3D Printing of Compositional Gradients Using the Microfluidic Circuit Analogy

Nguyen, Du T.; Yee, Timothy D.; Dudukovic, Nikola A.; Sasan, Koroush; Jaycox, Adam W.; Golobic, Alexandra M.; Duoss, Eric B.; Dylla‐Spears, Rebecca

doi:10.1002/admt.201900784

Cited by 20 publications

(18 citation statements)

References 30 publications

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“…The nozzle was held in a fixed position, while the material was deposited onto a silicone sheet, which was clamped to a threeaxis motion positioning stage (Aerotech). Before each print, a calibration procedure was performed to quantify the flow characteristics of the system, which was then used to calculate the flow rates necessary to achieve a desired compositional profile for a given geometry, as described previously (39). Typical print speeds were 10 mm/s.…”

Section: Printingmentioning

confidence: 99%

“…On the other hand, the mixer design must also provide a rapid response to changes in the programmed ink composition, which necessitates a shorter residence time. However, the latter requirement can also be accounted for by implementing strategic compensation of the dispense rates into the toolpath (39). Hence, the micromixer used in this work was optimized for longer residence time to ensure complete mixing within the filament.…”

Section: Introductionmentioning

confidence: 99%

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3D printed gradient index glass optics

et al. 2020

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We demonstrate an additive manufacturing approach to produce gradient refractive index glass optics. Using direct ink writing with an active inline micromixer, we three-dimensionally print multimaterial green bodies with compositional gradients, consisting primarily of silica nanoparticles and varying concentrations of titania as the index-modifying dopant. The green bodies are then consolidated into glass and polished, resulting in optics with tailored spatial profiles of the refractive index. We show that this approach can be used to achieve a variety of conventional and unconventional optical functions in a flat glass component with no surface curvature.

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Section: Printingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

3D printed gradient index glass optics

et al. 2020

Self Cite

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“…However, local compositional changes in the matrix as well as local density patterns are still difficult to produce with single‐nozzle DIW printing since they require in situ mixing of materials with different viscoelastic responses. [ 11 ] Such features might be achieved via multimaterial 3D printing approaches, [ 12 ] but these are usually time consuming due to the complexity of manufacturing and require careful selection of compatible materials. Indeed, multimaterial printing often introduces incoherent interfaces with abrupt changes of elastic modulus between materials to the manufactured composites, hence leading to stress concentration sites and defects that weaken the printed structure.…”

Section: Introductionmentioning

confidence: 99%

Mechanical Properties Tailoring of 3D Printed Photoresponsive Nanocellulose Composites

Müller

Zimmermann

Nyström

et al. 2020

Adv Funct Materials

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3D printing technologies allow control over the alignment of building blocks in synthetic materials, but compositional changes often require complex multimaterial printing steps. Here, 3D printable materials showing locally tunable mechanical properties are produced in a single printing step of Direct Ink Writing. These new inks consist of a polymer matrix bearing biocompatible photoreactive cinnamate derivatives and up to 30 wt% of anisotropic cellulose nanocrystals. The printed materials are mechanically versatile and can undergo further crosslinking upon illumination. When illuminating the material and controlling the irradiation doses, the Young's moduli can be adjusted between 15 and 75 MPa. Moreover, spatially controlled illumination allows patterning stiff geometries, resulting in 3D printed structures with segments of different mechanical properties tailoring the mechanical behavior under compression. The high design freedom implemented by 3D printing and photopatternability opens the venue to rapid manufacturing of devices for applications such as prosthetics or soft robotics where the 3D shapes and mechanical properties must be tailored for personalized load cases.

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“…[ 2 ] Structural components different from the extruded polymer are conventionally introduced directly as a mixture within the extruded polymer via the incorporation of particles, fibers, or nanoparticles to improve structural stability. In particular by use of photopolymerization a large plethora of different and highly complex structures have been addressed such as the 3D printing of compositional gradients for microfluidics, [ 3 ] 3D printing of ionogels for stretchable sensors, [ 4 ] shape‐deformable hydrogels, [ 5 ] or specific methodological developments such as the removal of overhanging structures without the need for supportive materials. [ 6 ] There is also ample application of 3D printing in the areas of energy materials (thin film solar cell technology, super capacitors, multilayered systems), where many different components (solids and liquids) are required to be printed into one and the same material.…”

Section: Introductionmentioning

confidence: 99%

3D Printing of Core–Shell Capsule Composites for Post‐Reactive and Damage Sensing Applications

Rupp

Binder

2020

Adv Materials Technologies

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3D printing of multicomponent materials as an advantageous method over traditional mold casting methods is demonstrated, developing small core–shell capsule composites fabricated by a two‐step 3D printing process. Using a two‐print‐head system (fused deposition modeling extruder and a liquid inkjet print head), micro‐sized capsules are manufactured in sizes ranging from 100 to 800 µm. The thermoplastic polymer poly(ε‐caprolactone) (PCL) is chosen as matrix/shell material due to its optimal interaction with the embedded hydrophobic liquids. First, the core–shell capsules are printed with model liquids and pure PCL to optimize the printing parameters and to ensure fully enclosed capsules inside the polymer. As a proof of concept, novel “click” reaction systems, used in self‐healing and stress‐detection applications, are manufactured in which PCL composites with nano‐ and micro‐fillers are combined with reactive, encapsulated liquids. The so generated 3D printed core–shell capsule composite can be used for post‐printing reactions and damage sensing when combined with a fluorogenic dye.

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3D Printing of Compositional Gradients Using the Microfluidic Circuit Analogy

Cited by 20 publications

References 30 publications

3D printed gradient index glass optics

3D printed gradient index glass optics

Mechanical Properties Tailoring of 3D Printed Photoresponsive Nanocellulose Composites

3D Printing of Core–Shell Capsule Composites for Post‐Reactive and Damage Sensing Applications

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