Numerical simulation of laser-generated ultrasound by the finite element method

Xu, Bo; Shen, Zhonghua; Ni, Xiaowu; Lü, Jian

doi:10.1063/1.1637712

Cited by 98 publications

(49 citation statements)

References 11 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…45,50 For small laser pulse energy, below the ablation regime, sudden thermal expansion of the surface of a material generates elastic waves. 45,48,49,[51][52][53][54][55][56] Here, considering the two generation mechanisms, elastic wave energy is discussed for point normal loading and dipole loading, as shown in Fig. 4.…”

Section: Relationship Between Source Position and Energy Generatedmentioning

confidence: 99%

“…Elastic waves are generated in a solid medium by a laser through one of two mechanisms: ablation or the thermoelastic effect. [42][43][44][45][46][47][48][49][50][51][52][53] For large pulse energy, a sudden laser energy input induces plasma emission from the surface of a material, and a normal force is instantaneously loaded as a reaction force of the plasma emission. 45,50 For small laser pulse energy, below the ablation regime, sudden thermal expansion of the surface of a material generates elastic waves.…”

Section: Relationship Between Source Position and Energy Generatedmentioning

confidence: 99%

See 1 more Smart Citation

Vibration energy analysis of a plate for defect imaging with a scanning laser source technique

Hayashi

Fukuyama

2016

The Journal of the Acoustical Society of America

View full text Add to dashboard Cite

Vibration energies generated by laser irradiation to a plate with a crack were calculated by the semi-analytical finite element method to elucidate the principle of defect imaging using a scanning laser source. For normal incidence in the ablation regime, the incident energy increases when the incident source is located in the vicinity of the crack, owing to the effect of the non-propagating A1 modes. For dipole loading in the thermoelastic regime, the vibration energies are completely different, depending on the position of the crack opening. If the crack opening is located opposite the incident source, the vibration energy increases abruptly in the vicinity of the crack, which is affected by the higher-order non-propagating modes as well as the A1 modes. When the crack opening and the incident source are located on the same side, the generated energy approaches zero as the source moves closer to the crack. The energy reduction around the crack is caused by the superposition of the incident wave from dipole loading and the phase-inverted reflected wave. The results of experiments conducted to verify the energy variations in the vicinity of a crack were in good agreement with the numerical results for dipole loading.

show abstract

Section: Relationship Between Source Position and Energy Generatedmentioning

confidence: 99%

Section: Relationship Between Source Position and Energy Generatedmentioning

confidence: 99%

Vibration energy analysis of a plate for defect imaging with a scanning laser source technique

Hayashi

Fukuyama

2016

The Journal of the Acoustical Society of America

View full text Add to dashboard Cite

show abstract

“…This velocity compares favorably with the Rayleigh SAW velocity of the glass substrates, 3100 m/s for soda lime glass. The upper branch, propagating at a velocity of 5590 ± 15 m/s, is the in-plane longitudinal acoustic wave, which has been termed previously as a surface skimming longitudinal wave (SSLW) [10], or the surface skimming bulk wave (SSBW) [11], an elastic excitation that has been used extensively for nondestructive material evaluation [12,13]. Again, the velocity is very close to the longitudinal sound velocity in glass (literature value 5400 m/s) due to the predominant concentration of elastic energy in the substrate.…”

Section: Experimental Techniquementioning

confidence: 99%

Ultrafast magnetoelastic probing of surface acoustic transients

et al. 2016

View full text Add to dashboard Cite

We generate in-plane magnetoelastic waves in nickel films using the all-optical transient grating technique. When performed on amorphous glass substrates, two dominant magnetoelastic excitations can be resonantly driven by the underlying elastic distortions, the Rayleigh surface acoustic wave and the surface skimming longitudinal wave. An applied field, oriented in the sample plane, selectively tunes the coupling between magnetic precession and one of the elastic waves, thus demonstrating selective excitation of coexisting, large-amplitude magnetoelastic waves. Analytical calculations based on the Green's function approach corroborate the generation of multiple surface acoustic transients with disparate decay dynamics.

show abstract

Section: Introductionmentioning

confidence: 99%

“…Laser ultrasonics uses a short laser pulse as a remote ultrasound input to excite thermal expansion, and then induces ultrasonic waves on surfaces, which contains the information of elastic properties. This technology has been widely used in industry to detect the surface condition of metallic materials and obtain relative mechanical properties of coatings [1][2][3][4][5].Laser ultrasonics has potential to quantify mechanical properties of skin for diagnosis and accurate assessment of skin diseases [6][7]. In skin laser ultrasonics, the study of thermal interaction between a laser pulse and skin becomes a very essential part for the following two reasons:…”

mentioning

confidence: 99%

Skin Thermal Effect by FE Simulation and Experiment of Laser Ultrasonics

Huang

et al. 2010

AMM

View full text Add to dashboard Cite

Abstract. Laser ultrasonics opened possibilities to measure thermal and mechanical property of skin which occupies an essential position and is beneficial in industrial and medical applications. This paper focuses on the thermal effect in the thermal section of the laser ultrasonic technique. A transient thermal analysis is developed and promoted to simulate the interaction between the laser pulse and human skin, using a multilayered finite element model (FEM). Chicken leg had been used and irradiated by KrF laser, the thermal reactions were detected and recorded by a thermal camera. By comparison, the thermal result of experiments and simulation matches. IntroductionThe study and research of the mechanical properties of different materials occupies an essential position in many engineering and industrial applications. Laser ultrasonics uses a short laser pulse as a remote ultrasound input to excite thermal expansion, and then induces ultrasonic waves on surfaces, which contains the information of elastic properties. This technology has been widely used in industry to detect the surface condition of metallic materials and obtain relative mechanical properties of coatings [1][2][3][4][5].Laser ultrasonics has potential to quantify mechanical properties of skin for diagnosis and accurate assessment of skin diseases [6][7]. In skin laser ultrasonics, the study of thermal interaction between a laser pulse and skin becomes a very essential part for the following two reasons:Firstly, it is of great importance to understand the relationships between increased temperature and laser energy along with other parameters (e.g. shape and duration) in terms of the laser safety. Subsequently, the range of safe laser energy and its relative parameters should be defined in order to avoid skin ablation even skin damage.Secondly, the amplitude of laser generated surface waves increases with increasing laser energy. It is important that the laser energy should be kept sufficient to produce ultrasonic waves which are readily detectable by available measurement tools such as interferometers and high frequency ultrasound transducers which allows the generated surface waves to be recorded and analysed .The finite element model provides a clear and detailed process of the thermal effect in skin laser ultrasonics. The previous work shows that the thermal effect of laser-skin interaction is subject to the thermal properties of tested materials and the parameters of laser pulses including the energy,

show abstract

Numerical simulation of laser-generated ultrasound by the finite element method

Cited by 98 publications

References 11 publications

Vibration energy analysis of a plate for defect imaging with a scanning laser source technique

Vibration energy analysis of a plate for defect imaging with a scanning laser source technique

Ultrafast magnetoelastic probing of surface acoustic transients

Skin Thermal Effect by FE Simulation and Experiment of Laser Ultrasonics

Contact Info

Product

Resources

About