Revealing the interaction mechanism of pulsed laser processing with the application of acoustic emission

Liu, Weinan; Rong, Youmin; Yang, Ranwu; Wu, Congyi; Zhang, Guojun; Huang, Yu

doi:10.1007/s12200-023-00070-7

Cited by 2 publications

(1 citation statement)

References 38 publications

(34 reference statements)

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“…and carbon (graphene oxide, Mxene) [ 9 , 10 , 16 , 17 ]. Currently, numerous applications of LDW technology have been reported for flexible sensor manufacturing of various types, such as for temperature [ 18 , 19 ], mechanical [ 20 – 22 ], acoustic [ 23 , 24 ], optical [ 25 – 27 ], gas [ 28 , 29 ] and biosensor [ 30 , 31 ] detection. To name a few, Shin and coauthors [ 18 ] demonstrate the Ni/NiO based temperature sensor through LDW method.…”

Section: Introductionmentioning

confidence: 99%

All laser direct writing process for temperature sensor based on graphene and silver

Li,

Bai,

Guo

et al. 2024

Front. Optoelectron.

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A highly sensitive temperature sensing array is prepared by all laser direct writing (LDW) method, using laser induced silver (LIS) as electrodes and laser induced graphene (LIG) as temperature sensing layer. A finite element analysis (FEA) photothermal model incorporating a phase transition mechanism is developed to investigate the relationship between laser parameters and LIG properties, providing guidance for laser processing parameters selection with laser power of 1–5 W and laser scanning speed (greater than 50 mm/s). The deviation of simulation and experimental data for widths and thickness of LIG are less than 5% and 9%, respectively. The electrical properties and temperature responsiveness of LIG are also studied. By changing the laser process parameters, the thickness of the LIG ablation grooves can be in the range of 30–120 μm and the resistivity of LIG can be regulated within the range of 0.031–67.2 Ω·m. The percentage temperature coefficient of resistance (TCR) is calculated as − 0.58%/°C. Furthermore, the FEA photothermal model is studied through experiments and simulations data regarding LIS, and the average deviation between experiment and simulation is less than 5%. The LIS sensing samples have a thickness of about 14 μm, an electrical resistivity of 0.0001–100 Ω·m is insensitive to temperature and pressure stimuli. Moreover, for a LIS-LIG based temperature sensing array, a correction factor is introduced to compensate for the LIG temperature sensing being disturbed by pressure stimuli, the temperature measurement difference is decreased from 11.2 to 2.6 °C, indicating good accuracy for temperature measurement. Graphical Abstract

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