Literatura académica sobre el tema "3D conductive polymer"
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Artículos de revistas sobre el tema "3D conductive polymer"
Cai, Zewei, Naveen Thirunavukkarasu, Xuefeng Diao, Haoran Wang, Lixin Wu, Chen Zhang y Jianlei Wang. "Progress of Polymer-Based Thermally Conductive Materials by Fused Filament Fabrication: A Comprehensive Review". Polymers 14, n.º 20 (13 de octubre de 2022): 4297. http://dx.doi.org/10.3390/polym14204297.
Texto completoEutionnat-Diffo, Prisca Aude, Aurélie Cayla, Yan Chen, Jinping Guan, Vincent Nierstrasz y Christine Campagne. "Development of Flexible and Conductive Immiscible Thermoplastic/Elastomer Monofilament for Smart Textiles Applications Using 3D Printing". Polymers 12, n.º 10 (8 de octubre de 2020): 2300. http://dx.doi.org/10.3390/polym12102300.
Texto completoZhang, Xiao, Jian Zheng, Yong Qiang Du y Chun Ming Zhang. "Three-Dimensional Graphite Filled Poly(Vinylidene Fluoride) Composites with Enhanced Strength and Thermal Conductivity". Key Engineering Materials 842 (mayo de 2020): 63–68. http://dx.doi.org/10.4028/www.scientific.net/kem.842.63.
Texto completoYurduseven, Okan, Shengrong Ye, Thomas Fromenteze, Benjamin J. Wiley y David R. Smith. "3D Conductive Polymer Printed Metasurface Antenna for Fresnel Focusing". Designs 3, n.º 3 (4 de septiembre de 2019): 46. http://dx.doi.org/10.3390/designs3030046.
Texto completoNakagawa, Yoshitaka, Hiroyuki Kageyama, Riho Matsumoto, Yuya Oaki y Hiroaki Imai. "Conductive polymer-mediated 2D and 3D arrays of Mn3O4 nanoblocks and mesoporous conductive polymers as their replicas". Nanoscale 7, n.º 44 (2015): 18471–76. http://dx.doi.org/10.1039/c5nr05912g.
Texto completoPark, Bumjun, Christiana Oh, Sooyoun Yu, Bingxin Yang, Nosang V. Myung, Paul W. Bohn y Jennifer L. Schaefer. "Coupling of 3D Porous Hosts for Li Metal Battery Anodes with Viscous Polymer Electrolytes". Journal of The Electrochemical Society 169, n.º 1 (1 de enero de 2022): 010511. http://dx.doi.org/10.1149/1945-7111/ac47ea.
Texto completoMarasso, Simone Luigi, Matteo Cocuzza, Valentina Bertana, Francesco Perrucci, Alessio Tommasi, Sergio Ferrero, Luciano Scaltrito y Candido Fabrizio Pirri. "PLA conductive filament for 3D printed smart sensing applications". Rapid Prototyping Journal 24, n.º 4 (14 de mayo de 2018): 739–43. http://dx.doi.org/10.1108/rpj-09-2016-0150.
Texto completoEutionnat-Diffo, Prisca Aude, Yan Chen, Jinping Guan, Aurelie Cayla, Christine Campagne y Vincent Nierstrasz. "Study of the Wear Resistance of Conductive Poly Lactic Acid Monofilament 3D Printed onto Polyethylene Terephthalate Woven Materials". Materials 13, n.º 10 (19 de mayo de 2020): 2334. http://dx.doi.org/10.3390/ma13102334.
Texto completoPrasopthum, Aruna, Zexing Deng, Ilyas M. Khan, Zhanhai Yin, Baolin Guo y Jing Yang. "Three dimensional printed degradable and conductive polymer scaffolds promote chondrogenic differentiation of chondroprogenitor cells". Biomaterials Science 8, n.º 15 (2020): 4287–98. http://dx.doi.org/10.1039/d0bm00621a.
Texto completoKrzeminski, Jakub, Bartosz Blicharz, Andrzej Skalski, Grzegorz Wroblewski, Małgorzata Jakubowska y Marcin Sloma. "Photonic curing of silver paths on 3D printed polymer substrate". Circuit World 45, n.º 1 (4 de febrero de 2019): 9–14. http://dx.doi.org/10.1108/cw-11-2018-0084.
Texto completoTesis sobre el tema "3D conductive polymer"
SCORDO, GIORGIO. "A novel electrical conductive resin for stereolithographic 3D printing". Doctoral thesis, Politecnico di Torino, 2021. http://hdl.handle.net/11583/2899751.
Texto completoBertolini, Mayara Cristina. "Flexible and 3D printable conductive composites for pressure sensor applications". Doctoral thesis, Università degli studi di Trento, 2022. https://hdl.handle.net/11572/360281.
Texto completoThe aim of this study was the development of flexible and highly electrically conductive polymer composites via compression molding and fused filament fabrication for possible applications as piezoresistive or piezoelectric materials for pressure sensors. Composites based on blends of poly(vinylidene fluoride)/thermoplastic polyurethane (PVDF/TPU) as matrix and containing various fractions of carbon black-polypyrrole (CB-PPy) as conductive filler were prepared. Several characterization techniques were performed in order to evaluate the mechanical, thermal, chemical and electrical properties, morphology and printability of the investigated materials. First, PVDF/TPU blends with different compositions were prepared by melt compounding followed by compression molding. The results showed that the flexibility aimed for the final materials was improved with the addition of TPU to PVDF composites. SEM images evidenced the achievement of a co-continuous blend comprising 50/50 vol% of PVDF/TPU. The blends composed of PVDF/TPU 38/62 vol% and the co-continuous blend of PVDF/TPU 50/50 vol% were selected as matrices for the preparation of compression molded and 3D printed composites in order to achieve an optimal compromise between electrical conductivity, mechanical properties and printability. Various amounts of carbon black-polypyrrole, from 0 up to 15%, were added to the selected blends in order to rise the electrical conductivity of the composites and to possible act as nucleating filler for the β crystalline phase of PVDF in order to increase its piezoelectric response. The addition of CB-PPy increased the electrical conductivity of all composites. However, the electrical conductivity of composites based on PVDF/TPU 50/50 vol% co-continuous blends was higher than those found for PVDF/TPU 38/62 vol% composites at the same filler content. Indeed, the electrical percolation threshold of the conductive co-continuous composite blends was 2%, while the electrical percolation threshold of the composites with the nonco-continuous composite blends was 5%. With respect to the mechanical properties, the incorporation of the filler into the blends leaded to more rigid materials with higher elastic modulus, lower elongation at break and higher storage modulus. The storage modulus (G’) and complex viscosity (η*) of the composites increased with the addition of CB-PPy. The rheological percolation threshold was found to be 3% for PVDF/TPU/CB-PPy 38/62 vol% and 1% for PVDF/TPU/CB-PPy 50/50 vol%, indicating that higher amount of filler could compromise the processability of the composites. The addition of CB-PPy also resulted in a reduction on the Tg and Tm values of the composites due to the reduction of the mobility of the polymeric chains. Based on the electrical conductivity and mechanical behavior of the composites, three different compositions were selected for the extrusion of filaments to be used in a 3D printing process. Overall, the 3D printed parts presented lower mechanical and electrical properties because of the presence of voids, defects and overlapping layers that can hinder the flow of electrons. The electrical conductivity values of PVDF/TPU/CB-PPy 38/62 vol% composites containing 5% and 6 wt% of CB-PPy 3D printed samples are one to seven orders of magnitude lower than those found for compression molded composites with the same composition. Even if the electrical conductivity value for PVDF/TPU 38/62 vol% compression molded composite with 6% of CB-PPy was as high as 1.94x10-1 S•m-1, the 3D printed composite with same composition showed a very low electrical conductivity of 6.01x10-8 S•m-1. On the other hand, the 3D printed co-continuous composite PVDF/TPU 50/50 vol% with 10% of filler displayed a high value of electrical conductivity of 4.14×100 S•m-1 even after the printing process. Moreover, the piezoresistive responses of the composites were investigated. For PVDF/TPU/CB-PPy 38/62 vol% composites, the compression molded and 3D printed samples with 5% and 6% of CB-PPy exhibited good piezoresistive response. However, only the composites with 6% displayed high sensitivity and gauge factor values, large pressure range and reproducible piezoresistive responses under 100 cycles for both methods. On the other hand, for PVDF/TPU/CB-PPy co-continuous composites only the compression molded sample with 5% of CB-PPy presented good and reproducible piezoresistive responses. The crystallinity and β phase content of PVDF were investigated for the composites. Althought the degree of crystallinity of the samples decreased with the addition of CB-PPy, the percentage of β phase in PVDF was increased. The piezoelectric coefficient d33 of the samples increased with the percentage of β phase. The addition of 6% or more of CB-PPy was necessary to increase significatively the piezoelectric coefficient (d33) of the composites. The β phase content and piezoelectric responses of PVDF were lower for samples prepared by FFF. Finally, as a collateral research, the electromagnetic interference shielding effectiveness (EMI-SE) were measured for all composites. Composites with higher electrical conductivity showed better shielding of the electromagnetic radiation. In addition, composites based on the co-continuous blend displayed higher EMI shielding efficiency than 38/62 vol% composites. The main mechanism of shielding was absorption for all composites. Specimens prepared by FFF displayed diminished EMI-SE responses when compared to compression molded samples.
Lo scopo di questo studio è lo sviluppo di compositi polimerici flessibili e ad elevata conducibilità elettrica tramite stampaggio a compressione e manifattura additiva (fused filament fabrication) per possibili applicazioni come materiali piezoresistivi o piezoelettrici in sensori di pressione. In particolare, sono stati preparati compositi a base di miscele di poli(vinilidene fluoruro)/poliuretano termoplastico (PVDF/TPU) come matrice e contenenti varie frazioni di nerofumo-polipirrolo (CB-PPy) come riempitivo conduttivo. Sono state utilizzate diverse tecniche di caratterizzazione al fine di valutare le proprietà meccaniche, termiche, chimiche ed elettriche, la morfologia e la stampabilità dei materiali ottenuti. In primo luogo, miscele PVDF/TPU con diverse composizioni sono state preparate mediante mescolatura allo stato fuso seguita da stampaggio a compressione. I risultati hanno mostrato che la flessibilità del PVDF viene notevolemente migliorata dall’aggiunta di TPU. Le immagini SEM hanno evidenziato il raggiungimento di una miscela co-continua per una composizione 50/50% in volume di PVDF/TPU. Le miscele composte da PVDF/TPU 38/62 vol% e la miscela co-continua di PVDF/TPU 50/50 vol% sono state selezionate come matrici per la preparazione di compositi per stampaggio a compressione e manifattura additiva al fine di ottenere un compromesso ottimale tra conducibilità, proprietà meccaniche e stampabilità. Alle miscele selezionate sono state aggiunte varie quantità di nerofumo-polipirrolo, dallo 0 al 15%, per aumentare la conducibilità elettrica dei compositi ed eventualmente fungere da additivo nucleante per la fase β cristallina del PVDF al fine di aumentarne la risposta piezoelettrica. L'aggiunta di CB-PPy ha aumentato la conduttività elettrica di tutti i compositi. Tuttavia, la conduttività elettrica dei compositi basati su miscele co-continue di PVDF/TPU 50/50% in volume era superiore a quella trovata per compositi PVDF/TPU 38/62% in volume con lo stesso contenuto di riempitivo. Infatti, la soglia di percolazione elettrica delle miscele conduttive era del 2%, mentre la soglia di percolazione elettrica dei compositi con miscele composite non continue era del 5%. Per quanto riguarda le proprietà meccaniche, l'incorporazione del riempitivo nelle mescole ha portato a materiali più rigidi con modulo elastico più elevato, allungamento a rottura inferiore e modulo conservativo più elevato. Il modulo conservativo (G') e la viscosità complessa (η*) dei compositi sono aumentate con l'aggiunta di CB-PPy. La soglia di percolazione reologica è risultata essere del 3% per PVDF/TPU/CB-PPy 38/62 vol% e dell'1% per PVDF/TPU/CB-PPy 50/50 vol%, indicando che una maggiore quantità di riempitivo potrebbe compromettere la processabilità dei compositi. L'aggiunta di CB-PPy ha comportato anche una riduzione dei valori di Tg e Tm dei compositi a causa della riduzione della mobilità delle catene polimeriche. Sulla base della conduttività elettrica e del comportamento meccanico dei compositi, sono state selezionate tre diverse composizioni per l'estrusione di filamenti da utilizzare in un processo di stampa 3D. Nel complesso, le parti stampate in 3D presentavano proprietà meccaniche ed elettriche inferiori a causa della presenza di vuoti, difetti e strati sovrapposti che possono ostacolare il flusso di elettroni. I valori di conducibilità elettrica dei compositi PVDF/TPU/CB-PPy 38/62 vol% contenenti il 5% e il 6% di CB-PPy di campioni stampati in 3D sono da uno a sette ordini di grandezza inferiori a quelli trovati per i compositi stampati a compressione con la stessa composizione. Anche se il valore di conducibilità elettrica per il composito stampato a compressione PVDF/TPU 38/62 vol% con il 6% di CB-PPy era pari a 1,94x10-1 S•m-1, il composito stampato in 3D con la stessa composizione ha mostrato un valore molto basso di conducibilità elettrica, pari a 6,01x10-8 S•m-1. D'altra parte, il composito PVDF/TPU 50/50 vol% stampato in 3D con il 10% di riempitivo ha mostrato un elevato valore di conducibilità elettrica, pari a 4,14 × 100 S•m-1, anche dopo il processo di stampa. Inoltre, sono state studiate le risposte piezoresistive dei compositi. Per i compositi PVDF/TPU/CB-PPy 38/62 vol%, i campioni stampati a compressione e stampati in 3D con il 5% e il 6% di CB-PPy hanno mostrato una buona risposta piezoresistiva. Tuttavia, solo i compositi con il 6% hanno mostrato valori di sensibilità e gauge factor elevati, ampio intervallo di pressione e risposte piezoresistive riproducibili in 100 cicli per entrambi i metodi. D'altra parte, per i compositi co-continui PVDF/TPU/CB-PPy solo il campione stampato a compressione con il 5% di CB-PPy ha presentato risposte piezoresistive adeguate e riproducibili. La cristallinità e il contenuto di fase β del PVDF sono stati studiati per i compositi. Sebbene il grado di cristallinità dei campioni diminuisca con l'aggiunta di CB-PPy, la percentuale di fase β in PVDF risulta aumentata. Il coefficiente piezoelettrico d33 dei campioni aumenta anch’esso con la percentuale di fase β. L'aggiunta del 6% o più di CB-PPy è stata necessaria per aumentare significativamente il coefficiente piezoelettrico (d33) dei compositi. Il contenuto di fase β e le risposte piezoelettriche del PVDF sono inferiori per i campioni ottenuti mediante stampa 3D. Infine, come ricerca collaterale, è stata misurata l'efficacia della schermatura contro le interferenze elettromagnetiche (EMI-SE) per tutti i compositi. I compositi con una maggiore conduttività elettrica hanno mostrato una migliore schermatura della radiazione elettromagnetica. Inoltre, i compositi basati sulla miscela co-continua hanno mostrato un'efficienza di schermatura EMI maggiore rispetto ai compositi a 38/62% in volume. Per tutti i compositi, il principale meccanismo di schermatura è l'assorbimento. I campioni preparati mediante manifattura additiva hanno mostrato risposte EMI-SE inferiori rispetto ai campioni stampati a compressione.
Hashemi, Sanatgar Razieh. "FDM 3D printing of conductive polymer nanocomposites : A novel process for functional and smart textiles". Thesis, Lille 1, 2019. http://www.theses.fr/2019LIL1I052/document.
Texto completoThe aim of this study is to get the benefit of functionalities of fused deposition modeling (FDM) 3D printed conductive polymer nanocomposites (CPC) for the development of functional and smart textiles. 3D printing holds strong potential for the formation of a new class of multifunctional nanocomposites. Therefore, development and characterization of 3D printable functional polymers and nanocomposites are needed to apply 3D printing as a novel process for the deposition of functional materials on fabrics. This method will introduce more flexible, resource-efficient and cost-effective textile functionalization processes than conventional printing process like screen and inkjet printing. The goal is to develop an integrated or tailored production process for smart and functional textiles which avoid unnecessary use of water, energy, chemicals and minimize the waste to improve ecological footprint and productivity. The contribution of this thesis is the creation and characterization of 3D printable CPC filaments, deposition of polymers and nanocomposites on fabrics, and investigation of the performance of the 3D printed CPC layers in terms of functionality. Firstly, the 3D printable CPC filaments were created including multi-walled carbon nanotubes (MWNT) and high-structured carbon black (Ketjenblack) (KB) incorporated into a biobased polymer, polylactic acid (PLA), using a melt mixing process. The morphological, electrical, thermal and mechanical properties of the 3D printer filaments and 3D printed layers were investigated. Secondly, the performance of the 3D printed CPC layers was analyzed under applied tension and compression force. The response for the corresponding resistance change versus applied load was characterized to investigate the performance of the printed layers in terms of functionality. Lastly, the polymers and nanocomposites were deposited on fabrics using 3D printing and the adhesion of the deposited layers onto the fabrics were investigated. The results showed that PLA-based nanocomposites including MWNT and KB are 3D printable. The changes in morphological, electrical, thermal, and mechanical properties of nanocomposites before and after 3D printing give us a great understanding of the process optimization. Moreover, the results demonstrate PLA/MWNT and PLA/KB as a good piezoresistive feedstock for 3D printing with potential applications in wearable electronics, soft robotics, and prosthetics, where complex design, multi-directionality, and customizability are demanded. Finally, different variables of the 3D printing process showed a significant effect on adhesion force of deposited polymers and nanocomposites onto fabrics which has been presented by the best-fitted model for the specific polymer and fabric
Oziat, Julie. "Electrode 3D de PEDOT : PSS pour la détection de métabolites électrochimiquement actifs de Pseudomonas aeruginosa". Thesis, Lyon, 2016. http://www.theses.fr/2016LYSEM026/document.
Texto completoDuring infections, microorganisms fast identification is critical to improve patient treatment and to better manage antibiotics use. Electrochemistry exhibits several advantages for rapid diagnostic: it enables easy, cheap and in situ analysis in most liquids. Its use for bacterial identification is recent and comes from the discovery of molecules giving strong redox signals in the bacterial supernatant of the Pseudomonas genus.This thesis focuses on the supernatants analysis of the bacterium Pseudomonas aeruginosa. This bacteria is the fourth cause of nosocomial infections in Europe. First, the interest of supernatants electrochemical analysis for identification was evaluated. For this, after the study of four redox biomarkers of this bacterium in model solutions, supernatant electrochemical analysis of several strains of P. aeruginosa was performed. The results are promising. They highlight a complex strain-dependant electrochemical signature of the supernatant.Following, we focused in the amplification of the electrochemical detection through the use of the conductive polymer PEDOT: PSS. This polymer was chosen for its good electrochemical properties, its biocompatibility and its easy shaping. It was first used as a thin films to confirm its amplification power through biomarker adsorption. Then, a 3D electrode was made by freeze drying. The use of this type of electrode can further amplify the detection by increasing the exchange surface as well as confining the bacteria in the electrode
Sandron, Marco. "Mils - Stampante per la creazione di PCB (printed circuit board) con polimero". Master's thesis, Alma Mater Studiorum - Università di Bologna, 2019. http://amslaurea.unibo.it/19757/.
Texto completoLiu, Shaohua, Faxing Wang, Renhao Dong, Tao Zhang, Jian Zhang, Zhikun Zheng, Yiyong Mai y Xinliang Feng. "Soft-Template Construction of 3D Macroporous Polypyrrole Scaffolds". Saechsische Landesbibliothek- Staats- und Universitaetsbibliothek Dresden, 2018. http://nbn-resolving.de/urn:nbn:de:bsz:14-qucosa-235502.
Texto completoAnhorn, Michael J. "Nitrogen Rich Porous Organic Frameworks: Proton Conduction Behavior of 3D Benzimidazole and Azo-linked Polymers". VCU Scholars Compass, 2018. https://scholarscompass.vcu.edu/etd/5448.
Texto completoBou-Saleh, Ziad. "Nickel-based 3D electrocatalyst layers for production of hydrogen by water electrolysis in an acidic medium". Thesis, McGill University, 2008. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=112559.
Texto completoIt was demonstrated that patterning of a glassy carbon electrode substrate with a 3D polyaniline (PANI) matrix is a convenient way of increasing the electrocatalytically active surface area of electrodeposited Ni, and hence its apparent electrocatalytic activity. The optimized PANI/Ni electrocatalyst layer showed a significantly higher activity in the hydrogen evolution reaction (HER) then a commercially available Ni-plate surface (control surface).
It was also demonstrated that it is possible to produce a Ni-based HER electrocatalyst layer by synthesizing Ni nanoparticles and supporting them on Vulcan carbon. This electrocatalyst also offered a significantly higher electrocatalytic activity in the HER then the control surface, but lower then the optimized PANI/Ni electrocatalyst.
The electrocatalytic activity of the optimized PANI/Ni layer was also compared to the activity of a 3D catalyst produced by electro-coating a porous reticulated vitreous carbon (RVC) substrate with Ni. This electrocatalyst showed the highest HER electrocatalytic activity among the investigated layers when tested under potentiodynamic polarization conditions. However, under the potentiostatic conditions, the optimized PANI/Ni layer showed the highest electrocatalytic activity.
The mechanisms and kinetics of the HER on the produced electrocatalysts was also investigated, as well as the electrocatalyst layers' surface morphology and crystalline structure.
Ferro, Magali. "Development of conducting polymer devices for the monitoring of in vitro barrier tissue models". Thesis, Lyon, 2018. http://www.theses.fr/2018LYSEM017.
Texto completoIn vitro cell models are widely accepted platforms for toxicological studies. However starting from the 2D models, improvements are needed to reproduce the physiological environment of the tissue. Advances in tissue engineering have given rise to 3D barrier tissue models that recreate cell-cell and cell-matrix interactions. However, electrical platforms to quantify barrier tissue permeability hasn’t followed the rapid pace of models complexification. In this work I explore the possibilities to design conductive polymer-based devices adapted for the characterization of barrier tissue models. Conventional electrical tools used to evaluate integrity of barrier tissues are made of metal electrodes placed on each side of the tissue. This technology presents limitations when it comes to analyzing customized 3D tissue models due to issues in electrode size and stiffness. As an alternative option to metal electrodes, organic electronic materials have shown great promise to interface with biological tissues. In particular the Organic ElectroChemical Transistor (OECT) using PEDOT:PSS has already shown great efficiency to quantify electrical properties of barrier tissues in 2D. Thanks to microfabrication techniques they can be miniaturized and tuned to form mechanically compliant interface with a range of biological tissues. In this thesis, OECT compatibility with models such as tracheal cell culture at the air-liquid interface, spheroid models and microvessel-on-a-chip system has been tested. The achievements described in this work present significant progress in the field of in vitro platforms of barrier tissue modeling for toxicology and drug discovery testing
Mariani, Federica. "PEDOT:PSS thin films: Applications in Bioelectronics". Master's thesis, Alma Mater Studiorum - Università di Bologna, 2016. http://amslaurea.unibo.it/11915/.
Texto completoCapítulos de libros sobre el tema "3D conductive polymer"
Xiang, Dong. "3D-Printed Flexible Strain Sensors of Conductive Polymer Composites". En Carbon-Based Conductive Polymer Composites, 141–60. Boca Raton: CRC Press, 2022. http://dx.doi.org/10.1201/9781003218661-8.
Texto completoAlegret, Nuria, Antonio Dominguez-Alfaro y David Mecerreyes. "Chapter 10. Conductive Polymers Building 3D Scaffolds for Tissue Engineering". En Polymer Chemistry Series, 383–414. Cambridge: Royal Society of Chemistry, 2020. http://dx.doi.org/10.1039/9781788019743-00383.
Texto completoSong, Edward y Jin-Woo Choi. "Inkjet Printing of Conducting Polymer Nanomaterials". En Nanomaterials for 2D and 3D Printing, 245–64. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2017. http://dx.doi.org/10.1002/9783527685790.ch12.
Texto completoBarbosa, Joseane R., Pedro H. O. Amorim, Mariana C. de O. Gonçalves, Rafael M. Dornellas, Robson P. Pereira y Felipe S. Semaan. "Evaluation of 3D Printing Parameters on the Electrochemical Performance of Conductive Polymeric Components for Chemical Warfare Agent Sensing". En Smart Innovation, Systems and Technologies, 425–35. Singapore: Springer Singapore, 2019. http://dx.doi.org/10.1007/978-981-13-9155-2_34.
Texto completoAgarwala, Shweta, Guo Liang Goh, Guo Dong Goh, Vishwesh Dikshit y Wai Yee Yeong. "3D and 4D printing of polymer/CNTs-based conductive composites". En 3D and 4D Printing of Polymer Nanocomposite Materials, 297–324. Elsevier, 2020. http://dx.doi.org/10.1016/b978-0-12-816805-9.00010-7.
Texto completoZhu, Jianxiong. "Carbon black-reinforced 3D and 4D printable conductive polymer composites". En 3D and 4D Printing of Polymer Nanocomposite Materials, 367–85. Elsevier, 2020. http://dx.doi.org/10.1016/b978-0-12-816805-9.00012-0.
Texto completoHorst, Diogo José y Pedro Paulo Andrade Junior. "3D-Printed Conductive Filaments Based on Carbon Nanostructures Embedded in a Polymer Matrix". En Research Anthology on Synthesis, Characterization, and Applications of Nanomaterials, 1725–42. IGI Global, 2021. http://dx.doi.org/10.4018/978-1-7998-8591-7.ch072.
Texto completoJoshi, Atharv, Jonathan Kenneth Goh y Kuan Eng Johnson Goh. "Polymer-based conductive composites for 3D and 4D printing of electrical circuits". En 3D and 4D Printing of Polymer Nanocomposite Materials, 45–83. Elsevier, 2020. http://dx.doi.org/10.1016/b978-0-12-816805-9.00003-x.
Texto completoPradeep Kumar G. S., Sachith T. S., Sasidhar Jangam, Shivakumar S. y Gurumoorthy S. Hebbar. "Development of High Performance Polymer Composites by Additive Manufacturing". En Advances in Chemical and Materials Engineering, 220–38. IGI Global, 2023. http://dx.doi.org/10.4018/978-1-6684-6009-2.ch013.
Texto completoHuang, Ching-Cheng y Masashi Shiotsuki. "Perspective Chapter: Design and Characterization of Natural and Synthetic Soft Polymeric Materials with Biomimetic 3D Microarchitecture for Tissue Engineering and Medical Applications". En Biomimetics - Bridging the Gap [Working Title]. IntechOpen, 2022. http://dx.doi.org/10.5772/intechopen.106471.
Texto completoActas de conferencias sobre el tema "3D conductive polymer"
Blasco, Eva, Jonathan B. Müller, Patrick Müller, Andreas C. Fischer, Christopher Barner-Kowollik y Martin Wegener. "Fabrication of 3D gold/polymer conductive microstructures via direct laser writing (Conference Presentation)". En Laser 3D Manufacturing IV, editado por Corey M. Dunsky, Jian Liu, Henry Helvajian, Alberto Piqué y Bo Gu. SPIE, 2017. http://dx.doi.org/10.1117/12.2256873.
Texto completoKamkar, Milad, Majed Amini, Saeed Ghaderi, Ahmadreza Ghafarkhah, Amirhossein Ahmadian Hosseini y Mohammad Arjmand. "Advanced 3D Printed Conductive Polymer Nanocomposites for Electromagnetic Shielding". En 2021 IEEE Sensors. IEEE, 2021. http://dx.doi.org/10.1109/sensors47087.2021.9639856.
Texto completoKawakita, Jin, Barbara Horvath y Toyohiro Chikyow. "Fast filling of through-silicon via (TSV) with conductive polymer/metal composites". En 2015 International 3D Systems Integration Conference (3DIC). IEEE, 2015. http://dx.doi.org/10.1109/3dic.2015.7334583.
Texto completoElwood, Jacqueline y Liwei Lin. "A 3D Printed Ethanol Sensor Using Conformally-Coated Conductive Polymer Electrodes". En 2019 20th International Conference on Solid-State Sensors, Actuators and Microsystems & Eurosensors XXXIII (TRANSDUCERS & EUROSENSORS XXXIII). IEEE, 2019. http://dx.doi.org/10.1109/transducers.2019.8808789.
Texto completoRodriguez, David Gonzalez, Cole Maynard, Julio Hernandez, Corey O’Brien, Tyler N. Tallman, Brittany Newell y Jose Garcia. "3D Printed Flexible Dielectric Electroactive Polymer Sensors". En ASME 2022 Conference on Smart Materials, Adaptive Structures and Intelligent Systems. American Society of Mechanical Engineers, 2022. http://dx.doi.org/10.1115/smasis2022-91072.
Texto completoLu, Lu, Shan Hu y Yayue Pan. "3D Printed Particle-Polymer Composites With Acoustically Localized Particle Distribution for Thermal Management Applications". En ASME 2018 13th International Manufacturing Science and Engineering Conference. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/msec2018-6643.
Texto completoAliheidari, Nahal, Cameron Hohimer y Amir Ameli. "3D-Printed Conductive Nanocomposites for Liquid Sensing Applications". En ASME 2017 Conference on Smart Materials, Adaptive Structures and Intelligent Systems. American Society of Mechanical Engineers, 2017. http://dx.doi.org/10.1115/smasis2017-3855.
Texto completoKoyalamudi, Kiran Babu, Ruoyu Yang y Rahul Rai. "Additive Manufacturing of Conductive Polymer Nanocomposites Under the Influence of External Magnetic Field". En ASME 2016 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. American Society of Mechanical Engineers, 2016. http://dx.doi.org/10.1115/detc2016-59595.
Texto completoHan, Jun, Lingyu Sun, Lijun Li, Bincheng Huang, Xudong Yang y Taikun Wang. "3D Numerical Model for Prediction of Percolation Threshold and Piezoresistive Characteristics of Conductive Polymer Filled With CNT". En ASME 2018 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/imece2018-86528.
Texto completoKim, Eunkyoung, HanWhuy Lim y Jongbeom Na. "Photothermal effect in conductive polymer layers for structural conversion into a complex 3D structure (Conference Presentation)". En Organic Photonic Materials and Devices XIX, editado por Christopher E. Tabor, François Kajzar, Toshikuni Kaino y Yasuhiro Koike. SPIE, 2017. http://dx.doi.org/10.1117/12.2257109.
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