Rapid Printing of High-Temperature Polymer-Derived Ceramic Composite Thin-Film Thermistor with Laser Pyrolysis

Xu, Lida; Li, Lanlan; Tang, Lantian; Zeng, Yingjun; Chen, Guochun; Shao, Chenhe; Wu, Chao; He, Gonghan; Chen, Qinnan; Fang, Guicai; Sun, Di; Hai, Zhenyin

doi:10.1021/acsami.2c20927

Cited by 13 publications

(6 citation statements)

References 67 publications

(127 reference statements)

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“…Finally, we used the electrical resistance characteristics of thin-film sensors to characterize the performance of ablation process coating. The thin-film coating was applied to the sensitive layer as an antioxidation layer forming a double-layer structure [ 16 ]. Figure 14 a illustrates the optical image of the sensor prior to ablation, displaying a predominantly light yellow surface.…”

Section: Resultsmentioning

confidence: 99%

Oxidation and Ablation Behavior of Particle-Filled SiCN Precursor Coatings for Thin-Film Sensors

Li,

He,

et al. 2023

Polymers

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Polymer-derived ceramic (PDC) thin-film sensors have a very high potential for extreme environments. However, the erosion caused by high-temperature airflow at the hot-end poses a significant challenge to the stability of PDC thin-film sensors. Here, we fabricate a thin-film coating by PDC/TiB2/B composite ceramic material, which can be used to enhance the oxidation resistance and ablation resistance of the sensors. Due to the formation of a dense oxide layer on the surface of the thin-film coating in a high-temperature air environment, it effectively prevents the ingress of oxygen as a pivotal barrier. The coating exhibits an exceptionally thin oxide layer thickness of merely 8 μm, while its oxidation resistance was rigorously assessed under air exposure at 800 °C, proving its enduring protection for a minimum duration of 10 h. Additionally, during ablation testing using a flame gun that can generate temperatures of up to 1000 °C, the linear ablation rate of thin-film coating is merely 1.04 μm/min. Our analysis reveals that the volatilization of B2O3 occurs while new SiO2 is formed on the thin-film coating surface. This phenomenon leads to the absorption of heat, thereby enhancing the ablative resistance performance of the thin-film sensor. The results indicate that the thin-film sensor exhibits exceptional resistance to oxidation and ablation when protected by the coating, which has great potential for aerospace applications.

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Section: Resultsmentioning

confidence: 99%

Oxidation and Ablation Behavior of Particle-Filled SiCN Precursor Coatings for Thin-Film Sensors

Li,

He,

et al. 2023

Polymers

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“…Flexible temperature sensors usually are manufactured based on thermocouples, metal-based resistance temperature detectors, and thermistors. − The thermistor-based temperature sensors have the advantages of high sensitivity, cost efficiency, miniaturization, and rapid response time and usually behave with the property of negative temperature coefficient (NTC) of resistance . Traditional thermistors are sintered by transition-metal oxide ceramic materials like Mn-spinel oxide in a thin film, which requires high fabrication temperature. , Meanwhile, a high fabrication temperature prevents the sintered thermistors from deposition on the flexible substrates and leads to high energy consumption and increasing cost.…”

Section: Introductionmentioning

confidence: 99%

“…It is vitally significant to develop a novel fabrication process of flexible thermistors to overcome those drawbacks. Laser direct writing (LDW), with the advantage of nonmasks, one-step patterning, and high accuracy, is quite suitable for manufacturing flexible electronics facilely and efficiently on a large scale in the room-temperature range. ,− The LDW process has a huge potential for fabricating flexible metal oxide thermistors.…”

Section: Introductionmentioning

confidence: 99%

Flexible Copper-Based Thermistors Fabricated by Laser Direct Writing for Low-Temperature Sensing

Peng,

Guo,

Liu

et al. 2024

ACS Appl. Mater. Interfaces

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With the flexibilization tendency of traditional electronics, developing sensing devices for the low-temperature field is demanding. Here, we fabricated a flexible copper-based thermistor by a laser direct writing process with Cu ion precursors. The copper-based thermistor performs with excellent temperature sensing ability and high stability under different environments. We discussed the effect of laser power on the temperature sensitivity of the copper-based thermistor, explained the sensing mechanism of the as-written copper-based films, and fabricated a temperature sensor array for realizing temperature management in a specific zone. All of the investigations have demonstrated that such copper-based thermistors can be used as candidate devices for low-temperature sensing fields.

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Section: Introductionmentioning

confidence: 99%

“…Real-time monitoring of the surface strain state of aero-engine turbine blades and other structures in high-temperature environments is critical for their ground testing and lifetime prediction. , In the field of high-temperature strain sensing, the conventional options mainly include discrete strain gauges, berth-type resistance strain gauges, and fiber Bragg gratings. − The discrete strain gauges are primarily fixed on the surface of the measured structure through installation or tape, which causes creep errors and interferes with the flow field. − Embedding fiber Bragg gratings into metal structures can adversely impact the structural integrity of the components and increase the risk of damage . Therefore, these strain gauges have struggled to meet the demand for in situ strain monitoring of hot-end components.…”

Section: Introductionmentioning

confidence: 99%

All-Three-Dimensionally-Printed AgPd Thick-Film Strain Gauge with a Glass–Ceramic Protective Layer for High-Temperature Applications

Zeng,

Chen,

Zhao

et al. 2023

ACS Appl. Mater. Interfaces

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A high-temperature thin/thick-film strain gauge (TFSG) shows development prospects for in situ strain monitoring of hot-end components due to their small perturbations, no damage, and fast response. Direct ink writing (DIW) 3D printing is an emerging and facile approach for the rapid fabrication of TFSG. However, TFSGs prepared based on 3D printing with both high thermal stability and low temperature coefficient of resistance (TCR) over a wide temperature range remain a great challenge. Here, we report a AgPd TFSG with a glass–ceramic protective layer based on DIW. By encapsulating the AgPd sensitive layer and regulating the Pd content, the AgPd TFSG demonstrated a low TCR (191.6 ppm/°C) from 50 to 800 °C and ultrahigh stability (with a resistance drift rate of 0.14%/h at 800 °C). Meanwhile, the achieved specifications for strain detection included a strain sensing range of ±500 με, fast response time of 153 ms, gauge factor of 0.75 at 800 °C, and high durability of >8000 cyclic loading tests. The AgPd TFSG effectively monitors strain in superalloys and can be directly deposited onto cylindrical surfaces, demonstrating the scalability of the presented approach. This work provides a strategy to develop TFSGs for in situ sensing of complex curved surfaces in harsh environments.

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Rapid Printing of High-Temperature Polymer-Derived Ceramic Composite Thin-Film Thermistor with Laser Pyrolysis

Cited by 13 publications

References 67 publications

Oxidation and Ablation Behavior of Particle-Filled SiCN Precursor Coatings for Thin-Film Sensors

Oxidation and Ablation Behavior of Particle-Filled SiCN Precursor Coatings for Thin-Film Sensors

Flexible Copper-Based Thermistors Fabricated by Laser Direct Writing for Low-Temperature Sensing

All-Three-Dimensionally-Printed AgPd Thick-Film Strain Gauge with a Glass–Ceramic Protective Layer for High-Temperature Applications

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