Self-assembly

In the lower left corner of this photograph, researchers prepare a submersible device. “Together with our collaborators in the Maldives, we are designing, testing, building, and deploying submersible devices that, based simply on their geometry in relationship to the ocean waves and currents, promote sand accumulation in specific areas,” says associate professor Skylar Tibbits.

3 Questions: Harnessing wave power to rebuild islands

In the Maldives, an MIT team is conducting experiments to combat sea-level rise by redirecting natural sand movement.

May 11, 2020

The Maldives, a chain of islands in the Indian Ocean, are at risk of erosion and, at worst, submersion from rising sea levels. MIT's Skylar Tibbits is conducting field experiments with a group called Invena in the Maldives to harness the power of waves with underwater bladders to promote sand accumulation where it is most needed to protect shorelines from flooding.

Transformation by design

Skylar Tibbits makes materials that water, heat, or mechanical forces can alter into new shapes.

November 27, 2019

Photo shows two prototype assembler robots at work putting together a series of small units, known as voxels, into a larger structure.

Assembler robots make large structures from little pieces

Systems of tiny robots may someday build high-performance structures, from airplanes to space settlements.

October 16, 2019

Scanning electron microscope images of the crystal structure of the block copolymer material, illustrating their unusual quasicrystal symmetries. Regions with different symmetry properties are highlighted in different colors, and examples of the different patterns, which resemble some ancient tiling patterns, are shown in the accompanying diagrams.

A new way of making complex structures in thin films

Self-assembling materials can form patterns that might be useful in optical devices.

July 5, 2019

MIT graduate student Will Langford developed a machine that's like a cross between a 3-D printer and the pick-and-place machines that manufacture electronic circuits, but that can produce complete robotic systems directly from digital designs. (Video in "Related" sidebar below shows the assembly of a machine from five standard parts.)

Tiny motor can “walk” to carry out tasks

Mobile motor could pave the way for robots to assemble complex structures — including other robots.

July 2, 2019

A new method produces a printable structure that begins to fold itself up as soon as it’s peeled off the printing platform.

“Peel-and-go” printable structures fold themselves

Expanding polymer enables self-folding without heating or immersion in water.

September 13, 2017

A newly developed wing architecture could greatly simplify the manufacturing process and reduce fuel consumption by improving the wing’s aerodynamics. It is based on a system of tiny, lightweight subunits that could be assembled by a team of small specialized robots, and could ultimately be used to build the entire airframe.

A new twist on airplane wing design

“Morphing” wing could enable more efficient plane manufacturing and flight.

November 3, 2016

Programming materials for better designs

Skylar Tibbits creates smart materials that elegantly transform themselves to improve processes and products.

August 11, 2015

Centimeter-long origami robot

Controlled by magnetic fields, tiny robot climbs inclines, swims, and carries loads twice its weight.

June 12, 2015

Origami robot folds itself up, crawls away

Prototype made almost entirely of printable parts demonstrates crucial capabilities of reconfigurable robots.

August 7, 2014

Before-and-after stills from the video "An End-to-End Approach to Making Self-Folded 3D Surface Shapes by Uniform Heating." The left image shows the self-folding sheet for a humanoid shape, while the right image shows the completed self-folded humanoid shape.

Bake your own robot

New algorithms and electronic components could enable printable robots that self-assemble when heated.

May 30, 2014

MIT Materials Science and Engineering graduate student Nicolas M. Aimon inserts a holder into a pulsed laser deposition chamber.

Switchable magnetic pillars

Graduate student Nicolas Aimon develops pulsed laser deposition techniques for mixed multiferroic oxide films.

September 30, 2013

Caroline Ross uses models to demonstrate the crystal structures of complex metal oxides, such as spinel and perovskite phases.

Faculty highlight: Caroline Ross

New techniques for combining complex oxide thin films promise electrical control of magnetic properties for data storage and computing.

September 27, 2013

The Self-Assembly Line installation at TED Long Beach 2012

Exploring the future of making things

Introducing the Self-Assembly Lab at SA+P

April 8, 2013

An artist's representation of the structures produced by this self-assembly method shows a top-down view, with the posts produced by electron-beam lithography shown in blue, and the resulting self-assembled shapes shown in white.

Research update: Chips with self-assembling rectangles

New technique allows production of complex microchip structures in one self-assembling step.

July 19, 2012

MIT News | Massachusetts Institute of Technology

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