, boosting capacity and cycle life.
Five courses celebrate the nanoscale, highlight technologies in photogrammetry and 360-degree videography.
Student committee delivers interactive conference on microsystems and nanoscience.
Engineered plant nanosensors and portable Raman spectroscopy will help enable sustainable practices in traditional and urban agriculture.
Cutting-edge microscope helps reveal ways to control the electronic properties of atomically thin materials.
Reducing internal losses could pave the way to low-cost perovskite-based photovoltaics that match silicon cells’ output.
Inspired by decades-old MIT research, the new technology could boost quantum computers and other superconducting electronics.