Abstract: An electronic device having a thermal management system is provided. The thermal management system has a monolithic graphite element having a thickness of at least 150 microns. The graphite element has a thermal conductivity of at least about 700 W/mK. The graphite element is devoid of an internal adhesive, i.e., the graphite element is monolithic. The thermal management system is in operative contact with a heat source which comprises more than one electronic component. Preferably, the more than one electronic component is disposed on a stacked motherboard.

Abstract: Shielding articles are disclosed. One shielding article includes a fire retardancy element/fire propagation reduction element, which includes a pair of flexible graphite outer layers and a core, where the flexible graphite outer layers are on opposing sides of the core. The core may include one or more fire retardant elements or insulation materials. Also disclosed are battery packs that include the shielding articles. The shielding articles can be applied in any system that reduced fire propagation would be desirable.

Abstract: Assemblies having multi-functionalities of any combination of heat spreading, absorption of stray radiation, signal focusing, and shielding are provided. The assemblies may include a heat spreading layer of at least one sheet of a compressed particles of exfoliated graphite, graphitized polymers and combinations thereof. The assemblies may also include at least one magnetic layer, which may provide the benefits of magnetic flux management and/or stray radiation absorption. The assemblies may include an optional plastic coating on one or both of the exterior surfaces. The assemblies may be used to enable fast wireless charging of electronic devices by efficiently focusing magnetic flux for better power transmission efficiency.

Abstract: Assemblies having multi-functionalities of any combination of heat spreading, absorption of stray radiation, signal focusing, and shielding are provided. The assemblies may include a heat spreading layer of at least one sheet of a compressed particles of exfoliated graphite, graphitized polymers and combinations thereof. The assemblies may also include at least one magnetic layer, which may provide the benefits of magnetic flux management and/or stray radiation absorption. The assemblies may include an optional plastic coating on one or both of the exterior surfaces. The assemblies may be used to enable fast wireless charging of electronic devices by efficiently focusing magnetic flux for better power transmission efficiency.

Abstract: A microfluidic system including a number of microfluidic devices having a first perfusion path and a second separate perfusion path; the microfluidic devices each also having a chamber containing a matrix, where the matrix surrounds at least one void whose lumen is in fluidic connection exclusively with the first perfusion path, where the at least one void is populated with at least one cell type in such way that the cells are in direct contact with the matrix; where the matrix is in fluidic connection exclusively with the second separate perfusion path. The microfluidic devices are integrated onto a platform; and each of the microfluidic devices mimics at least a partial organ module.

Abstract: A microfluidic system for generating compartmentalized microenvironments of tissues and organs in vitro and for independently perfusing the compartments. A microfluidic device that includes at least a first perfusion path and a second separate perfusion path. The microfluidic device also has a chamber containing a matrix, where the matrix surrounds at least one void whose lumen is in fluidic connection exclusively with the first perfusion path, where the at least one void can be populated with at least one cell type in such way that the cells are in direct contact with the matrix and the matrix is in fluidic connection exclusively with the second separate perfusion path.

Abstract: Methods of randomly dispersing chopped carbon fiber and consolidating the materials together to make a fiber reinforcement mat are disclosed. The term “Z-mat” is used to describe the claimed random fiber mat in which the chopped fibers are not preferentially oriented in either the x or y direction in the in-plane directions of the mat. The stiffness in the Z-mat is substantially independent of the test direction in the plane of the mat. The Z-mat offers the distinct advantages of higher stiffness and lighter weight.