Abstract: An assembly and method to precisely and concurrently control the concentration, release, and depletion of chemical and biochemical species in localized regions in a three-dimensional volume of material using spatially patterned light. The system includes a container for holding a material comprising photo-responsive substance; the container is mounted to a motorized rotation stage that rotates the container along the z-axis at a predetermined rate; and a projector configured to project radiations at predefined wavelengths along an r-axis into the container while the container is rotating, wherein the radiations from multiple angles intersect to form localized photoreactive regions within a volume of the material.

Abstract: A system for determining a light intensity field for use in manufacturing a 3D object from a volume of material. The system receives a 3D specification of a 3D geometry for the 3D object that specifies voxels within the volume that contain material that is to be part of the 3D object. The system employs a cost function for effectiveness of a light intensity field in manufacturing the 3D object. The cost function may be an adjoint of an Attenuated Radon Transform that models an energy dose that each voxel would receive during manufacture of the 3D object using the light intensity field. The system applies an optimization technique that employs the cost function to generate a measure of the effectiveness of possible light intensity fields and outputs an indication of a light intensity field that will be effective in manufacturing the 3D object.

Abstract: An assembly and method to precisely and concurrently control the concentration, release, and depletion of chemical and biochemical species in localized regions in a three-dimensional volume of material using spatially patterned light. The system includes a container for holding a material comprising photo-responsive substance; the container is mounted to a motorized rotation stage that rotates the container along the z-axis at a predetermined rate; and a projector configured to project radiations at predefined wavelengths along an r-axis into the container while the container is rotating, wherein the radiations from multiple angles intersect to form localized photoreactive regions within a volume of the material.

Abstract: Methods and materials for volumetric additive manufacturing, including computed axial lithography (“CAL”), using photosensitive resins comprising a photocurable resin prepolymer; a photoinitiator; and (optionally) a curing inhibitor. In various embodiments, such photosensitive polymers comprise (a) one or more monomer (or prepolymer) molecules, which form the backbone of the polymer network of the polymeric material and define its architecture; and (b) a photoinitiator that captures illumination energy and initiates polymerization.

Abstract: Provided herein is a system for producing a product. The system generally comprises a large-area micro-stereolithography system and a layer leveling system. The large-area micro-stereolithography system is capable of generating the product by optically polymerizing successive layers of a curable resin at a print plane. The layer leveling system is capable of flattening a non-flat region (such as a meniscus) of the curable resin in a vicinity of the build plane.

Abstract: A system for determining a light intensity field for use in manufacturing a 3D object from a volume of material. The system receives a 3D specification of a 3D geometry for the 3D object that specifies voxels within the volume that contain material that is to be part of the 3D object. The system employs a cost function for effectiveness of a light intensity field in manufacturing the 3D object. The cost function may be an adjoint of an Attenuated Radon Transform that models an energy dose that each voxel would receive during manufacture of the 3D object using the light intensity field. The system applies an optimization technique that employs the cost function to generate a measure of the effectiveness of possible light intensity fields and outputs an indication of a light intensity field that will be effective in manufacturing the 3D object.

Abstract: Methods and materials for volumetric additive manufacturing, including computed axial lithography (“CAL”), using photosensitive resins comprising a photocurable resin prepolymer; a photoinitiator; and (optionally) a curing inhibitor. In various embodiments, such photosensitive polymers comprise (a) one or more monomer (or prepolymer) molecules, which form the backbone of the polymer network of the polymeric material and define its architecture; and (b) a photoinitiator that captures illumination energy and initiates polymerization.