Difference between revisions of "Published Papers"
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== '''Research Papers''' Citing [[Cold_and_Warm_Flow|Hyrel Cold Flow]] == | == '''Research Papers''' Citing [[Cold_and_Warm_Flow|Hyrel Cold Flow]] == | ||
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| + | === 2018 ==== | ||
* [https://ieeexplore.ieee.org/abstract/document/8329484/?reload=true UV-curable Ferrite Paste for Additive Manufacturing of Power Magnetics] by a team from [http://vt.edu Virginia Tech] | * [https://ieeexplore.ieee.org/abstract/document/8329484/?reload=true UV-curable Ferrite Paste for Additive Manufacturing of Power Magnetics] by a team from [http://vt.edu Virginia Tech] | ||
* [https://pubs.acs.org/doi/abs/10.1021/acs.jpcc.8b00580 Tailoring the Porosity and Microstructure of Printed Graphene Electrodes via Polymer Phase Inversion] by a team from [http://northwestern.edu Northwestern University] | * [https://pubs.acs.org/doi/abs/10.1021/acs.jpcc.8b00580 Tailoring the Porosity and Microstructure of Printed Graphene Electrodes via Polymer Phase Inversion] by a team from [http://northwestern.edu Northwestern University] | ||
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| + | ==== 2017 ==== | ||
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* [https://static1.squarespace.com/static/59581b474c8b03b8a580b4ae/t/5a5c280bec212d764ffc3203/1515989014007/Bioink+Paper.pdf Injectable Nanocomposite Hydrogels for Cell Delivery and Bioprinting] by a team by a team from three disciplines of [http://www.tamu.edu/ Texas A&M University]. | * [https://static1.squarespace.com/static/59581b474c8b03b8a580b4ae/t/5a5c280bec212d764ffc3203/1515989014007/Bioink+Paper.pdf Injectable Nanocomposite Hydrogels for Cell Delivery and Bioprinting] by a team by a team from three disciplines of [http://www.tamu.edu/ Texas A&M University]. | ||
* [https://www.researchgate.net/profile/Manik_Chandra_Biswas2/publication/317318891_Feasibility_of_Printing_3D_Bone_Models_for_Education_at_TUCVM/links/5931e797aca272fc55093f49/Feasibility-of-Printing-3D-Bone-Models-for-Education-at-TUCVM.pdf Feasibility of Printing 3D Bone Models for Education at TUCVM] at [https://www.researchgate.net/ ResearchGate] | * [https://www.researchgate.net/profile/Manik_Chandra_Biswas2/publication/317318891_Feasibility_of_Printing_3D_Bone_Models_for_Education_at_TUCVM/links/5931e797aca272fc55093f49/Feasibility-of-Printing-3D-Bone-Models-for-Education-at-TUCVM.pdf Feasibility of Printing 3D Bone Models for Education at TUCVM] at [https://www.researchgate.net/ ResearchGate] | ||
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*[http://iopscience.iop.org/article/10.1088/1758-5090/aa7077/meta Fabrication of Biomimetic Bone Grafts with Multi-Material 3D Printing] by Nicholas Sears et. al., of the [https://engineering.tamu.edu/biomedical Biomedical Engineering Department] of [http://www.tamu.edu/ Texas A&M University]. | *[http://iopscience.iop.org/article/10.1088/1758-5090/aa7077/meta Fabrication of Biomimetic Bone Grafts with Multi-Material 3D Printing] by Nicholas Sears et. al., of the [https://engineering.tamu.edu/biomedical Biomedical Engineering Department] of [http://www.tamu.edu/ Texas A&M University]. | ||
*[http://hyrel3d.net/papers/Tuskegee_Eggshell.pdf Nanoengineered Eggshell–Silver Tailored Copolyester Polymer Blend Film with Antimicrobial Properties] by the [http://www.tuskegee.edu/academics/colleges/ceps/ceps_special_programs/phd_program_in_materials_science_engineering.aspx Department of Materials Science and Engineering] and the Department of Pathobiology, [http://www.tuskegee.edu/academics/colleges/cvmnah/school_of_veterinary_medicine.aspx College of Veterinary Medicine] of [http://www.tuskegee.edu Tuskegee University] | *[http://hyrel3d.net/papers/Tuskegee_Eggshell.pdf Nanoengineered Eggshell–Silver Tailored Copolyester Polymer Blend Film with Antimicrobial Properties] by the [http://www.tuskegee.edu/academics/colleges/ceps/ceps_special_programs/phd_program_in_materials_science_engineering.aspx Department of Materials Science and Engineering] and the Department of Pathobiology, [http://www.tuskegee.edu/academics/colleges/cvmnah/school_of_veterinary_medicine.aspx College of Veterinary Medicine] of [http://www.tuskegee.edu Tuskegee University] | ||
| + | *[http://hyrel3d.net/papers/Design_Meth_Additive_Mfg_Magnetic_Comp_YYan_2017.pdf Design Methodology and Materials for Additive Manufacturing of Magnetic Components] - PhD Thesis of Y. Yan, [http://vt.edu Virginia Tech] | ||
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| + | ==== 2016 ==== | ||
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*[http://www.ieeeconfpublishing.org/cpir/UploadedFiles/Additive%20Manufacturing%20of%20Magnetic%20Components%20for%20Heterogeneous%20Integration.pdf Additive Manufacturing of Magnetic Components for Heterogeneous Integration] by Dr. Y. Yan (and others), [http://vt.edu Virginia Tech] | *[http://www.ieeeconfpublishing.org/cpir/UploadedFiles/Additive%20Manufacturing%20of%20Magnetic%20Components%20for%20Heterogeneous%20Integration.pdf Additive Manufacturing of Magnetic Components for Heterogeneous Integration] by Dr. Y. Yan (and others), [http://vt.edu Virginia Tech] | ||
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*[http://hyrel3d.net/papers/Sydney_Bioprinting_Presentation.pptx Bioprinting Defined Heterogeneous Cellular Microenvironments] from [http://sydney.edu.au/engineering/research/centres/biomaterials-tissue-engineering/ The Biomaterials and Tissue Engineering Research Unit] of the [http://web.aeromech.usyd.edu.au/index.php Aerospace, Mechanical and Mechatronic Engineering Department] of [http://sydney.edu.au The University of Sydney] | *[http://hyrel3d.net/papers/Sydney_Bioprinting_Presentation.pptx Bioprinting Defined Heterogeneous Cellular Microenvironments] from [http://sydney.edu.au/engineering/research/centres/biomaterials-tissue-engineering/ The Biomaterials and Tissue Engineering Research Unit] of the [http://web.aeromech.usyd.edu.au/index.php Aerospace, Mechanical and Mechatronic Engineering Department] of [http://sydney.edu.au The University of Sydney] | ||
*[http://hyrel3d.net/papers/3D-4D_Printing_and_Stretchable_Conductive_Adhesives.pdf A Novel Approach to Integrating 3D/4D Printing and Stretchable Conductive Adhesive Technologies for High Frequency Packaging Applications] | *[http://hyrel3d.net/papers/3D-4D_Printing_and_Stretchable_Conductive_Adhesives.pdf A Novel Approach to Integrating 3D/4D Printing and Stretchable Conductive Adhesive Technologies for High Frequency Packaging Applications] | ||
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*[http://hyrel3d.net/papers/3D_Printed_Scaffolds_to_Repair_Large_Bone_Deficits.pdf Design and Fabrication of 3D Printed Scaffolds with a Mechanical Strength Comparable to Cortical Bone to Repair Large Bone Defects] in [http://www.nature.com/index.html Nature.com's] [http://www.nature.com/srep/ Scientific Reports] | *[http://hyrel3d.net/papers/3D_Printed_Scaffolds_to_Repair_Large_Bone_Deficits.pdf Design and Fabrication of 3D Printed Scaffolds with a Mechanical Strength Comparable to Cortical Bone to Repair Large Bone Defects] in [http://www.nature.com/index.html Nature.com's] [http://www.nature.com/srep/ Scientific Reports] | ||
*[http://hyrel3d.net/papers/Eumlsion_Inks_for_3D_Printing.pdf Emulsion Inks for 3D Printing of High Porosity Materials] in the [http://www.frontiersin.org/10.3389/conf.FBIOE.2016.01.02721/2893/10th_World_Biomaterials_Congress/all_events/event_abstract Macromolecular Journals] | *[http://hyrel3d.net/papers/Eumlsion_Inks_for_3D_Printing.pdf Emulsion Inks for 3D Printing of High Porosity Materials] in the [http://www.frontiersin.org/10.3389/conf.FBIOE.2016.01.02721/2893/10th_World_Biomaterials_Congress/all_events/event_abstract Macromolecular Journals] | ||
| − | * 2015 | + | *[https://www.dst.defence.gov.au/sites/default/files/events/documents/WCSD%20Presentation.pdf 3D Printed Energetics] by the [https://www.dst.defence.gov.au/research-division/weapons-and-combat-systems-division Weapons and Combat Systems Division] of the [http://defence.gov.au Australian Department of Defense] |
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| + | ==== 2015==== | ||
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| + | *[http://c.ymcdn.com/sites/www.surfaces.org/resource/collection/4423FA75-D640-4955-A412-240A38EF1FAA/2015_Elizabeth_Cosgriffpdf.pdf 3D Printing of High Porosity, Biodegradable Foams with Cure on Dispense] - Presentation by Elizabeth Cosgriff-Hernández of [https://engineering.tamu.edu/biomedical Department of Biomedical Engineering], [http://www.tamu.edu Texas A&M University] | ||
| + | *[https://www.biomaterials.org/sites/default/files/docs/2015/graduate_abstracts.pdf Graduate Abstract: Dynamic increase in matrix stiffness promotes invasive tumor phenotype in vivo] from multiple organizations, at [https://www.biomaterials.org BioMaterials.org] | ||
| + | *[https://www.mpif.org/cpmt/studentprojects/Scholar_work_2015-02.pdf Die-Less MIM-style Additive Manufacturing with Controlled Porosity: A Proof of Concept] by the [http://www.lehigh.edu/matsci/ Department of Materials Science and Engineering] of [http://www1.lehigh.edu/home Lehigh University] | ||
*[http://pubs.acs.org/doi/abs/10.1021/nn507488s Bioactive Nanoengineered Hydrogels for Bone Tissue Engineering: A Growth-Factor-Free Approach] in [http://www.acs.org/content/acs/en.html The American Chemical Society's] [http://pubs.acs.org/journal/ancac3 ACS Nano] | *[http://pubs.acs.org/doi/abs/10.1021/nn507488s Bioactive Nanoengineered Hydrogels for Bone Tissue Engineering: A Growth-Factor-Free Approach] in [http://www.acs.org/content/acs/en.html The American Chemical Society's] [http://pubs.acs.org/journal/ancac3 ACS Nano] | ||
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| + | ==== 2014 ==== | ||
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| + | *[http://www.anzors.org.au/pdfs/2014-proceedings.pdf Development of 3D printed Ceramic scaffolds for Treatment of Segmental Bone Defects] from [http://sydney.edu.au/engineering/research/centres/biomaterials-tissue-engineering/ The Biomaterials and Tissue Engineering Research Unit] of the [http://web.aeromech.usyd.edu.au/index.php Aerospace, Mechanical and Mechatronic Engineering Department] of [http://sydney.edu.au The University of Sydney] | ||
=== '''Research Video''' Citing [[Cold_and_Warm_Flow|Hyrel Cold Flow]] === | === '''Research Video''' Citing [[Cold_and_Warm_Flow|Hyrel Cold Flow]] === | ||
Revision as of 13:12, 10 April 2018
Below is a list of research works citing Hyrel equipment.
Contents
Research Papers Citing Hyrel Cold Flow
2018 =
- UV-curable Ferrite Paste for Additive Manufacturing of Power Magnetics by a team from Virginia Tech
- Tailoring the Porosity and Microstructure of Printed Graphene Electrodes via Polymer Phase Inversion by a team from Northwestern University
2017
- Injectable Nanocomposite Hydrogels for Cell Delivery and Bioprinting by a team by a team from three disciplines of Texas A&M University.
- Feasibility of Printing 3D Bone Models for Education at TUCVM at ResearchGate
- Design and Additive Manufacturing of Multi-Permeability Magnetic Cores, in 2017 IEEE Energy Conversion Congress and Exposition (ECCE)
- Combustion-Assisted Photonic Annealing of Printable Graphene Inks via Exothermic Binders, by a team from Northwestern Univeristy
- In Vitro Evaluation of 3D Bbioprinted Tri-Polymer Network Scaffolds for Bone Tissue Regeneration, by Stephanie Bendtsen and Mei Wei, in The Journal of Biomedical Materials Research Part A
- Self-Actuating 3D Printed Packaging for Deployable Antennas, The Institute of Electrical and Electronics Engineers, Incorporated (IEEE)
- Enabling Process Intensification via 3D Printing of Catalytic Structures by Muxina Konarova (and others), University of Queensland
- 3D Bioprinting for Musculoskeletal Applications by Alexander Popov, Sara Malferrari, & Deepak M Kalaskar in Future Medicine
- UV-assisted 3D-printing of Soft Ferrite Magnetic Components for Power Electronics Integration by Dr. Y. Yan (and others), Virginia Tech
- Alginate Hydrogels for Bone Tissue Regeneration by Stephanie T. Bendtsen of The University of Connecticut
- Fabrication of Biomimetic Bone Grafts with Multi-Material 3D Printing by Nicholas Sears et. al., of the Biomedical Engineering Department of Texas A&M University.
- Nanoengineered Eggshell–Silver Tailored Copolyester Polymer Blend Film with Antimicrobial Properties by the Department of Materials Science and Engineering and the Department of Pathobiology, College of Veterinary Medicine of Tuskegee University
- Design Methodology and Materials for Additive Manufacturing of Magnetic Components - PhD Thesis of Y. Yan, Virginia Tech
2016
- Additive Manufacturing of Magnetic Components for Heterogeneous Integration by Dr. Y. Yan (and others), Virginia Tech
- Bioprinting Defined Heterogeneous Cellular Microenvironments from The Biomaterials and Tissue Engineering Research Unit of the Aerospace, Mechanical and Mechatronic Engineering Department of The University of Sydney
- A Novel Approach to Integrating 3D/4D Printing and Stretchable Conductive Adhesive Technologies for High Frequency Packaging Applications
- Additive Manufacturing of Planar Inductor for Power Electronics Applications
- Design and Fabrication of 3D Printed Scaffolds with a Mechanical Strength Comparable to Cortical Bone to Repair Large Bone Defects in Nature.com's Scientific Reports
- Emulsion Inks for 3D Printing of High Porosity Materials in the Macromolecular Journals
- 3D Printed Energetics by the Weapons and Combat Systems Division of the Australian Department of Defense
2015
- 3D Printing of High Porosity, Biodegradable Foams with Cure on Dispense - Presentation by Elizabeth Cosgriff-Hernández of Department of Biomedical Engineering, Texas A&M University
- Graduate Abstract: Dynamic increase in matrix stiffness promotes invasive tumor phenotype in vivo from multiple organizations, at BioMaterials.org
- Die-Less MIM-style Additive Manufacturing with Controlled Porosity: A Proof of Concept by the Department of Materials Science and Engineering of Lehigh University
- Bioactive Nanoengineered Hydrogels for Bone Tissue Engineering: A Growth-Factor-Free Approach in The American Chemical Society's ACS Nano
2014
- Development of 3D printed Ceramic scaffolds for Treatment of Segmental Bone Defects from The Biomaterials and Tissue Engineering Research Unit of the Aerospace, Mechanical and Mechatronic Engineering Department of The University of Sydney
Research Video Citing Hyrel Cold Flow
Research Papers Citing Hyrel Warm Flow
- Shear-Thinning and Thermo-Reversible Nanoengineered Inks for 3D Bioprinting in the American Chemical Society's Applied Materials & Interfaces Journal
- Nanoengineered Colloidal Inks for 3D Bioprinting in The American Chemical Society's Langmuir
- 4D Printing of Liquid Crystal Elastomers in the American Chemical Society's Applied Materials & Interfaces Journal
- Influence of Shear Thinning and Material Flow on Robotic Dispensing of PEG in The American Chemical Society's ACS Nano
Research Papers Citing Hyrel Hot Flow
- Pharmaceutical 3D Printing: Design and Qualification of a Single Step Print and Fill Capsule by a team from Merck Pharmaceuticals
- Fabrication and Properties of Novel Polymer-Metal Composites using Fused Deposition Modeling by the Mechanical Engineering Staff at Worcester Polytechnic Institute
- NANOSATC-BR2, 2 unit CUBESAT, Power Analysis, Solar Flux Prediction, Design and 3D Printing of the Flight Model from the UFSM & INPE’S NANOSATC-BR, CUBESAT Development Program by a team from the Federal University of Santa Maria (UFSM), Brasil.
- A Preliminary Study of Conductive Filaments Printed Via Fused Filament Fabrication by Smruti Ranjan Sahoo at Rochester Institute of Technology
- Tensile Mechanical Properties of Polypropylene Composites Fabricated by Material Extrusion, a reviewed paper of the Solid Freeform Fabrication Symposium 2017.
- Effect of Process Parameters and Shot Peening on Mechanical Behavior of ABS Parts Manufactured by Fused Filament Fabrication (FFF), a reviewed paper of the Solid Freeform Fabrication Symposium 2017.
- Hybrid Processes in Additive Manufacturing in the Journal of Manufacturing Science and Engineering of the American Society of Mechanical Engineers
- Effects of Material Properties on Warpage in Fused Deposition Modeling Parts in The International Journal of Advanced Manufacturing Technology
- Thermal and Mechanical Properties of 3D Printed Boron Nitride – ABS Composites, in Applied Composite Materials
- Review of Batteryless Wireless Sensors Using Additively Manufactured Microwave Resonators in Sensors, a Journal of the Multidisciplinary Digital Publishing Institute
- Self-Actuating 3D Printed Packaging for Deployable Antennas, The Institute of Electrical and Electronics Engineers, Incorporated (IEEE)
- Dynamical Majorana edge modes in a broad class of topological mechanical systems by The New Jersey Institute of Technology
- A Low-Cost, Single Platform, Hybrid Manufacturing System for RF Passives, The Institute of Electrical and Electronics Engineers, Incorporated (IEEE)
- Button-Shaped RFID Tag Combining Three-Dimensional and Inkjet Printing Technologies, The IET Digital Library.
- Demonstration and Characterization of Fully 3D-printed RF Structures, The Institute of Electrical and Electronics Engineers, Incorporated (IEEE)
- Infill Dependent 3D-Printed Material Based on NinjaFlex Filament for Antenna Applications, The Institute of Electrical and Electronics Engineers, Incorporated (IEEE)
- A Novel Strain Sensor Based on 3D Printing Technology and 3D Antenna Design, The Institute of Electrical and Electronics Engineers, Incorporated (IEEE)
- A Novel 3-D Printed Loop Antenna Using Flexible NinjaFlex Material for Wearable and IoT Applications, The Institute of Electrical and Electronics Engineers, Incorporated (IEEE)
- RF Characterization of 3D Printed Flexible Materials - NinjaFlex Filaments, The European Microwave Association (EuMA)
- Nano-Material Based Flexible Radio Frequency Sensors for Wearable Health and Environment Monitoring: Designs and Prototypes Utilizing 3D/Inkjet Printing Technologies, A Dissertation Presented to The Academic Faculty of The School of Electrical and Computer Engineering at Georgia Tech
