Structure, electrical characteristics, and high-temperature stability of aerosol jet printed silver nanoparticle films

Rahman, Taibur; McCloy, John S.; Ramana, C. V.; Panat, Rahul

doi:10.1063/1.4960779

Cited by 56 publications

(44 citation statements)

References 50 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Studies to date have leveraged a limited set of characterization methods to correlate printed thin film electrical performance with microstructure [72,74,[87][88][89]. A more comprehensive set of characterization methods shown in Tables 4 and 5 must be employed to establish a better understanding of the kinetics and growth mechanisms during sintering to achieve thin film conductivities near-bulk values for AM-printed metal film lines.…”

Section: Characterization Methods and Figures Of Meritmentioning

confidence: 99%

“…Studies by Rahman et al correlated microstructuralelectrical properties of AJP Ag NP thin films at high temperatures [87]. They determined that optimization of sintering conditions could provide efficient means to control the temperature stability and oxidation resistance of the Ag NP thin films up to a temperature of 500°C.…”

Section: Materials For DC and Rf: Structure-propertymentioning

confidence: 99%

See 1 more Smart Citation

Printable Materials for the Realization of High Performance RF Components: Challenges and Opportunities

Rosker

Sandhu

Hester

et al. 2018

International Journal of Antennas and Propagation

View full text Add to dashboard Cite

Printing methods such as additive manufacturing (AM) and direct writing (DW) for radio frequency (RF) components including antennas, filters, transmission lines, and interconnects have recently garnered much attention due to the ease of use, efficiency, and low-cost benefits of the AM/DW tools readily available. The quality and performance of these printed components often do not align with their simulated counterparts due to losses associated with the base materials, surface roughness, and print resolution. These drawbacks preclude the community from realizing printed low loss RF components comparable to those fabricated with traditional subtractive manufacturing techniques. This review discusses the challenges facing low loss RF components, which has mostly been material limited by the robustness of the metal and the availability of AM-compatible dielectrics. We summarize the effective printing methods, review ink formulation, and the postprint processing steps necessary for targeted RF properties. We then detail the structure-property relationships critical to obtaining enhanced conductivities necessary for printed RF passive components. Finally, we give examples of demonstrations for various types of printed RF components and provide an outlook on future areas of research that will require multidisciplinary teams from chemists to RF system designers to fully realize the potential for printed RF components.

show abstract

Section: Characterization Methods and Figures Of Meritmentioning

confidence: 99%

Section: Materials For DC and Rf: Structure-propertymentioning

confidence: 99%

Printable Materials for the Realization of High Performance RF Components: Challenges and Opportunities

Rosker

Sandhu

Hester

et al. 2018

International Journal of Antennas and Propagation

View full text Add to dashboard Cite

show abstract

“…The second challenge of AJP for thin, multilayer printing is identifying key parameters to control print profiles to prevent shorting between conductive layers. [22] However, the PMMA layer required for transfer to elastomer may be damaged and prevent transfer due to excessive exposure to high temperatures. The previously reported AJP-enabled structure [21] relied on a thick layer deposition for preventing shorting between conductive layers, but lowered sensitivity.…”

Section: Optimization Of Multilayer Ajp For Capacitive Sensormentioning

confidence: 99%

“…Optimization of relevant parameters in the inductive coupling system is performed by analytical and computational calculations. [22] X-ray diffraction study of the two printed silver layers indicates the extra sintering time (2 h) for the bottom AgNP layer does not significantly change its composition ( Figure 1F). The sensor is demonstrated in two highly contoured biomimetic cerebral aneurysm models, indicating high sensitivity to incoming aneurysm flow.…”

Section: Introductionmentioning

confidence: 99%

Fully Printed, Wireless, Stretchable Implantable Biosystem toward Batteryless, Real‐Time Monitoring of Cerebral Aneurysm Hemodynamics

et al. 2019

View full text Add to dashboard Cite

This study introduces a high‐throughput, large‐scale manufacturing method that uses aerosol jet 3D printing for a fully printed stretchable, wireless electronics. A comprehensive study of nanoink preparation and parameter optimization enables a low‐profile, multilayer printing of a high‐performance, capacitance flow sensor. The core printing process involves direct, microstructured patterning of biocompatible silver nanoparticles and polyimide. The optimized fabrication approach allows for transfer of highly conductive, patterned silver nanoparticle films to a soft elastomeric substrate. Stretchable mechanics modeling and seamless integration with an implantable stent display a highly stretchable and flexible sensor, deployable by a catheter for extremely low‐profile, conformal insertion in a blood vessel. Optimization of a transient, wireless inductive coupling method allows for wireless detection of biomimetic cerebral aneurysm hemodynamics with the maximum readout distance of 6 cm through meat. In vitro demonstrations include wireless monitoring of flow rates (0.05–1 m s−1) in highly contoured and narrow human neurovascular models. Collectively, this work shows the potential of the printed biosystem to offer a high throughput, additive manufacturing of stretchable electronics with advances toward batteryless, real‐time wireless monitoring of cerebral aneurysm hemodynamics.

show abstract

“…dispersions) for this printing method. 1,17 The Ag nanoparticle size in the ink was 30-50 nm, the ink viscosity was about 1.5 cP, and the Ag particle loading in the ink was about 40 ± 2 wt %. The solvents used for this ink were de-ionized (DI) water and ethylene glycol.…”

Section: Methodsmentioning

confidence: 99%

CMU Array: A 3D Nano-Printed, Customizable Ultra-High-Density Microelectrode Array Platform

Saleh

Ritchie

Nicholas

et al. 2019

Preprint

View full text Add to dashboard Cite

Microelectrode arrays (MEAs) provide the means to record electrophysiological activity fundamental to both basic and clinical neuroscience (e.g. brain-computer interfaces). Despite recent advances, current MEAs have significant limitations -including recording density, fragility, expense, and the inability to optimize the probe to individualized study or patient needs.Here we address the technological limitations through the utilization of the newest developments in 3D nanoparticle printing. 1 Our 'CMU Arrays' possess previously impossible electrode densities (> 6000 channels/cm 2 ) with tip diameters as small as 10µm. Most importantly, the probes are entirely customizable owing to the adaptive manufacturing process. Any combination of individual shank lengths, impedances, and layouts are possible. This is achieved in part via our new multi-layer, multi material, custom 3D-printed circuit boards, a fabrication advancement in itself. This device design enables new experimental avenues of targeted, large-scale recording of electrical signals from a variety of biological tissues.

show abstract

Structure, electrical characteristics, and high-temperature stability of aerosol jet printed silver nanoparticle films

Cited by 56 publications

References 50 publications

Printable Materials for the Realization of High Performance RF Components: Challenges and Opportunities

Printable Materials for the Realization of High Performance RF Components: Challenges and Opportunities

Fully Printed, Wireless, Stretchable Implantable Biosystem toward Batteryless, Real‐Time Monitoring of Cerebral Aneurysm Hemodynamics

CMU Array: A 3D Nano-Printed, Customizable Ultra-High-Density Microelectrode Array Platform

Contact Info

Product

Resources

About