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Main Authors: Lin, Dajun, Chen, Xiaofeng, Dea, Connor O., Kim, Ji-Won, Mason, Keldy S., Lee, Kwong Sang, Majumder, Apratim, Chang, Chih-Hao, Cullinan, Michael, Page, Zachariah A., Menon, Rajesh
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.06614
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author Lin, Dajun
Chen, Xiaofeng
Dea, Connor O.
Kim, Ji-Won
Mason, Keldy S.
Lee, Kwong Sang
Majumder, Apratim
Chang, Chih-Hao
Cullinan, Michael
Page, Zachariah A.
Menon, Rajesh
author_facet Lin, Dajun
Chen, Xiaofeng
Dea, Connor O.
Kim, Ji-Won
Mason, Keldy S.
Lee, Kwong Sang
Majumder, Apratim
Chang, Chih-Hao
Cullinan, Michael
Page, Zachariah A.
Menon, Rajesh
contents Additive manufacturing using light is commonly constrained by serial voxel-by-voxel or layer-by-layer processing, which fundamentally limits fabrication speed and scalability. Here, we introduce a single-exposure holographic three-dimensional (3D) printing approach that synthesizes an entire volumetric dose distribution optically in one step. The method combines inverse-designed microstructured phase masks with photopolymer resins engineered for controlled optical absorption. By precisely tailoring the phase-mask topography, we generate arbitrary 3D light-intensity distributions within the resin, including intentionally encoded dark regions that define hollow internal features. Simultaneously, the resin formulation is designed to balance optical penetration with sufficient local energy deposition to achieve high-fidelity polymerization throughout the volume. Using this approach, millimeter-scale architectures comprising more than $10^{6}$ addressable voxels are fabricated in a single 7.5~s exposure, corresponding to a volumetric throughput of $\sim$1~mm$^{3}$/s ($>10^{5}$~voxels/s). The demonstrated performance is presently limited by resin kinetics and illumination geometry rather than by the phase-mask framework itself. Because the volumetric information capacity scales with the space--bandwidth product of the phase mask, this approach provides a clear pathway toward substantially higher throughput, enabling scalable fabrication of micro-optical components, biomedical scaffolds, and other precision-engineered mesoscale systems.
format Preprint
id arxiv_https___arxiv_org_abs_2601_06614
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Single-exposure holographic 3D printing via inverse-designed phase masks
Lin, Dajun
Chen, Xiaofeng
Dea, Connor O.
Kim, Ji-Won
Mason, Keldy S.
Lee, Kwong Sang
Majumder, Apratim
Chang, Chih-Hao
Cullinan, Michael
Page, Zachariah A.
Menon, Rajesh
Optics
Additive manufacturing using light is commonly constrained by serial voxel-by-voxel or layer-by-layer processing, which fundamentally limits fabrication speed and scalability. Here, we introduce a single-exposure holographic three-dimensional (3D) printing approach that synthesizes an entire volumetric dose distribution optically in one step. The method combines inverse-designed microstructured phase masks with photopolymer resins engineered for controlled optical absorption. By precisely tailoring the phase-mask topography, we generate arbitrary 3D light-intensity distributions within the resin, including intentionally encoded dark regions that define hollow internal features. Simultaneously, the resin formulation is designed to balance optical penetration with sufficient local energy deposition to achieve high-fidelity polymerization throughout the volume. Using this approach, millimeter-scale architectures comprising more than $10^{6}$ addressable voxels are fabricated in a single 7.5~s exposure, corresponding to a volumetric throughput of $\sim$1~mm$^{3}$/s ($>10^{5}$~voxels/s). The demonstrated performance is presently limited by resin kinetics and illumination geometry rather than by the phase-mask framework itself. Because the volumetric information capacity scales with the space--bandwidth product of the phase mask, this approach provides a clear pathway toward substantially higher throughput, enabling scalable fabrication of micro-optical components, biomedical scaffolds, and other precision-engineered mesoscale systems.
title Single-exposure holographic 3D printing via inverse-designed phase masks
topic Optics
url https://arxiv.org/abs/2601.06614