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APPLICATIONS OF THERMOACOUSTIC TECHNIQUES FOR THERMAL, OPTICAL AND MECHANICAL CHARACTERIZATION OF MATERIALS, STRUCTURES AND DEVICES. Mirosław Maliński Department of Electronics and Computer Studies Technical Univeristy of Koszalin, Poland. Contents. Introduction
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APPLICATIONS OF THERMOACOUSTIC TECHNIQUES FOR THERMAL, OPTICAL AND MECHANICAL CHARACTERIZATION OF MATERIALS, STRUCTURES AND DEVICES Mirosław Maliński Department of Electronics and Computer Studies Technical Univeristy of Koszalin, Poland
Contents • Introduction • Multi-layer optically opaque systems • Optically semitransparent systems • Determination of thermal parameters of materials • Determination of recombination parameters of carriers • Determination of air-tightness of packagings • Investigation of the quality of the surface of samples • Investigation of composition of crystals and their quality • Determination of internal quantum efficiency
Introduction • Thermoacoustics uses both frequency and spectral amplitude and phase characteristicsfor determination of several parameters of samples and structures • This presentation is limited to the analysis of FA characteristics measured with a microphone or piezoelectric methods
The idea of a thermoacoustic method • Generation of periodical heat in the sample by absorbed light or dissipation of electric power • Propagation of induced thermal waves in the sample • Detection of the amplitude and phase of a thermal wave with one of the methods e.g. microphone, IR or piezoelectric or… • Detection of one of the effects connected with the periodical temperature distribution e.g. thermal expantion, thermoelastic bending, IR emission, overpressure
Example temperature distributions R=1(left)R= -1 (right):1-t=0, 2-t=T/4, 3-t=T/2, 4-t=3T/4.l=0.1 cm, =0.1 cm2/s, =100 cm-1,f=16Hz.
Photoacoustic signals • Microphone detection • Piezoelectric detection
Multilayer optically opaque systems • Theoretical frequency domain dependencies of a phase of a photoacoustic signal for a transistor structure of a thickness l1=230 m, a lead frame of the thickness l3=350 m for different values of air delaminations: 1– 0.025 m, 2– 0.05 m, 3– 0.075 m, 4– 0.1 m, 5– 0.15 m, 6– 0.2 m.
Multilayer optically opaque systems • Correlation of the phase of the PA signal and the force of detachment of the transistor structure from a lead frame. Solid line is a theoretical curve, circles are experimental points, BC 237 transistor structures • Phase(S) = (180/)arg (S1( d2 = 0m)p + S2(d2 = 0.1 m)(1-p)) • Force necessary for detachment is proportional to the parameter p
Optically semitransparent systems • Schematic diagram of a thin semitransparent layer on the semitransparent backing • Application – characterization of thin semiconductor films on semiconductor thick substrates
0.4 40 0.3 60 PHASE [degs] AMPLITUDE [a.u] 0.2 80 0.1 100 0 100 200 300 400 500 100 200 300 400 500 FREQUENCY [Hz} FREQUENCY [Hz] Optically semitransparent systems GaAs on Si • Amplitude and phase photoacoustic frequency characteristics of a l1= 10 m thick layer on the thick substrate. Parameters taken for computations: 1=0 cm-1 , 2=10000 cm-1 (solid line), 1=104 cm-1, 2=103 cm-1 ( dash line), 1=0.3 cm2/s, 2=0.9 cm2/s, GaAs/Si
Optically semitransparent systems SCL in Si • Theoretical influence of a SCL on the photoacoustic amplitude and phase characteristics in the front configuration. Parameters: =0.01 cm2/s, thickness of the layer l1=5 m – dash line, l1=10 m – dotted line, l1=15 m – solid line, 1=0 cm-1, 2=1000 cm-1, R12=0.
Optically semitransparent systems PS on Si substrate • The phase frequency characteristics of the PS/Si structure in the reflection configuration. Diamonds and circles are for exc=514 nm and exc=670 nm. Parameters of PS layer=0.016cm2/s, kc=0.0042 cal(cmKs)-1, 1(514nm)=1900 cm-1, 1(670nm)=903 cm-1.
Optically semitransparent systems PS on Si substrate • d1=50m on theSi substrate of the thickness d2=500 m.The anodisation current I=100mA for the time t=10 min
Determination of thermal parameters –piezoelectric method • ZnSe crystal l = 0.081 cm=0.01 cm2/s( solid line),= 0.05 cm2/s, 0.1 cm2/s, 0.2 cm2/s. • Zn0.83Be0.17Sel=0.1161 cm=0.05 cm2/s,=0.01 cm2/s, =0.1 cm2/s and = 0.2 cm2/s
Determination of thermal parameters –microphone method • Si samplel=240m and =0.6 cm2/s. Description of lines: line 1 – R = 1, line 2 – R = 0.9, line 3 – R = 0.76, line 4 – R = 0.5. Circles and diamonds are experimental lines, lines are theoretical curves.
Determination of thermal parameters 100 80 60 THERMAL CONDUCTIVITY [W/mK] 40 • Dependance of the thermal conductivity of SiGe on the composition 20 0 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 CONCENTRATION of Si in SiGe
Determination of recombination parameters • Computations of Ge samples: = 0.4 cm2/s, l = 0.1 cm, = 2010-6 s, D = 44 cm2/s, V = 500 cm/s a) = 0.110-6 s and D = 22 cm2/s b).
3.5 100 3 50 2.5 AMPLITUDE RATIO [a.u.] PHASE SHIFT [degs] 2 0 1.5 1 50 0.5 3 . 3 . 10 100 1 10 10 100 1 10 FREQUENCY [Hz] FREQUENCY [Hz] Determination of recombination parameters • SiGe: =0.37 cm2/s, L=0.1 cm, E1=2.0 eV, E2=1.4 eV, Eg=1.1 eV, D=44 cm2/s, V=800 cm/s, = 100 s
Air-tightness measurements- theoretical model • Parameters taken for computation: = 1710-6 [Ns/m2], L = 6-4 [m], M = 2810-3 [kg/mole], V2 = 2.1610-6 [m3], V2/V1 = 3.19, r = 20 m...60 m, = 1.3 [kg/m3], Na = 610-23 [mole-1], T = 300 K, k = 1.3810-23 [J/K].
1 0.9 1 0.8 0.7 2 0.6 0.5 AMPLITUDE RATIO [1] 3 0.4 0.3 4 0.2 0.1 5 6 0 10 100 log (f) Air-tightness measurements -poster • 1) r = 108m; 2) r = 91m;3) r = 78m; 4) r = 69m; 5) r = 42m;6) r =24m; L.Majchrzak, M.Maliński ‘Analysis of a Thermoacoustic Approach for the Evaluation of Hermeticity of Packaging of Electronic Devices’ XXIV IMAPS Poland Conf2005
Determination of the quality of the surface p-type Si • Theoretical and experimental piezoelectric spectra of p-Si at RTd=0.0037 cm, d=0.0050 cm.
Determination of the surface quality • Amplitude PPT spectra of CdTe sample at f = 76 Hz. Circles – experimental results, and a solid line is the theoretical curve: Eg = 1.51 eV, = 0.03 cm2s-1, = 0.0019 cm, 0 = 130 cm-1, = 0.9.
Composition of mixed crystals • The correlation of the energy gap value of the Zn 1-xBexTe mixed crystal and the mole fraction of beryllium x in the crystal
8 150 100 6 50 4 AMPLITUDE [j.u.] PHASE[deg] 0 2 – 50 – 100 0 2.0 2.2 2.4 2.6 2.0 2.1 2.2 2.3 2.4 2.5 ENERGY [eV] ENERGY [eV] Composition of mixed crystals • Zn0.93Be0.07TeEg1 = 2.31eV, Eg2 = 2.380 eV , k = 0.4, = 0.2cm2/s, f = 36 Hz, = 0.005 cm, R = 1
Internal quantum efficiency • Schematic diagram of the absorption and irradiative and radiative recombination processes involved in a generation of the photoacoustic signal.
Internal quantum efficiency • ZnTe RT at 76 Hz and 126 Hz, internal quantum efficiency of irradiative recombination R=0.75
Conclusions • Frequency FA characteristics are a useful tool bringing information about: • Multilayer optically opaque systems • Optically semitransparent systems • Thermal parameters of materials • Recombination parameters of carriers • Air-tightness of packagings • Determination of the quality of the surface and composition • Determination of the internal quantum efficiency