Thermal
management materials (TMMs) used in electronic devices
are crucial for future electronics and technologies such as flexible
electronics and artificial intelligence (AI) technologies. As future
electronics will work in a more complicated circumstance, the overheating
and overcooling problems can exist in the same electronics while the
common TMMs cannot meet the demand of thermal management for future
electronics. In this work, nacre-mimetic graphene-based films with
super flexibility and durability (in over 10,000 tensile cycles),
excellent capability to dissipate excess heat (20.84 W/(m·K)
at only 16–22 μm thickness), and outstanding heating
performance to generate urgent heat for electronics under extremely
cold conditions are fabricated by a facile solution casting method,
and the fabricated composites are proved to be superior multifunctional
TMMs for the thermal management in electronic chips. In addition,
the application of the paper-like films with high in-plane thermal
conductivity to a flexible heat spreader and film heater is demonstrated
by simulation using a finite volume method, which shows the high importance
of the in-plane thermal conductivity in thermal management of electronics.
With the intention to abate the pollution arising from the improper handling of petroleum-based plastic, green composites consisting of biodegradable plastics and biomass wastes have received widespread attention. However, the balance between mechanical performance and biodegradability still has not been reconciled and evaluated. Herein, a concept for water-soluble poly(vinyl alcohol) (PVA)/biomass waste composite materials is proposed. Instead of degrading to small molecules, the PVA matrix can dissolve in water within the soil. Moreover, after PVA was composited with waste cottonseed shell (CTS) using solid-state shearing milling (S 3 M) technology, considerable mechanical and thermal performance was achieved, with the maximum tensile strength and degradation temperature of the PVA/CTS composites reaching 10.3 MPa and ∼250 °C, respectively. Moreover, the soil burial test demonstrated that even if PVA cannot degraded in environment within a short term, its water-soluble nature ensures its environmental friendliness, as the PVA matrix can dissolve in soil in 10 days without imposing any adverse effects on either plants (wheat) or animals (earthworm). This work not only describes the preparation a series of ecofriendly PVA/biomass composites but also provides new insight into the environmental friendliness of PVA-based materials.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.