Mechanism of audible sound generation during flash lamp operation Ushio Inc. R&D center Tetsuya Kitagawa, Mitsuru Ikeuchi, Yukihiro Morimoto, Fumihiko Oda
Features Pulsed light source High peak power Good color rendering properties 1. High peak power 2. Very short period irradiation (Radiates from the UV to the IR light! ) Solid-state laser pumping Xe flash lamps Relative intensity / a.u. For industrial applications 1.0 0.8 0.6 0.4 0.2 0 200 400 600 800 Wavelength / nm 1000
Xe flash lamps Features Pulsed light source High peak power Good color rendering properties For industrial applications 1. High peak power 2. Very short period irradiation (Radiates from the UV to the IR light! ) Solid-state laser pumping Strobes (Camera) Cure of adhesive agent (DVD) Toner fixing (Copy machine) Thermal treatment of MOSFET
Activation process of an implanted Si wafer p+ Poly-Si Gate Gate Oxide Source p+ p+ Drain p+ p+ n well P - Si Extension (Xj 14nm) Schematic cross sectional view of P- MOS FLA machine for 12 inch wafer (Courtesy of Dainippon Screen MFG.,Co.,Ltd)
Purpose Xe flash lamp USJ formation FLA flash lamp annealing Pulse width 1 ms Energy density on a wafer surface 25 J/cm 2 When flash lamp is operated, significant audible sound is generated the sound generation mechanism has NOT been clarified Purpose To clarify the mechanism of the sound generation
Models of the sound generation Mechanical vibration of the flash lamp tube An object will vibrate and become a sound source, if it is rubbed or struck. 2. Due to the light radiated from the lamp Test experiment Selection of tube materials VUV lamp O 3 free lamp UFQ-75002 Ushio Inc. Two types of the lamps, The intensities of the sound differ.
Experimental set up Precision sound level meter Microphone Outer tube synthetic silica glass Flash lamp Osilloscope 35 cm Role of outer tube : divide the model 1 and 2 The sound by vibration of the tube reduced The sound due to the light not reduced
6 Sound pressure waveform of O 3 free lamp Distance from microphone (cm) 0 10 20 30 40 50 60 70 80 Sound pressure (Pa) 4 2 0-2 Microphone -4 1.6ms (audible frequency component 600Hz) Outer tube & flash lamp -6 0 0.5 1 1.5 2 2.5 Time (ms) The audible frequency component, originated from light The high frequency component vibration of the tube
Frequency analysis of the O 3 free lamp waveform without outer tube 0.1 0.08 27kHz Amplitude (a.u) 0.06 0.04 The audible sound area: 20Hz 20kHz 0.02 0 0 20 40 60 Frequency (khz) Mechanical vibration of tube The sound of 27 khz cannot be heard.
6 Sound pressure waveform of O 3 free lamp Distance from microphone (cm) 0 10 20 30 40 50 60 70 80 Sound pressure (Pa) 4 2 0-2 Microphone -4 1.6ms (audible frequency component 600Hz) Outer tube & flash lamp -6 27kHz non-audible frequency component 0 0.5 1 1.5 2 2.5 Time (ms) The audible sound accompanied by flash lamp operation is from light, not from vibration.
2 Emission spectra of operated lamps in VUV-UV regions Oxygen 1000 Flash light output (arb. units) 1.5 1 0.5 Carbon dioxide Water vapor VUV lamp 100 10 1 Absorption coefficient (cm-1/bar) O 3 free lamp 0 0.1 140 160 180 200 220 240 260 Wavelength (nm) Ref) K. Watanabe, M. Zelikoff, E. C. Y. Inn, Air Force Cambridge Research Center Technical Report 53 (23), (1953) Hypothesis : Oxygen and water vapor may be the cause of the sound generation
Experimental set up To precision sound level meter Microphone Controlled Oxygen Water vapor Air Flash lamp Nitrogen Molecular seives or water Purge box Oxygen concetration Controlled by adjusting air and nitrogen flow Water vapor pressure Controlled by molecular sieves or water
The dependence of maximum sound pressure on the oxygen concentration Oxygen concentration (vol %) 20.5 0.06 VUV lamp 100 13 O 3 free lamp 0.62 0.62 The water vapor pressure was kept at 500Pa VUV lamp noticeably reduced at low oxygen concentration O 3 free lamp NOT depended on the oxygen concentration
The dependence of maximum sound pressure on the water vapor pressure Water vapor pressure (Pa) 2400 500 VUV lamp 100 13 O 3 free lamp 0.88 0.62 The oxygen concentration was kept at 0.06 vol VUV lamp: noticeably reduced O 3 free lamp at low water vapor pressure tended to be reduced
The absorption coefficient of atmospheric main constituents and the spectral distribution of the lamps 2 Oxygen 1000 Flash light output (arb. units) 1.5 1 0.5 Carbon dioxide Water vapor VUV lamp 100 10 1 Absorption coefficient (cm-1/bar) 0 140 160 180 200 220 240 260 Wavelength (nm) O 3 free lamp VUV lamp be influenced by oxygen and water vapor O 3 free lamp be influenced only by water vapor 0.1
Summary We studied the mechanism of the audible sound generation accompanied by flash lamp operation. As result, we clarified as follows; - The audible sound originated from the light which was radiated from the lamp. - Oxygen and water vapor absorb VUV light, water vapor absorbs IR light and heating occurs. Consequently air rapidly expands and the audible sound is generated.