Publications by Type: Journal Article

2018
Shukrun E, Cooperstein I, Magdassi S. 3D‐Printed Organic–Ceramic Complex Hybrid Structures with High Silica Content. Advanced Science. 2018 :1800061.
Cooperstein I, Shukrun E, Press O, Kamyshny A, Magdassi S. Additive Manufacturing of Transparent Silica Glass from Solutions. ACS Appl. Mater. InterfacesACS Applied Materials & Interfaces. 2018;10 (22) :18879 - 18885.Abstract
A sol, aq. soln.-based ink is presented for fabrication of 3D transparent silica glass objects with complex geometries, by a simple 3D printing process conducted at room temp. The ink combines a hybrid ceramic precursor that can undergo both photopolymn. reaction and a sol-gel process, both in a soln. form, without any particles. The printing is conducted by localized photopolymn. with the use of a low-cost 3D printer. Following printing, upon aging and densifying, the resulting objects convert from a gel to a xerogel and then to a fused silica. The printed objects, which are composed of fused silica, are transparent and have tunable d. and refractive indexes. [on SciFinder(R)]
Farraj Y, Layani M, Yaverboim A, Magdassi S. Binuclear Copper Complex Ink as a Seed for Electroless Copper Plating Yielding >70% Bulk Conductivity on 3D Printed Polymers. Adv. Mater. InterfacesAdvanced Materials Interfaces. 2018;5 (8) :1701285/1 - 1701285/7.Abstract
3D printed electronics is an emerging field of high importance in both academic research and industrial manufg. It enables fabrication of 3D devices with embedded or conformal electronic circuits, which are relevant to a variety of applications, such as Internet of things, soft robotics, and medical devices. Patterning of elec. conductors with cond. higher than 50% bulk copper is challenging and usually involves electroless or electrolytic deposition processes that require the use of very costly catalyst, mainly palladium, as a seed material. Here, the use of a binuclear copper complex as a very efficient replacement for the conventional catalysts, which can be directly inkjet printed onto 3D plastic objects, is described. After printing, the copper complex is converted into pure copper upon short exposure to low-temp. plasma. By combining the binuclear complex with electroless plating, resistivity as low as 2.38 μΩ cm, which corresponds to a 72% cond. of bulk copper, is obtained. The applicability of the complex ink and the process is demonstrated in the fabrication of a near-field communication antenna on a 3D printed plastic object. [on SciFinder(R)]
Avigail Stern, Azoubel S, Sachyani E, Livshits GI, Rotem D, Magdassi S, Porath D. Conductivity Enhancement of Transparent 2D Carbon Nanotube Networks Occurs by Resistance Reduction in All Junctions. J. Phys. Chem. CJournal of Physical Chemistry C. 2018 :Ahead of Print.Abstract
Transparent conductive networks are important for flexible electronics and solar cells. Often interwire (junction) cond. is the limiting factor for network cond. and can be improved by various treatments. The cond. of individual junctions in a single walled carbon nanotube network was measured by conductive at. force microscopy before and after exposure to nitric acid. The measurements show that this exposure improves the cond. of each one of the junctions within the network. Our results suggest that the acid improves the cond. by p-type charge transfer doping and by surfactant degrdn. [on SciFinder(R)]
Cai G, Cheng X, Layani M, Tan AWM, Li S, Eh AL-S, Gao D, Magdassi S, Lee PS. Direct inkjet-patterning of energy efficient flexible electrochromics. Nano EnergyNano Energy. 2018;49 :147 - 154.Abstract
High-quality patterns were successfully prepd. by inkjet-printing WO3-PEDOT:PSS composites on different substrates including the rigid FTO glass and most importantly, on flexible PEDOT:PSS/Ag grid/PET. Excellent electrochromic performances can be achieved, including large optical modulation (85.7% optical contrast at the wavelength of 633nm on FTO glass substrate), fast switching speed (coloration/bleaching time of 2.4/0.8s on the PEDOT:PSS/Ag grid/PET substrate), instantaneous coloration efficiency (68.8cm2 C-1) and good cycling stability (up to 10,000 cycles). The effects of the applied potential window during electrochem. evaluation on the electrochromic performances were analyzed in detail. The printed electrochromics films on PEDOT:PSS/Ag grid/PET showed the best electrochem. stability, in agreement with its superior cond. and transmittance at 633nm of 0.6Ω/sq and 66%, resp. It sustained transmittance modulation of about 75.5% and 53.1% of its first cycle recorded contrast at 633nm, after being subjected to 1000 and 5000 cycles, resp., and maintained good electrochem. stability up to 10,000 cycles. Moreover, a robust mech. stability was also achieved by the printed films on flexible PEDOT:PSS/Ag grid/PET substrate. The film maintained a transmittance modulation of 85.8% of its original contrast after 5000 bending cycles at a curvature radius of 1cm. The inkjet-printed WO3 nanocomposite based flexible electrochromic displays exhibited excellent electrochromic performance, making it a promising candidate for energy efficient displays, e-books, e-cards and multifunctional electronic devices. [on SciFinder(R)]
Patel DK, Cohen B-E, lioz etgar, Magdassi S. Fully 2D and 3D printed anisotropic mechanoluminescent objects and their application for energy harvesting in the dark. Mater. Horiz.Materials Horizons. 2018 :Ahead of Print.Abstract
We report on new material compns. enabling fully printed mechanoluminescent 3D devices by using a one-step direct write 3D printing technol. The ink is composed of PDMS, transition metal ion-doped ZnS particles, and a platinum curing retarder that enables a long open time for the printing process. 3D printed mechanoluminescent multi-material objects with complex structures were fabricated, in which light emission results from stretching or wind blowing. The multi-material printing yielded anisotropic light emission upon compression from different directions, enabling its use as a directional strain and pressure sensor. The mechanoluminescent light emission peak was tailored to match that of a perovskite material, and therefore, enabled the direct conversion of wind power in the dark into electricity, by linking the printed device to perovskite-based solar cells. [on SciFinder(R)]
Zhang B, Li S, Hingorani H, Serjouei A, Larush L, Pawar AA, Goh WH, Sakhaei AH, Hashimoto M, Kowsari K, et al. Highly stretchable hydrogels for UV curing based high-resolution multimaterial 3D printing. J. Mater. Chem. BJournal of Materials Chemistry B: Materials for Biology and Medicine. 2018;6 (20) :3246 - 3253.Abstract
We report a method to prep. highly stretchable and UV curable hydrogels for high resoln. DLP based 3D printing. Hydrogel solns. were prepd. by mixing self-developed high-efficiency water-sol. TPO nanoparticles as the photoinitiator with an acrylamide-PEGDA (AP) based hydrogel precursor. The TPO nanoparticles make AP hydrogels UV curable, and thus compatible with the DLP based 3D printing technol. for the fabrication of complex hydrogel 3D structures with high-resoln. and high-fidelity (up to 7 μm). The AP hydrogel system ensures high stretchability, and the printed hydrogel sample can be stretched by more than 1300%, which is the most stretchable 3D printed hydrogel. The printed stretchable hydrogels show an excellent biocompatibility, which allows us to directly 3D print biostructures and tissues. The great optical clarity of the AP hydrogels offers the possibility of 3D printing contact lenses. More importantly, the AP hydrogels are capable of forming strong interfacial bonding with com. 3D printing elastomers, which allows us to directly 3D print hydrogel-elastomer hybrid structures such as a flexible electronic board with a conductive hydrogel circuit printed on an elastomer matrix. [on SciFinder(R)]
Yeshua T, Layani M, Dekhter R, Huebner U, Magdassi S, Lewis A. Nanochemical Printing: Micrometer to 15 nm Printing of Metallic Inks with Fountain Pen Nanolithography (Small 1/2018). SmallSmall. 2018;14 (1) :n/a.
Layani M, Wang X, Magdassi S. Novel Materials for 3D Printing by Photopolymerization. Adv. Mater. (Weinheim, Ger.)Advanced Materials (Weinheim, Germany). 2018 :Ahead of Print.Abstract
The field of 3D printing, also known as additive manufg. (AM), is developing rapidly in both academic and industrial research environments. New materials and printing technologies, which enable rapid and multimaterial printing, have given rise to new applications and utilizations. However, the main bottleneck for achieving many more applications is the lack of materials with new phys. properties. Here, some of the recent reports on novel materials in this field, such as ceramics, glass, shape-memory polymers, and electronics, are reviewed. Although new materials have been reported for all three main printing approaches-fused deposition modeling, binder jetting or laser sintering/melting, and photopolymn.-based approaches, apparently, most of the novel physicochem. properties are assocd. with materials printed by photopolymn. approaches. Furthermore, the high resoln. that can be achieved using this type of 3D printing, together with the new properties, has resulted in new implementations such as microfluidic, biomedical devices, and soft robotics. Therefore, the focus here is on photopolymn.-based additive manufg. including the recent development of new methods, novel monomers, and photoinitiators, which result in previously inaccessible applications such as complex ceramic structures, embedded electronics, and responsive 3D objects. [on SciFinder(R)]
Perrin L, Ortega F, Rubio RG, Pajor-Swierzy A, Magdassi S, Kamyshny A, Ortega F, Rubio RG. Evaporation of Nanosuspensions on Substrates with Different Hydrophobicity. ACS Appl Mater InterfacesACS applied materials & interfaces. 2018;10 (3) :3082 - 3093.Abstract
Liquid drop evaporation on surfaces is present in many industrial and medical applications, e.g., printed electronics, spraying of pesticides, DNA mapping, etc. Despite this strong interest, a theoretical description of the dynamic of the evaporation of complex liquid mixtures and nanosuspensions is still lacking. Indeed, one of the aspects that have not been included in the current theoretical descriptions is the competition between the kinetics of evaporation and the adsorption of surfactants and/or particles at the liquid/vapor and liquid/solid interfaces. Materials formed by an electrically isolating solid on which a patterned conducting layer was formed by the deposits left after drop evaporation have been considered as very promising for building electrical circuits on flexible plastic substrates. In this work, we have done an exhaustive study of the evaporation of nanosuspensions of latex and hydrophobized silver nanoparticles on four substrates of different hydrophobicity. The advancing and receding contact angles as well as the time dependence of the volume of the droplets have been measured over a broad range of particle concentrations. Also, mixtures of silver particles and a surfactant, commonly used in industrial printing, have been examined. Furthermore, the adsorption kinetics at both the air/liquid and solid/liquid interfaces have been measured. Whereas the latex particles do not adsorb at the solid/liquid and only slightly reduce the surface tension, the silver particles strongly adsorb at both interfaces. The experimental results of the evaporation process were compared with the predictions of the theory of Semenov et al. (Evaporation of Sessile Water Droplets: Universal Behavior in the Presence of Contact Angle Hysteresis. Colloids Surf. Physicochem. Eng. Asp. 2011, 391 (1-3), 135-144) and showed surprisingly good agreement despite that the theory was developed for pure liquids. The morphology of the deposits left by the droplets after total evaporation was studied by scanning electronic microscopy, and the effects of the substrate, the particle nature, and their concentrations on these patterns are discussed.[on SciFinder (R)]
Shi L, Layani M, Cai X, Zhao H, Magdassi S, Lan M. An inkjet printed Ag electrode fabricated on plastic substrate with a chemical sintering approach for the electrochemical sensing of hydrogen peroxide. Sens. Actuators, BSensors and Actuators, B: Chemical. 2018;256 :938 - 945.Abstract
The trend of developing electrochem. sensors toward cellular level detection put forward higher requirements of the electrodes in the detection performance. However, common disk electrodes or conventional screen printing electrodes meet up with some limitations in the electrocatalytic activity and electron transfer capability. In this work, we applied inkjet printing technol. to fabricate electrodes to make some improvements. Highly conductive Ag nanoparticles based electrodes were obtained on plastic substrate by inkjet printing technol. followed by a sintering process at room temp. The resistivity of IPAgE is detd. to be 64.0 ± 5.3 μΩ cm. With better cond. and the nanoparticle-based interface, superb electrochem. response of IPAgE for H2O2 was obtained, nearly 300-fold higher than the conventional screen printed Ag electrode. Moreover, high sensitivity of 287 μA mM-1 cm-2 with a LOD of 5.0 μM was obtained under the optimized 20 printed layers. The inkjet printed Ag electrodes were also credibly applied in the detection of H2O2 release from living cells. This work demonstrates inkjet printing is a promising method for the high performance electrochem. sensors. [on SciFinder(R)]
Friedman-Levi Y, Eyal S, Larush L, Magdassi S, Diana M, Marchegiani F, Marescaux J, Goder N, Lahat G, Klausner J, et al. Optimization of liposomal indocyanine green for imaging of the urinary pathways and a proof of concept in a pig model. Surg EndoscSurgical endoscopy. 2018;32 (2) :963 - 970.Abstract
BACKGROUND: Iatrogenic ureteral injury is an increasing concern in the laparoscopic era, affecting both patient morbidity and costs. Current techniques enabling intraoperative ureteral identification require invasive procedures or radiations. Our aim was to develop a real-time, non-invasive, radiation-free method to visualize ureters, based on near-infrared (NIR) imaging. For this purpose, we interfered with the biliary excretion pathway of the indocyanine green (ICG) fluorophore by loading it into liposomes, enabling renal excretion. In this work, we studied various parameters influencing ureteral imaging. METHODS: Fluorescence intensity (FI) of various liposomal ICG sizes and doses were characterized in vitro and subsequently tested in vivo in mice and pigs. Quantification was performed by measuring FI in multiple points and applying the ureteral/retroperitoneum ratio (U/R). RESULTS: The optimal liposomal ICG loading dose was 20%, for the different liposomes' sizes tested (30, 60, 100 nm). Higher concentration of ICG decreased FI. In vivo, the optimal liposome size for ureteral imaging was 60 nm, which yielded a U/R of 5.2 ± 1.7 (p < 0.001 vs. free ICG). The optimal ICG dose was 8 mg/kg (U/R = 2.1 ± 0.4, p < 0.05 vs. 4 mg/kg). Only urine after liposomal ICG injection had a measurable FI, and not after free ICG injection. Using a NIR-optimized laparoscopic camera, ureters could be effectively imaged in pigs, from 10 min after injection and persisting for at least 90 min. Ureteral peristaltic waves could be clearly identified only after liposomal ICG injection. CONCLUSIONS: Optimization of liposomal ICG allowed to visualize enhanced ureters in animal models and seems a promising fluorophore engineering, which calls for further developments.[on SciFinder (R)]
Rosen YS, Magdassi S. Effect of Carboxylic Acids on Reactive Transfer Printing of Copper Formate Ink. MRS Adv.MRS Advances. 2018;3 (5) :261 - 267.Abstract
During decompn. of copper formate, a volatile intermediate is formed, that can be utilized to fabricate conductive copper lines for elec. interconnections. By the method called Reactive Transfer Printing (RTP), a pattern of copper (II) formate was printed, and placed adjacent to a second surface; decompn. of the printed pattern led to a transfer of copper to the second substrate. It was found that the yield of the transfer process improved due to presence of several carboxylic acids which are liq. with a high b.p. Furthermore we found that the transport of copper starts at a lower temp. than previously reported, indicating that the first decompn. step of copper formate is related to the catalytic decompn. of formic acid on a copper surface. The findings enable printing of conductive copper patterns onto the interior surface of a glass vessel. [on SciFinder(R)]
Perrin L, Pajor-Swierzy A, Magdassi S, Kamyshny A, Ortega F, Rubio RG. Evaporation of Nanosuspensions on Substrates with Different Hydrophobicity. ACS Appl. Mater. InterfacesACS Applied Materials & Interfaces. 2018;10 (3) :3082 - 3093.Abstract
Liq. drop evapn. on surfaces is present in many industrial and medical applications, e.g., printed electronics, spraying of pesticides, DNA mapping, etc. Despite this strong interest, a theor. description of the dynamic of the evapn. of complex liq. mixts. and nanosuspensions is still lacking. Indeed, one of the aspects that have not been included in the current theor. descriptions is the competition between the kinetics of evapn. and the adsorption of surfactants and/or particles at the liq./vapor and liq./solid interfaces. Materials formed by an elec. isolating solid on which a patterned conducting layer was formed by the deposits left after drop evapn. have been considered as very promising for building elec. circuits on flexible plastic substrates. In this work, we have done an exhaustive study of the evapn. of nanosuspensions of latex and hydrophobized silver nanoparticles on four substrates of different hydrophobicity. The advancing and receding contact angles as well as the time dependence of the vol. of the droplets have been measured over a broad range of particle concns. Also, mixts. of silver particles and a surfactant, commonly used in industrial printing, have been examd. Furthermore, the adsorption kinetics at both the air/liq. and solid/liq. interfaces have been measured. Whereas the latex particles do not adsorb at the solid/liq. and only slightly reduce the surface tension, the silver particles strongly adsorb at both interfaces. The exptl. results of the evapn. process were compared with the predictions of the theory of Semenov et al. (Evapn. of Sessile Water Droplets: Universal Behavior in the Presence of Contact Angle Hysteresis. Colloids Surf. Physicochem. Eng. Asp. 2011, 391 (1-3), 135-144) and showed surprisingly good agreement despite that the theory was developed for pure liqs. The morphol. of the deposits left by the droplets after total evapn. was studied by scanning electronic microscopy, and the effects of the substrate, the particle nature, and their concns. on these patterns are discussed. [on SciFinder(R)]
Zhou Y, Layani M, Wang S, Hu P, Ke Y, Magdassi S, Yi L. Fully Printed Flexible Smart Hybrid Hydrogels. Adv. Funct. Mater.Advanced Functional Materials. 2018;28 (9) :n/a.Abstract
A printable hybrid hydrogel is fabricated by embedding poly(N-isopropylacrylamide) (PNIPAm) microparticles within a water-rich silica-alumina(Si/Al)-based gel matrix. The hybrid gel holds water content of up to 70 wt%, due to its unique Si/Al matrix. The hybrid hydrogel can respond to both heat and elec. stimuli, and can be directly printed layer-by-layer using a com. 3-dimensional printer, without requiring any curing. The hybrid ink is printed onto a transparent, flexible conductive electrode composed of silver nanoparticles and sustains bending angles of up to 180°, which enables patterning of various flexible devices such as smart windows and a 3D optical waveguide valve. [on SciFinder(R)]
Halevi O, Tan JMR, Lee PS, Magdassi S. Hydrolytically Stable MOF in 3D-Printed Structures. Adv. Sustainable Syst.Advanced Sustainable Systems. 2018;2 (2) :n/a.Abstract
Metal-org. frameworks (MOFs) are a well-developed field of materials, having a high potential for various applications such as gas storage, water purifn., and catalysis. Despite the continuous discoveries of new MOFs, so far there are only a limited no. of industrial applications, partially due to their low chem. stability and limited mech. properties, as well as difficulties in integration within functional devices, Herein, a new approach is presented toward the fabrication of MOF-based devices, utilizing direct 3D printing. By this method, 3D, flexible, and hydrolytically stable MOF-embedded polymeric structures are fabricated. It is found that the adsorption capacity of the 3D-printed MOF is retained, with significantly improved hydrolytic stability of the printed MOFs (copper benzene-1,3,5-tricarboxylate) compared to the MOF only. It is expected that applying 3D printing technologies, for the fabrication of functional MOF objects such as filters and matrixes for columns and flow reactors, will open the way for utilization of this important class of materials. [on SciFinder(R)]
Liu C, Wang S, Zhou Y, Yang H, Lu Q, Mandler D, Magdassi S, Tay CY, Long Y. Index-tunable anti-reflection coatings: Maximizing solar modulation ability for vanadium dioxide-based smart thermochromic glazing. J. Alloys Compd.Journal of Alloys and Compounds. 2018;731 :1197 - 1207.Abstract
V dioxide (VO2) nanoparticles with reversible semiconductor-metal phase transition holds the tremendous potential as a thermochromic material for the energy-saving smart glazing. However, the trade-off between improving the luminous transmittance (Tlum) while sacrificing the solar modulation ability (ΔTsol) hampers its bench-to-market translation. Previous studies of anti-reflection coatings (ARCs) focused primarily on increasing Tlum while neglecting ΔTsol, which is a key energy-saving determinant. The intrinsically low ΔTsol (<16%) is due to the fact that VO2 has a higher refractive index (RI) from 500 nm to 2200 nm wavelength (λ) below its crit. transition temp. (τc), which causes excessive reflection at a lower temp. This study aims to study ARCs with tunable RI (1.47-1.92 at λ = 550 nm) to improve the antireflection effect at a lower temp., thereby maximizing ΔTsol for various VO2 nanosubstrates, e.g. continuous thin films, nanocomposites, and periodic micro-patterning films. The best performing coatings could maximize ΔTsol (from 15.7% to 18.9%) and increase Tlum(avg) (from 39% to 44%) simultaneously, which surpasses the current bench-mark specifications ever reported for ARC-coated VO2 smart glazing. The cytotoxicity analyses evidence that ARCs are feasible to improve the cyto-compatibility of VO2 nanoparticles-based nanocomposites. The presented RI-tunable ARC, which circumvents the complex materials selection and optical design, not only paves the way for practical applications of VO2-based smart windows but also has extensive applications in the field of solar cells, optical lenses, smart display, etc. [on SciFinder(R)]
Yeshua T, Layani M, Dekhter R, Huebner U, Magdassi S, Lewis A. Micrometer to 15 nm Printing of Metallic Inks with Fountain Pen Nanolithography. SmallSmall. 2018;14 (1) :n/a.Abstract
The field of printed electronics is continually trying to reduce the dimensions of the elec. components. Here, a method of printing metallic lines with widths as small as 15 nm and up to a few micrometers using fountain pen nanolithog. (FPN) is shown. The FPN technique is based on a bent nanopipette with at. force feedback that acts similar to a nanopen. The geometry of the nanopen allows for rapid placement accuracy of the printing tip, on any desired location, with the highest of optical sub-micrometer resoln. Using this nanopen, investigations of various inks are undertaken together with instrumental and script-tool development that allows accurate printing of multiple layers. This has led to the printing of conductive lines using inks composed of silver nanoparticles and salt solns. of silver and copper. In addn., it is shown that the method can be applied to substrates of various materials with minimal effect on the dimension of the line. The line widths are varied by using nanopens with different orifices or by tailoring the wetting properties of the ink on the substrate. Metallic interconnections of conducting lines are reported. [on SciFinder(R)]
Agarwala S, Lee JM, Ng WL, Layani M, Yeong WY, Magdassi S. A novel 3D bioprinted flexible and biocompatible hydrogel bioelectronic platform. Biosens. Bioelectron.Biosensors & Bioelectronics. 2018;102 :365 - 371.Abstract
Bioelectronics platforms are gaining widespread attention as they provide a template to study the interactions between biol. species and electronics. Decoding the effect of the elec. signals on the cells and tissues holds the promise for treating the malignant tissue growth, regenerating organs and engineering new-age medical devices. This work is a step forward in this direction, where bio- and electronic materials co-exist on one platform without any need for post processing. We fabricate a freestanding and flexible hydrogel based platform using 3D bioprinting. The fabrication process is simple, easy and provides a flexible route to print materials with preferred shapes, size and spatial orientation. Through the design of interdigitated electrodes and heating coil, the platform can be tailored to print various circuits for different functionalities. The biocompatibility of the printed platform is tested using C2C12 murine myoblasts cell line. Furthermore, normal human dermal fibroblasts (primary cells) are also seeded on the platform to ascertain the compatibility. [on SciFinder(R)]
Li W, Tan JMR, Leow SW, Lie S, Magdassi S, Wong LH. Recent Progress in Solution-Processed Copper-Chalcogenide Thin-Film Solar Cells. Energy Technol. (Weinheim, Ger.)Energy Technology (Weinheim, Germany). 2018;6 (1) :46 - 59.Abstract
Soln.-based thin-film semiconductors offer a promising path for the mass prodn. of low-cost solar cells prepd. at low temps. Thin-film Cu-based chalcogenides such as Cu(In,Ga)(S,Se)2 (CIGSSe) and Cu2ZnSn(S,Se)4 (CZTSSe) hold great promise and have been regarded as viable candidates because of the abundance of their constituent elements and environmentally nontoxic nature. This Review summarizes the recent progress in soln.-processed Cu chalcogenides (CuInSe2, Cu(In,Ga)(S,Se)2, Cu2ZnSnS4, Cu2ZnSn(S,Se)4) for thin-film solar cells, with emphasis on the precursor soln. deposited by spray pyrolysis and spin coating. The general aspects, current status, and recent research highlights are introduced and analyzed in detail. Finally, the challenges and future prospects of these solar cells are also discussed. [on SciFinder(R)]

Pages