Relevant bibliographies by topics / Inkjet printing

Contents

  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers
  6. Reports

Academic literature on the topic 'Inkjet printing'

Author: Grafiati
Published: 4 June 2021
Last updated: 6 September 2023

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Journal articles on the topic "Inkjet printing"

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Zhang, Yanzhen, Guofang Hu, Yonghong Liu, Jide Wang, Guodong Yang, and Dege Li. "Suppression and Utilization of Satellite Droplets for Inkjet Printing: A Review." Processes 10, no. 5 (May 8, 2022): 932. http://dx.doi.org/10.3390/pr10050932.

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Inkjet printing, initially invented for text and pattern printing, has been extensively used to fabricate electronic, mechanical, and even biological devices. Numerous reviews focused on the mechanisms, development, and application of inkjet printing have been published in recent years. However, a small review has focused on the satellite droplets during inkjet printing. Satellite droplets have long been recognized as an undesirable byproduct in the inkjet community since they potentially blur the printing patterns, polluting the printer and the air. Numerous efforts have been made to avoid or suppress the generation of satellite droplets since the inkjet’s birth. However, recent studies demonstrated the delicately utilizing of the satellite for realizing extremely high printing resolution otherwise impossible for the traditional inkjet printing. In this review, we focus on the formation mechanisms of satellites, efforts made to suppress satellites, and techniques developed to utilize satellites, distinguishing them from the existing inkjet printing reviews.
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Gao, Shao Hong, Xian Fu Wei, and Bei Qing Huang. "Effect of Resin on the Property of the Fluorescent Inkjet Ink." Advanced Materials Research 287-290 (July 2011): 49–53. http://dx.doi.org/10.4028/www.scientific.net/amr.287-290.49.

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Digital printing ink imaging is one of main technical fields in digital printing technology development, fluorescence inkjet digital printing is provided with favorable anti-falsification, which is used widely in Securities anti-counterfeiting and labels anti-counterfeiting etc[1]. Printings coated with fluorescence inkjet ink that emits fluorescence under using short-wave ultraviolet light excitation get more favorable anti-falsification. Green fluorescent inkjet ink is composed of phosphor, resin, solvent, assistant agent etc, resin is main one of green fluorescent inkjet ink, which has a significant implication for its property. In order to discuss resins to green fluorescent inkjet ink properties, five samples of fluorescent inkjet ink are prepared, and test various performance parameters of ink samples, such as luminous intensity, surface tension, adhesive force, aridity, and so on. The study result indicated that resins have a great influence on luminous intensity, surface tension, aridity of fluorescence inkjet ink samples, surface tension and viscosity of resins immediately impact surface tension and viscosity of fluorescent inkjet ink.
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Hsieh, Yung Cheng, Hsiang Tung Lee, and Ssu Yi Cheng. "Color Gamut of UV Wide-Format Inkjet Printing on Special Substrates." Applied Mechanics and Materials 262 (December 2012): 345–48. http://dx.doi.org/10.4028/www.scientific.net/amm.262.345.

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UV Inkjet Printing has demonstrated extraordinary potential in printing technology around the globe in recent years. Other than its environment-friendly trait, UV Inkjet Printing can also be applied to various printing materials due to its wide range of application. Comparing to the low-price competition invoked by paper-based printing, it achieves high added-value results from its output. While international market’s perspective on inkjet printing remains positive, most printing press in Taiwan still have doubts for the technology. In recent years, there has been a considerable growth in importing UV Width Inkjet printers in Taiwan domestically. However, working personnel in Taiwan are inexperienced in dealing with new equipment and wider selection of printing materials, therefore the issue of printers adapting to their diverse printing materials. This study will examine the five combinations of UV printer and printing materials that are common in Taiwan (brands of printers, serial number of the sprinkler head, and brands of printing ink) and three specific high-value printing substrates (glass, acrylic and melamine plywood). Through the printing experiment, the color gamut of printing materials will be re-examined. The goal of the study is to establish a standard for UV printing’s application in decoration materials, so as to provide reference for future development.
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Yang, Xiao, Xian Fu Wei, Bei Qing Huang, Wan Zhang, and Liang Zhao. "Study on the Printability of UV-Curable Inkjet Ink on Different Printed Materials." Applied Mechanics and Materials 262 (December 2012): 324–28. http://dx.doi.org/10.4028/www.scientific.net/amm.262.324.

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The printed materials used for UV-curable inkjet ink have diversity, in order to research the differences of the printability of UV-curable inkjet ink on different printed materials and improve the printing quality of UV-curable inkjet ink printing on different materials, this research select coated paper, glass card adhesive paper, PVC plastic film as printed materials. After printing the same UV-curable inkjet ink,the printing quality indicators of printing proofs including the density of the line, blurriness, raggedness, line width and contrast of printing product lines were tested,and then test the contact angle of UV-curable inkjet ink on three printed materials, combined with wetting situation,analysis the printing quality of UV ink-jet ink on different substrate, prepare UV ink-jet ink with different printability, printing and testing the printing quality, assessing the quality with comprehensive evaluation method. The result shows that it's existed large differences among the printing quality of the same UV-curable inkjet inks printing on different materials. We match the printed materials with the corresponding printability of UV-curable inkjet inks in the practical production, in order to get the best printing results.
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Guo, Yang, Huseini S. Patanwala, Brice Bognet, and Anson W. K. Ma. "Inkjet and inkjet-based 3D printing: connecting fluid properties and printing performance." Rapid Prototyping Journal 23, no. 3 (April 18, 2017): 562–76. http://dx.doi.org/10.1108/rpj-05-2016-0076.

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Purpose This paper aims to summarize the latest developments both in terms of theoretical understanding and experimental techniques related to inkjet fluids. The purpose is to provide practitioners a self-contained review of how the performance of inkjet and inkjet-based three-dimensional (3D) printing is fundamentally influenced by the properties of inkjet fluids. Design/methodology/approach This paper is written for practitioners who may not be familiar with the underlying physics of inkjet printing. The paper thus begins with a brief review of basic concepts in inkjet fluid characterization and the relevant dimensionless groups. Then, how drop impact and contact angle affect the footprint and resolution of inkjet printing is reviewed, especially onto powder and fabrics that are relevant to 3D printing and flexible electronics applications. A future outlook is given at the end of this review paper. Findings The jettability of Newtonian fluids is well-studied and has been generalized using a dimensionless Ohnesorge number. However, the inclusion of various functional materials may modify the ink fluid properties, leading to non-Newtonian behavior, such as shear thinning and elasticity. This paper discusses the current understanding of common inkjet fluids, such as particle suspensions, shear-thinning fluids and viscoelastic fluids. Originality/value A number of excellent review papers on the applications of inkjet and inkjet-based 3D printing already exist. This paper focuses on highlighting the current scientific understanding and possible future directions.
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Yan, Ji Fang, Bei Qing Huang, Xian Fu Wei, and Jin Wei Dai. "The Effects of Resin on the Performance of Water-Based Inkjet Ink Used in Printing." Advanced Materials Research 380 (November 2011): 44–47. http://dx.doi.org/10.4028/www.scientific.net/amr.380.44.

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People pay more and more attention to water-based printing inkjet ink which has no environmental pollution and fits environmental protection requirements. Inkjet printing technology could be applicable small batch and various variety products and satisfy the customer’s personalized requirements. Resin as one of the main compositions of printing inkjet ink has important effects on ink’s performance. To determine the effects of resin on the performance of water-based printing inkjet ink, adopting grinding method prepare the samples by changing resin and its proportion. By testing the samples’ particle size, viscosity, surface tension, pH value, the effects of resin on the water-based printing inkjet ink were analyzed. The results show that the type of resin and composite ratio has some effects on the performance of printing inkjet ink. When the resin was mixed in accordance with Resin B/Resin C=29/21, the performance of printing inkjet ink which was diluted with this resin was better.
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Peng, Xishun, Anjiang Lu, Pangyue Li, Zhongpeng Chen, Ziran Yu, Jianwu Lin, Yi Wang, Yibo Zhao, Jiao Yang, and Jin Cheng. "Simulation of a Hemispherical Chamber for Thermal Inkjet Printing." Micromachines 13, no. 11 (October 28, 2022): 1843. http://dx.doi.org/10.3390/mi13111843.

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It is crucial to improve printing frequency and ink droplet quality in thermal inkjet printing. This paper proposed a hemispherical chamber, and we used the CFD (computational fluid dynamics model) to simulate the inkjet process. During the whole simulation process, we first researched the hemispherical chamber’s inkjet state equipped with straight, conical shrinkage, and conical diffusion nozzles. Based on the broken time and volume of the liquid column, the nozzle geometry of the hemispherical chamber was determined to be a conical shrinkage nozzle with a specific size of 15 µm in height and 15 µm in diameter at the top, and 20 µm in diameter at the bottom. Next, we researched the inkjet performance of the square chamber, the round chamber, and the trapezoidal chamber. The round chamber showed the best inkjet performance using 1.8 µs as the driving time and 10 MPa as the maximum bubble pressure. After that, we compared the existing thermal inkjet printing heads. The results showed that the hemispherical chamber inkjet head had the best performance, achieving 30 KHz high-frequency printing and having the most significant volume ratio of droplet to the chamber, reaching 14.9%. As opposed to the current 15 KHz printing frequency of the thermal inkjet heads, the hemispherical chamber inkjet head has higher inkjet performance, and the volume ratio between the droplet and the chamber meets the range standard of 10–15%. The hemispherical chamber structure can be applied to thermal inkjet printing, office printing, 3D printing, and bio-printing.
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Smith, Patrick J., and Aoife Morrin. "Reactive inkjet printing." Journal of Materials Chemistry 22, no. 22 (2012): 10965. http://dx.doi.org/10.1039/c2jm30649b.

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Kukkamo, Vesa, and Philipp Hunziker. "Industrial Inkjet Printing." JAPAN TAPPI JOURNAL 64, no. 10 (2010): 1163–66. http://dx.doi.org/10.2524/jtappij.64.1163.

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Cao, Hongmei, Li Ai, Zhenming Yang, and Yawei Zhu. "Application of Xanthan Gum as a Pre-Treatment and Sharpness Evaluation for Inkjet Printing on Polyester." Polymers 11, no. 9 (September 16, 2019): 1504. http://dx.doi.org/10.3390/polym11091504.

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Inkjet printing on polyester fabric displays versatile environmental advantages. One of the significant benefits of inkjet printing is a dramatic enhancement of the printing quality. In this study, xanthan gum—a bio-based thickening agent accompanied by several salts—was adopted for the pretreatment of polyester fabric aiming at improving the sharpness and color depth of inkjet printed patterns. The influences of four metal salts (NaCl, KCl, CaCl2 and MgCl2) on inkjet printing performance were studied. More importantly, a quantitative method for evaluating the sharpness of an inkjet printed pattern was established according to the characteristics of anisotropy and isotropy of diffusion and adsorption of ink droplets on a fiber surface. Results showed that xanthan gum along with a low dosage of bivalent salts can significantly improve the color depth (K/S value) and sharpness of the printed polyester fabrics. It is feasible to evaluate the sharpness of inkjet printed polyester fabrics using a five-stage system, selecting the inkjet ellipse coefficient (T) and inkjet ellipse area (S), which can provide a quantitative and rapid evaluation method for defining inkjet printing.
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Dissertations / Theses on the topic "Inkjet printing"

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Al-Chami, Hussein. "Inkjet printing of transducers." Thesis, University of British Columbia, 2010. http://hdl.handle.net/2429/28260.

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In the past few years, inkjet printing has been emerging as a cost effective, environment friendly, net-shape microfabrication technique. This non-contact deposition technique facilitated the deposition of metallic and polymeric inks, biological proteins, and cells. The present work investigates the inkjet printing of microtransducers, with a focus on stress-sensing and movable microstructures. Piezoresistive and interdigitated capacitor based strain gauges were printed and tested. The inexpensive conductive polymer, poly(3,4-ethylenedioxythiophene) oxidized with poly(styrenesulfonate) (PEDOT:PSS), was used as base material. We have performed measurements on several test structures to show that PEDOT:PSS does preserve its piezoresistive properties after printing. As we were relying further on PEDOT:PSS as a base material for printed transducers, the mechanical and electrical properties of this commercially available ink were comprehensively investigated. A dedicated experimental setup, which was used for the mechanical and electrical characterization of test structures, and micro-topography measurements were combined in order to extract the parameters of the PEDOT:PSS thin film: a zero-stress electrical conductivity of G=201 S/cm and gauge factor of 3.63. The longitudinal and transversal piezoresistive coefficients were estimated to be, [formula omitted] and [formula omitted] respectively, which denote a piezoresistive material in a similar range of piezoresistivity as n-doped silicon and conventionally fabricated PEDOT:PSS. A second explored direction was using inkjet microprinting technology for the fabrication of movable microstructures. An inkjet-printed CMUT (capacitive micromachined ultrasound transducer) was the target device, using ZnO as sacrificial layer and PEDOT:PSS as structural layer. The printed ZnO sacrificial layer was too rough, non-uniform and with a high porosity, so that printing a conductive membrane on top of it was unsuccessful. An alternative solution approach used kapton tape, a polyimide, as movable membrane; experimental characterization has shown that the structure is not properly clamped along its rim, yielding a vibraion at a frequency of 1.1 KHz, when actuated, compared to a resonant frequency of 9.3 KHz achieved by finite element analysis of the CMUT structure. The approach shows enough promise for further investigations, along directions suggested at the end of the thesis.
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Seerden, Kitty A. M. "Inkjet printing of ceramics." Thesis, University of Oxford, 2001. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.393981.

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Whitehouse, Louise Elizabeth. "Inkjet printing for biosensors." Thesis, University of Leeds, 2003. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.396947.

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Sowade, Enrico, Thomas Blaudeck, and Reinhard R. Baumann. "Inkjet Printing of Colloidal Nanospheres." Universitätsbibliothek Chemnitz, 2015. http://nbn-resolving.de/urn:nbn:de:bsz:ch1-qucosa-188147.

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We report on inkjet printing of aqueous colloidal suspensions containing monodisperse silica and/or polystyrene nanosphere particles and a systematic study of the morphology of the deposits as a function of different parameters during inkjet printing and solvent evaporation. The colloidal suspensions act as a model ink for an understanding of layer formation processes and resulting morphologies in inkjet printing in general. We investigated the influence of the surface energy and the temperature of the substrate, the formulation of the suspensions, and the multi-pass printing aiming for layer stacks on the morphology of the deposits. We explain our findings with models of evaporation-driven self-assembly of the nanosphere particles in a liquid droplet and derive methods to direct the self-assembly processes into distinct one- and two-dimensional deposit morphologies.
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Tse, Christopher Chi Wai. "Utilising inkjet printing for tissue engineering." Thesis, University of Sheffield, 2015. http://etheses.whiterose.ac.uk/13950/.

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The field of tissue engineering has the potential to improve the quality of life of individuals through combining the knowledge of engineering and life sciences in creating engineered biological substitutes that repair, support and enhance tissue function. Inkjet printing is a versatile tool that can be used for a broad range of applications. Ubiquitous in households, offices and industry, there has been growing interest in the use of inkjet printing for biological applications. Inkjet printing allows the user to deposit nano-picolitre volume of inks of low viscosity with high precision and high repeatability. Within this thesis, inkjet printing was used to explore its applications in the life sciences, with jetting behaviour and scaffold design optimised. The creation of cell-friendly scaffolds was investigated. Gelatin scaffolds, crosslinked with inkjet printed glutaraldehyde were fabricated. Fibroblasts were seeded onto these fabricated scaffolds and shown to proliferate without hindrance, allowing a method to create sub-millimetre cell-friendly fibres for tissue engineering applications. The ability for inkjet printing to create scaffolds to control cell alignment was investigated. Cell orientation can be controlled through inkjet printing paraffin wax to restrict cell proliferation on a substrate. Paraffin wax is not harmful or toxic to cells, and cells were able to grow within the negative spaces between the wax patterns, to create aligned cell culture as cells proliferated. An advantage with the wax scaffolds was that the wax scaffold was readily removable with a scalpel that allowed further analysis of cell behaviour when proliferating into an unrestricted space. A proportion of cells was also detached upon wax removal, proportional to cell density within the wax scaffold and wax channel width. After wax removal, cell cultures quickly lost their ordered appearance within 3 days as they proliferated randomly across the substrate. The creation of in vitro vasculature models through the use of a combination of inkjet-printed wax, PDMS moulding and wax-loss method to create medical phantoms for the study of rheological behaviour was studied. The scalloping behaviour of the printed wax vessel was reduced in the final phantom created, as there would be a thin lining of wax that covers the interior of the PDMS mould after wax removal, making the vessel smoother. Cell printing of neuronally relevant cells were investigated. NG108-15 and porcine Schwann cells (along with fibroblasts to act as a control experiment) were inkjet printed, studying cell viability during and after inkjet printing. It was concluded that cells were not significantly damaged during inkjet printing over a wide range of voltages (50 V-230 V), and no correlation was seen to show an increase in cell death with increasing voltages. Inkjet printed NG108-15 cells showed they produced longer neurites compared to control samples after 7 days. Further to results, it was confirmed that cell printing is limited to a duration of less than 40 minutes due to cell aggregation within the reservoir of the printing system, causing a steady significant decrease in cell numbers during printing.
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Rickerby, Jenny. "Polymeric precursors for inkjet printing copper." Thesis, Imperial College London, 2003. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.405841.

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He, Pei. "Inkjet printing of two dimensional materials." Thesis, University of Manchester, 2017. https://www.research.manchester.ac.uk/portal/en/theses/inkjet-printing-of-two-dimensional-materials(e11ace04-abb2-42be-b17b-80fc95f3b198).html.

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Over the last decade, two dimensional (2D) materials have attracted considerable attention from both the scientific and engineering community due to their unique properties. One important advance of 2D materials is that they can be exfoliated into nanosheets suspended in a liquid phase and that this allows the formulation of 2D nanomaterials inks. Such inks can be deposited as functional components through low-cost inkjet printing techniques. Many 2D materials based inks have been produced over the years. This thesis investigates the use of inkjet printing to deposit 2D materials such as graphene oxide (GO) and black phosphorus (BP).GO, a derivative of graphene, has been widely used to produce graphene-based conductors via inkjet printing owing to its good stability in readily available solvents such as water. In this work, highly conductive reduced graphene oxide (rGO) films with bulk conductivity in excess of 2 × 10^4 Sm-1 have been prepared by inkjet printing a GO aqueous ink, with mean flake size 35.9 micro metre, through a 60 micro metre inkjet printing nozzle followed by a reduction step. Experimental results showed that individual GO flakes up to 200 micro metre diameter can be successfully printed with no instances of nozzle blocking or poor printing performance. The mechanism by which this occurs is believed to be GO sheet folding during drop formation followed by elastic unfolding during drop impact and spreading. In addition, the influence of GO flake size on rGO film conductivity has been investigated. It was found that the rGO film conductivity increased about 60% when the mean flake size of the GO flakes in the ink increases from 0.68 micro metre to 35.9 micro metre. The drying behaviour of printed GO droplets has been studied on eight GO aqueous inks in which the mean flake size of GO was varied over a range from 0.68 to 35.9 micro metre. It was found that the coffee ring effect (inhomogeneous drying of a droplet to leave a ring like deposit) of dried droplets of the GO ink weakened and disappeared when the flake size increasing. It was found that, with a printed deposit around 340 micro metre in diameter, the coffee ring effect (CRE) was suppressed with the mean flake size > 10.3 micro metre. The critical flake size for CRE suppression reduced to 5.97 and 3.68 micro metre when the substrate temperature was 40 and 50 °C, respectively. It was further found that the CRE weakened with decreasing printed drop size, with the critical flake size reducing to 1.58 micro metre with a printed drop diameter of 30 micro metre.The interaction between BP nanometre thickness flakes and humid atmospheres was investigated using an inkjet printed BP sensor. The BP sensor showed was very sensitive to changes in humidity with a response time of a few seconds and the effect is reproducible in minutes. However, long term exposure to humid air with a relative humidity (RH) > 11% leads to a significant chemical change in the BP films, with Fourier transform infra-red spectroscopy (FTIR) indicating partial hydrolysis of the BP to form phosphate and phosphonate ions. Low temperature heat treatment of BP films under dry conditions after exposure to elevated RH leads to a partial recovery of the impedance response and reversion to a chemical state similar to that before exposure to a humid environment. The recovery of BP properties is most complete after exposure to lower humidity environments (RH < 11%), although exact replication of the original impedance response and FTIR spectrum was not possible.
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Zhang, Yu. "Reactive inkjet printing of silk swimmers." Thesis, University of Sheffield, 2018. http://etheses.whiterose.ac.uk/19417/.

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Biological Micro-motors are one of the most remarkable products of evolution; they can perform biological tasks with surprisingly high efficiency. A novel form of miniaturized man-made self-propelled micro-motors based on silk have been designed and fabricated in this thesis. These ‘swimmers’ were made from regenerated Bombyx mori silk fibroin via 3D reactive inkjet printing under ambient processing conditions. While Bombyx mori silk exhibits impressive mechanical properties, remarkable biocompatibility, controlled biodegradability, environmental stability, and morphologic flexibility, silk swimmers have expanded the range of potential applications even to the biomedical platform and sensitive protein therapeutics. Micro-motors are able to convert chemical or external energy into mechanical motion. Two different types of propulsion mechanisms were studied for silk swimmers: catalytically powered bubble propulsion and surface tension gradient powered.
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Buanz, A. B. M. "Pharmaceutical applications of thermal inkjet printing." Thesis, University College London (University of London), 2014. http://discovery.ucl.ac.uk/1425722/.

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Recent trends in the area of pharmaceutical products research and development appear to be directed more towards new drug delivery systems such as oro-dispersible films, as well as new physical forms of existing drugs such as co-crystals. Adapting technologies from other fields for developing such systems can be beneficial. Thermal inkjet printing (TIJP), a technique commonly encountered in office printers, has found applications in different areas due to its advantageous properties. The aim of this work was to utilise this technique to develop oral films for personalised dosing and to investigate its potential as a rapid and inexpensive method to prepare pharmaceutical co-crystals. Two unmodified Hewlett-Packard printers were used where the ink cartridges were modified to accommodate polymeric and aqueous drug solutions. Films were successfully prepared by printing multiple layers of hydroxyl-propyl-methylcellulose solutions onto transparency films, which disintegrated faster than those prepared by solvent casting (SC). Further, the amount deposited of a model drug (salbutamol sulphate, SS) varied linearly with the feed solution concentration. This led to the preparation of oral films using edible starch paper. Good agreement between the printed and theoretical dose was achieved with single print passes. Multiple print passes resulted in a significant loss, which was predictable and the dose variation was within the BP limits for SS tablets. Polymeric films were then used as substrates to prepare oral films of clonidine. Comparison with films prepared by solvent casting in terms of their physical stability, mechanical and drug release properties was also conducted. Films prepared by TIJP were more flexible and had better dose uniformity than films prepared by SC. Nonetheless, drug release from both films was similar. Finally, the technique was investigated to prepare pharmaceutical co-crystals. This was successfully achieved by printing solutions of co-crystal formers at specific stoichiometric ratios. In conclusion, this work demonstrates the suitability of TIJP as a method to prepare oral films extemporaneously for personalised dosing as well as pharmaceutical co-crystals.
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Castro, Spencer Maria Diana. "Fluorescence microscopy of inkjet prints." Thesis, University of Edinburgh, 2010. http://hdl.handle.net/1842/33322.

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Inkjet printing technology has been developing rapidly during recent years, pressing the ink and paper manufacturers to develop a better understanding of the mechanism of fixation of inkjet dye into the substrate. The aim of the work described in this thesis was to investigate the three-dimensional distribution of inkjet dye in paper and the interaction between dye and paper using advanced fluorescence microscopy techniques, Confocal Laser Scanning Microscopy (CLSM), and Two-photon Fluorescence Lifetime Imaging Microscopy (2P-FLIM). It has been shown that CLSM is a valuable, non-destructive, rapid technique for threedimensional imaging of printed samples and evaluation of print quality. The intrinsic fluorescence of both the inkjet dye and the paper substrate can be used to determine the spread and penetration of ink droplets in different inkjet papers. The optical sectioning capability of CLSM enables the position of the ink layer relative to the paper surface and the penetration depth of the ink to be quantified. It was observed that while in the microporous type of inkjet paper the penetration depends on the quantity of ink in the printed sample, in the swellable type of inkjet paper the penetration is almost the same for different amounts of ink. 2P-FLIM has been employed to spatially map, in three-dimensions, fluorescence lifetimes by measuring the lifetime at each pixel in the image. Fluorescent molecules in both the ink and paper were analysed. Because the fluorescence lifetime is affected by the local molecular environment, the fluorescence lifetime maps provide information on the interaction between inkjet dye and paper. Analysis of fluorescence lifetime maps reveals the interaction between dye molecules and silica or alumina particles in the paper, variations of the molecular environment within a single ink dot and that interaction between dye and paper is affected by pH.
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Books on the topic "Inkjet printing"

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Smith, Patrick J., and Aoife Morrin, eds. Reactive Inkjet Printing. Cambridge: Royal Society of Chemistry, 2017. http://dx.doi.org/10.1039/9781788010511.

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Hoath, Stephen D., ed. Fundamentals of Inkjet Printing. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2016. http://dx.doi.org/10.1002/9783527684724.

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Zapka, Werner, ed. Handbook of Industrial Inkjet Printing. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2017. http://dx.doi.org/10.1002/9783527687169.

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The chemistry of inkjet inks. Singapore: World Scientific, 2010.

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Romano, Frank J. Inkjet!: History, technology, markets, and applications. Pittsburgh: Digital printing Council, PIA/GATFPress, 2008.

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Springford, Chris. The future of inkjet printing: Strategic five-year forecasts. Leatherhead: Pira International, 2003.

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Springford, Chris. The future of inkjet printing: Strategic five-year forecasts. Leatherhead: Pira International, 2003.

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1935-, Takahashi Yasusuke, ed. Inkujetto gijutsu to zairyō: Technology of inkjet and materials. Tōkyō: CMC Shuppan, 2007.

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Steinmueller, Uwe. Fine art printing for photographers: Exhibition quality prints with inkjet printers. 3rd ed. Santa Barbara, CA: Rocky Nook, 2013.

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Jürgen, Gulbins, ed. Fine art printing for photographers: Exhibition quality prints with inkjet printers. 2nd ed. Santa Barbara, CA: Rocky Nook, 2008.

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Book chapters on the topic "Inkjet printing"

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Morita, Naoki, Amol A. Khalate, Arend M. van Buul, and Herman Wijshoff. "Inkjet Printheads." In Fundamentals of Inkjet Printing, 57–92. Weinheim, Germany: Wiley-VCH Verlag GmbH & Co. KGaA, 2015. http://dx.doi.org/10.1002/9783527684724.ch3.

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Smith, Patrick J., and Aoife Morrin. "CHAPTER 1. Reactive Inkjet Printing—An Introduction." In Reactive Inkjet Printing, 1–11. Cambridge: Royal Society of Chemistry, 2017. http://dx.doi.org/10.1039/9781788010511-00001.

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Stringer, Jonathan. "CHAPTER 2. From Inkjet Printed Droplets to Patterned Surfaces." In Reactive Inkjet Printing, 12–37. Cambridge: Royal Society of Chemistry, 2017. http://dx.doi.org/10.1039/9781788010511-00012.

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Wilson, Mark C. T., J. Rafael Castrejón-Pita, and Alfonso A. Castrejón-Pita. "CHAPTER 3. Droplet Mixing." In Reactive Inkjet Printing, 38–58. Cambridge: Royal Society of Chemistry, 2017. http://dx.doi.org/10.1039/9781788010511-00038.

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Wheeler, Joseph S. R., and Stephen G. Yeates. "CHAPTER 4. Unwanted Reactions of Polymers During the Inkjet Printing Process." In Reactive Inkjet Printing, 59–87. Cambridge: Royal Society of Chemistry, 2017. http://dx.doi.org/10.1039/9781788010511-00059.

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Lennon, A. J. "CHAPTER 5. Reactive Inkjet Printing for Silicon Solar Cell Fabrication." In Reactive Inkjet Printing, 88–116. Cambridge: Royal Society of Chemistry, 2017. http://dx.doi.org/10.1039/9781788010511-00088.

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Jabbour, Ghassan, Hyung Woo Choi, Mutalifu Abulikamu, Yuka Yoshioka, Basma El Zein, and Hanna Haverinen. "CHAPTER 6. Reactive Inkjet Printing: From Oxidation of Conducting Polymers to Quantum Dots Synthesis." In Reactive Inkjet Printing, 117–46. Cambridge: Royal Society of Chemistry, 2017. http://dx.doi.org/10.1039/9781788010511-00117.

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Rider, P. M., I. M. Brook, P. J. Smith, and C. A. Miller. "CHAPTER 7. Reactive Inkjet Printing of Silk Barrier Membranes for Dental Applications." In Reactive Inkjet Printing, 147–68. Cambridge: Royal Society of Chemistry, 2017. http://dx.doi.org/10.1039/9781788010511-00147.

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Gregory, David A., Yu Zhang, Stephen J. Ebbens, and Xiubo Zhao. "CHAPTER 8. Reactive Inkjet Printing of Regenerated Silk Fibroin as a 3D Scaffold for Autonomous Swimming Devices (Micro-rockets)." In Reactive Inkjet Printing, 169–201. Cambridge: Royal Society of Chemistry, 2017. http://dx.doi.org/10.1039/9781788010511-00169.

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He, Yinfeng, Aleksandra Foerster, Belen Begines, Fan Zhang, Ricky Wildman, Richard Hague, Phill Dickens, and Christopher Tuck. "CHAPTER 9. Reactive Inkjet Printing for Additive Manufacturing." In Reactive Inkjet Printing, 202–21. Cambridge: Royal Society of Chemistry, 2017. http://dx.doi.org/10.1039/9781788010511-00202.

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Conference papers on the topic "Inkjet printing"

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Srichan, Chavis, Thitirat Saikrajang, Tanom Lomas, Apichai Jomphoak, Thitima Maturos, Disayut Phokaratkul, Teerakiat Kerdcharoen, and Adisorn Tuantranont. "Inkjet printing PEDOT:PSS using desktop inkjet printer." In 2009 6th International Conference on Electrical Engineering/Electronics, Computer, Telecommunications and Information Technology (ECTI-CON). IEEE, 2009. http://dx.doi.org/10.1109/ecticon.2009.5137049.

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Vadzak, Adam, Juraj Nevrela, Michal Micjan, and Martin Weis. "Flexible inkjet sensor fabricated by inkjet printing." In 2020 13th International Conference on Advanced Semiconductor Devices And Microsystems (ASDAM). IEEE, 2020. http://dx.doi.org/10.1109/asdam50306.2020.9393831.

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Al-Chami, Hussein, and Edmond Cretu. "Inkjet printing of microsensors." In 2009 IEEE 15th International Mixed-Signals, Sensors, and Systems Test Workshop (IMS3TW). IEEE, 2009. http://dx.doi.org/10.1109/ims3tw.2009.5158692.

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Kaiser, Jan. "Inkjet printing: Color accuracy." In 2009 19th International Conference Radioelektronika (RADIOELEKTRONIKA). IEEE, 2009. http://dx.doi.org/10.1109/radioelek.2009.5158759.

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Li, Dapeng, Paul Calvert, and Charlene Mello. "Inkjet printing virus-based sensors." In 2009 IEEE 35th Annual Northeast Bioengineering Conference. NEBEC 2009. IEEE, 2009. http://dx.doi.org/10.1109/nebc.2009.4967839.

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Yoshioka, Yuka, Ghassan E. Jabbour, and Paul D. Calvert. "Multilayer inkjet printing of materials." In International Symposium on Optical Science and Technology, edited by Guozhong Cao and Wiley P. Kirk. SPIE, 2002. http://dx.doi.org/10.1117/12.453796.

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Kim, Daeyoung, Jun Hyeon Yoo, Yunho Lee, Wonjae Choi, Koangki Yoo, and Jeong-Bong Lee. "Gallium-based liquid metal inkjet printing." In 2014 IEEE 27th International Conference on Micro Electro Mechanical Systems (MEMS). IEEE, 2014. http://dx.doi.org/10.1109/memsys.2014.6765804.

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Calvert, Paul, Yuka Yoshioka, and Ghassan Jabbour. "Inkjet printing for building multilayer devices." In Frontiers in Optics. Washington, D.C.: OSA, 2003. http://dx.doi.org/10.1364/fio.2003.wr2.

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DMONTE, David John, Pavol ŠULY, Jan ANTOŠ, Pavel URBÁNEK, and Ivo KUŘITKA. "INKJET PRINTING OF A GAS SENSOR." In NANOCON 2019. TANGER Ltd., 2020. http://dx.doi.org/10.37904/nanocon.2019.8574.

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Kemper, Falk, Maximilian Reif, Sabrina J. Wolleb, Thomas Schönfelder, Lisa Pohle, Erik Beckert, Ulrike Schulz, and Andreas Tünnermann. "Inkjet-printing of 3D optical systems." In Organic Photonic Materials and Devices XXIII, edited by Ileana Rau, Okihiro Sugihara, and William M. Shensky. SPIE, 2021. http://dx.doi.org/10.1117/12.2578404.

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Reports on the topic "Inkjet printing"

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Rupich, Martin, Dr, and Robert, Dr Duckworth. Low AC Loss YBCO Coated Conductor Geometry by Direct Inkjet Printing. Office of Scientific and Technical Information (OSTI), October 2009. http://dx.doi.org/10.2172/1083457.

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Pioneering Inkjet Printing Technology Produces Thin-Film Photovoltaics; The Spectrum of Clean Energy Innovation (Fact Sheet). Office of Scientific and Technical Information (OSTI), June 2010. http://dx.doi.org/10.2172/983721.

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