Various implementations and embodiments relate to three-dimensional open cellular diamond micro-truss structures and methods.

A porous metal body having a flat plate shape and having a three-dimensional network structure skeleton includes multiple cells, in which, when a ratio of a cell diameter in a thickness direction of the porous metal body to a cell diameter in a direction orthogonal to the thickness direction (cell diameter in thickness direction/cell diameter in direction orthogonal to thickness direction) is defined as a cell diameter ratio, formula (1) and formula (2) below are satisfied:

0.4≥cell diameter ratio≥1.0  formula (1)

0.50<cell diameter in direction orthogonal to thickness direction/(thickness of porous metal body/cell diameter ratio)≥1.50  formula (2)

A porous metal body having a flat plate shape and having a three-dimensional network structure skeleton includes multiple cells, in which, when a ratio of a cell diameter in a thickness direction of the porous metal body to a cell diameter in a direction orthogonal to the thickness direction (cell diameter in thickness direction/cell diameter in direction orthogonal to thickness direction) is defined as a cell diameter ratio, formula (1) and formula (2) below are satisfied:

0.4≥cell diameter ratio≥1.0  formula (1)

0.50<cell diameter in direction orthogonal to thickness direction/(thickness of porous metal body/cell diameter ratio)≥1.50  formula (2)

Disclosed are actuators containing an active layer comprising at least one metal hydroxide, the active layer having a first volume under no stimulation and a second volume either greater than or smaller than the first volume under stimulation; and a passive layer comprising a porous polymer membrane, the passive layer having an elastic modulus at least half of an elastic modulus of the active layer.

Disclosed are actuators containing an active layer comprising at least one metal hydroxide, the active layer having a first volume under no stimulation and a second volume either greater than or smaller than the first volume under stimulation; and a passive layer comprising a porous polymer membrane, the passive layer having an elastic modulus at least half of an elastic modulus of the active layer.

In a method for producing porous composite bodies, which have a support structure made of a material having good thermal conductivity and which have at least one functional material, a multiplicity of shaped bodies (1) made of the functional material are coated with the material having good thermal conductivity and a solid connection between the coated shaped bodies (1) is established in order to form the support structure made of the material having good thermal conductivity. The coating (2) is generated with a porous structure or is provided with a porous structure, which, after the solid connection has been established, permits access for a liquid or gaseous medium through the coating to the functional material. The method permits cost-effective production of porous composite bodies with very good heat transfer properties.

In a method for producing porous composite bodies, which have a support structure made of a material having good thermal conductivity and which have at least one functional material, a multiplicity of shaped bodies (1) made of the functional material are coated with the material having good thermal conductivity and a solid connection between the coated shaped bodies (1) is established in order to form the support structure made of the material having good thermal conductivity. The coating (2) is generated with a porous structure or is provided with a porous structure, which, after the solid connection has been established, permits access for a liquid or gaseous medium through the coating to the functional material. The method permits cost-effective production of porous composite bodies with very good heat transfer properties.

An aluminum porous body has a skeleton with a three-dimensional network structure, in which the skeleton is formed of an aluminum layer containing aluminum carbide, and when the aluminum porous body is subjected to XRD measurement, diffraction peaks originating from aluminum carbide are detected at two peak positions in a 2θ range of 30.8° or more and 31.5° or less and a 2θ range of 31.6° or more and 32.3° or less.

A porous metal body including a skeleton having a three-dimensional mesh-like structure, the porous metal body having a plate-like overall shape. The skeleton has a hollow structure and includes a primary metal layer and at least one of a first microporous layer and a second microporous layer. The primary metal layer is composed of nickel or a nickel alloy. The first microporous layer contains nickel and chromium and is disposed on the outer peripheral surface of the primary metal layer. The second microporous layer contains nickel and chromium and is disposed on the inner peripheral surface of the primary metal layer, the inner peripheral surface facing the hollow space of the skeleton.

A porous metal body including a skeleton having a three-dimensional mesh-like structure, the porous metal body having a plate-like overall shape. The skeleton has a hollow structure and includes a primary metal layer and at least one of a first microporous layer and a second microporous layer. The primary metal layer is composed of nickel or a nickel alloy. The first microporous layer contains nickel and chromium and is disposed on the outer peripheral surface of the primary metal layer. The second microporous layer contains nickel and chromium and is disposed on the inner peripheral surface of the primary metal layer, the inner peripheral surface facing the hollow space of the skeleton.