Multi-material additive manufacturing of low sintering temperature Bi2Mo2O9ceramics with Ag floating electrodes by selective laser burnout

Gheisari, Reza; Chamberlain, Henry; Chi-Tangyie, George; Zhang, Shiyu; Goulas, Athanasios; Lee, Chih‐Kuo; Whittaker, Tom; Wang, Dawei; Ketharam, Annapoorani; Ghosh, Avishek; Vaidhyanathan, Bala; Whittow, William G.; Cadman, Darren; Vardaxoglou, Yiannis; Reaney, Ian M.; Engstrøm, Daniel S.

doi:10.1080/17452759.2019.1708026

Cited by 31 publications

(26 citation statements)

References 53 publications

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“…Using this method, a 3D-printed structure of Bi 2 Mo 2 O 9 with floating Ag electrodes has been successfully fabricated. 49 Another potential application of ceramics AM is in microelectronic packaging, where current scale limitations are limiting the miniaturization of 3D designs, causing technological bottlenecks. One needs to be able to machine features smaller than 10 μm.…”

Section: Electronicsmentioning

confidence: 99%

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Materials research & measurement needs for ceramics additive manufacturing

2020

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We report on a recent workshop dedicated to additive manufacturing (AM) of ceramics that was held at the National Institute of Standards and Technology (NIST) in November 2019. This two‐day all‐invited meeting brought together experts from industry, government agencies and academia to review the state of the field and identify the most pressing applied materials research and metrology issues which, if addressed, could accelerate the incorporation of AM methods into commercial ceramic manufacturing. Besides the AM technologies, the discussions included consideration of the necessary post‐processing steps. We highlight some of the successes and challenges for the adoption of ceramics AM on an industrial scale, as viewed by the workshop participants. We also propose actions for the ceramic community to facilitate the wider commercialization of these fabrication methods.

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Section: Electronicsmentioning

confidence: 99%

“…A slurry‐based 3D printing process using selective laser burnout (SLB) of Bi 2 Mo 2 O 9 could achieve satisfactory microstructures, high dielectric constants, and low losses. Using this method, a 3D‐printed structure of Bi 2 Mo 2 O 9 with floating Ag electrodes has been successfully fabricated 49 …”

Section: Application‐specific Challengesmentioning

confidence: 99%

Materials research & measurement needs for ceramics additive manufacturing

2020

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“…[2][3][4][5] Low-temperature co-fired ceramics (LTCC, 700-900 °C sintering temperature) and ultra-low temperature co-fired ceramics (ULTCC, 400-600 °C sintering temperature) can be co-sintered with low cost electrodes (Ag, Cu and Al, etc.). [6][7][8][9][10][11][12][13][14][15] To date, temperature-stable MW ceramics cannot be directly integrated onto polymer-based printed circuit boards (PCBs) in a single deposition step from powder. To revolutionize radio frequency (RF) manufacturing therefore, low loss (high quality factor, Qf ≥ 3000 GHz), temperature-stable (low temperature coefficient of resonant frequency, TCF = +/-3 ppm/°C), medium permittivity (8 < εr < 40) are required that densify at <200 °C and permit printing/pressing directly onto PCBs, reducing the costs and energy used in manufacturing and increasing functionality.…”

Section: Introductionmentioning

confidence: 99%

Direct Integration of Cold Sintered, Temperature-Stable Bi2Mo2O9-K2MoO4 Ceramics on Printed Circuit Boards for Satellite Navigation Antennas

Wang

Siame

Zhang

et al. 2020

Journal of the European Ceramic Society

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Bi2Mo2O9-K2MoO4 (BMO-KMO) composite ceramics with >95% theoretical density were densified by cold sintering at 150 °C. XRD, Raman, back-scattered SEM and EDX spectroscopy indicated that the BMO and KMO phases coexisted in all composites without inter-diffusion and secondary phases. Temperature coefficient of resonant frequency with near-zero value ~ -1 ppm/°C was acheived for BMO-10%KMO with pemittivity ~ 31 and quality factor ~ 3,000 GHz.Cold-sintered composite ceramics were directly pressed/integrated onto a printed circuit board (PCB) using the Cu metallisation as a ground plane for the design and fabrication of a circularly polarized microstrip patch antenna suitable for satellite navigation systems which achieved efficiencies 87% at 1561 MHz (BeiDou) and 88% at 1575 MHz (GPS/Galileo). The low cost, low energy integration of temperature stable, cold sintered ceramics directly onto a PCB represents a step change in substrate fabrication technology for RF devices.

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“…Therefore, printing multifunctional materials (e.g., ferromagnetic, piezoelectric) and hybrid structures is still a major challenge. [17,[26][27][28][29][30][31][32][33][34][35] Direct printing of multifunctional materials and composites such as titanium dioxdie (TiO 2 ), [36][37][38][39][40][41][42] barium titanate (BTO), [43][44][45] indium tin oxide (ITO) [11,46] opens a new pathway toward the direct manufacturing of devices with complex functionality. This has led to the emergence of laser-based additive nanomanufacturing (ANM) as a promising approach that could enable the synthesis and patterning of a variety of materials with micro/nanoscale resolutions.…”

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confidence: 99%

Additive Nanomanufacturing of Multifunctional Materials and Patterned Structures: A Novel Laser‐Based Dry Printing Process

Ahmadi

Lee

Unocic

et al. 2021

Adv Materials Technologies

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Direct printing of functional materials, structures, and devices on various platforms such as flexible to rigid substrates is of interest for applications ranging from electronics to energy and sensing to biomedical devices. Current additive manufacturing (AM) and printing processes are either limited by the available sources of functional materials or require to be in the form of precisely designed inks. Here, a novel laser‐based additive nanomanufacturing (ANM) system capable of in situ and on‐demand generations of nanoparticles that can serve as nanoscale building blocks for real‐time sintering and dry printing a variety of multifunctional materials and patterns at atmospheric pressure and room temperature is reported. The ability to print different functional materials on various rigid and flexible platforms is shown. This nonequilibrium process involves pulsed laser ablation of targets and in situ formation of pure amorphous nanoparticles’ stream that are guided through a nozzle onto the surface of the substrate, where they are sintered/crystallized in real‐time. Further, the process–structure relationship of the printed materials from nanoscale to microscale is shown. This new ANM concept opens up an opportunity for printing advanced functional materials and devices on rigid and flexible substrates that can be employed both on the earth and in space.

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Multi-material additive manufacturing of low sintering temperature Bi₂Mo₂O₉ceramics with Ag floating electrodes by selective laser burnout

Cited by 31 publications

References 53 publications

Materials research & measurement needs for ceramics additive manufacturing

Materials research & measurement needs for ceramics additive manufacturing

Direct Integration of Cold Sintered, Temperature-Stable Bi2Mo2O9-K2MoO4 Ceramics on Printed Circuit Boards for Satellite Navigation Antennas

Additive Nanomanufacturing of Multifunctional Materials and Patterned Structures: A Novel Laser‐Based Dry Printing Process

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