However, Ceramic nanoparticles take on a larger variety of functions,[1] including dielectric, ferroelectric, piezoelectric, pyroelectric, ferromagnetic, magnetoresistive, superconductive and electro-optical.
In 2014 researchers announced a lasering process involving polymers and ceramic particles to form a nanotruss.
[citation needed] Ceramic nanoparticles have been used as drug delivery mechanism in several diseases including bacterial infections, glaucoma, and most commonly, chemotherapy deliver in experimental cancer treatment.
These properties are often shown in terms of various electrical and magnetic physics phenomenons which include: Ceramic nanoparticle is more than 85% air and is very light, strong, flexible and durable.
The sol and gel are mixed to produce an oxide material which are generally a type of ceramic.
This process uses a laser technique called two-photon lithography to etch out a polymer into a three-dimensional structure.
This resulted in a rough material that damages the properties of ceramics and requires more time to obtain an end product.
Inside the boxes are suspectors that absorb microwaves at room temperature to initialize the sintering process.
In 2012 researchers replicated the sea sponge's structure using ceramics[7] and the nanoarchitecture called nanotruss.
It has been suggested for areas including energy supply and storage, communication, transportation systems, construction and medical technology.