There are many conceptions of programmable matter, and thus many discrete avenues of research using the name. Below are some specific examples of programmable matter.
"Solid-liquid phase-change pumping" Shape-changing and locomotion of solid objects are possible with solid-liquid phase change pumping. This approach allows deforming objects into any intended shape with sub-millimetre resolution and freely changing their topology.
"Simple" These include materials that can change their properties based on some input, but do not have the ability to do complex computation by themselves.
Complex fluids The physical properties of several complex fluids can be modified by applying a current or voltage, as is the case with
liquid crystals.
Metamaterials Metamaterials are artificial
composites that can be controlled to react in ways that do not occur in nature. One example developed by David Smith and then by John Pendry and David Schuri is of a material that can have its
index of refraction tuned so that it can have a different index of refraction at different points in the material. If tuned properly, this could result in an
invisibility cloak. A further example of programmable -mechanical- metamaterial is presented by Bergamini et al. Here, a pass band within the phononic bandgap is introduced, by exploiting variable stiffness of piezoelectric elements linking aluminum stubs to the aluminum plate to create a phononic crystal as in the work of Wu et al. The piezoelectric elements are shunted to ground over synthetic inductors. Around the resonance frequency of the LC circuit formed by the piezoelectric and the inductors, the piezoelectric elements exhibit near zero stiffness, thus effectively disconnecting the stubs from the plate. This is considered an example of programmable mechanical metamaterial. Similarly, these mechanical unit cells are programmed through the interaction between two electromagnetic coils in the Maxwell configuration, and an embedded magnetorheological elastomer. Different binary states are associated with different stress-strain response of the material.
Shape-changing molecules An active area of research is in molecules that can change their shape, as well as other properties, in response to external stimuli. These molecules can be used individually or en masse to form new kinds of materials. For example,
J Fraser Stoddart's group at UCLA has been developing molecules that can change their electrical properties.
Robotics-based approaches Self-reconfiguring modular robotics Self-reconfiguring modular robotics involves a group of basic robot modules working together to dynamically form shapes and create behaviours suitable for many tasks, similar to programmable matter. SRCMR aims to offer significant improvement to many kinds of objects or systems by introducing many new possibilities. For example: 1. Most important is the incredible flexibility that comes from the ability to change the physical structure and behavior of a solution by changing the software that controls modules. 2. The ability to self-repair by automatically replacing a broken module will make SRCMR solution incredibly resilient. 3. Reducing the environmental footprint by reusing the same modules in many different solutions. Self-reconfiguring modular robotics enjoys a vibrant and active research community.
Claytronics Claytronics is an emerging field of
engineering concerning reconfigurable
nanoscale robots ('claytronic
atoms', or
catoms) designed to form much larger scale
machines or mechanisms. The catoms will be sub-millimeter computers that will eventually have the ability to move around, communicate with other computers, change color, and
electrostatically connect to other catoms to form different shapes.
Cellular automata Cellular automata are a useful concept to abstract some of the concepts of discrete units interacting to give a desired overall behavior.
Quantum wells Quantum wells can hold one or more electrons. Those electrons behave like
artificial atoms which, like real atoms, can form
covalent bonds, but these are extremely weak. Because of their larger sizes, other properties are also widely different.
Synthetic biology is a
biological machine that utilizes
protein dynamics on
nanoscales to synthesize
proteins. Synthetic biology is a field that aims to engineer cells with "novel biological functions." Such
cells are usually used to create larger systems (e.g.,
biofilms) which can be "programmed" utilizing synthetic
gene networks such as
genetic toggle switches, to change their color, shape, etc. Such bioinspired approaches to materials production has been demonstrated, using self-assembling bacterial biofilm materials that can be programmed for specific functions, such as substrate adhesion,
nanoparticle templating, and protein immobilization. == See also ==