The positron annihilation technique can provide a sensitive measure of defect density in metals. In this program the technique has been used to monitor defects generated during plastic deformation by cold work or fatigue cycling. The primary goals have been 1) to assess the degree of sensitivity of the technique, 2) to correlate positron annihilation readings with observed microstructural changes to better understand the physical basis for these readings, and 3) to determine correlations between positron annihilation measurements and number of fatigue cycles. Examination of fatigued samples by transmission electron microscopy indicates some correlation between dislocation density and positron annihilation lineshape parameter (determined by the Doppler broadening technique). However, annealing studies of deformed samples indicate that positron annihilation response in 316 stainless steel is sensitive primarily to excess vacancies generated during the deformation and is less sensitive to dislocation density. Data on deformed nickel show sensitivity to both vacancies and dislocations. In general, lineshape parameter values tend to achieve a constant level at approximately 10 per cent of fatigue life

Bauster, W. B.

Jones, W. B.

Van Den Avyle, J. A.

Wampler, W. R.

English

Jones, W B

Van Den Avyle, J A

Bauster, W B

Wampler, W R

Iowa State University Computer Science Technical Reports

Assessment of Positron Annihilation as a Potential Non-Destructive Examination Technique

The positron annihilation technique can provide a sensitive measure of defect density in metals. In this program the technique has been used to monitor defects generated during plastic deformation by cold work or fatigue cycling. The primary goals have been 1) to assess the degree of sensitivity of the technique, 2) to correlate positron annihilation readings with observed microstructural changes to better understand the physical basis for these readings, and 3) to determine correlations between positron annihilation measurements and number of fatigue cycles. Examination of fatigued samples by transmission electron microscopy indicates some correlation between dislocation density and positron annihilation lineshape parameter (determined by the Doppler broadening technique). However, annealing studies of deformed samples indicate that positron annihilation response in 316 stainless steel is sensitive primarily to excess vacancies generated during the deformation and is less sensitive to dislocation density. Data on deformed nickel show sensitivity to both vacancies and dislocations. In general, lineshape parameter values tend to achieve a constant level at approximately 10 per cent of fatigue life.</p

Jones, W.

Van Den Avyle, J.

Bauster, W.

Wampler, W.

Digital Repository @ Iowa State University (ISU)

ASSESSMENT OF POSITRON ANNlliiiATION AS A POTENTIAL NON-DESTRUCTIVE EXAMINATION TECHNIQUE W. B. Jones, J. A. Van Den Avyle, W. B. Bauster and W. R. Wampler Sandia Laboratories Albuquerque, NM 87185 ABSTRACT The positron annihilation technique can provide a sensitive measure of defect density in metals. In this program the technique has been used to monitor defects generated during plastic deformation by cold work or fatigue cycling. The primary goals have been 1) to assess the degree of sensitivity of the technique, 2) to correlate positron annihilation readings with observed microstructural changes to better understand the physical basis for these readings, and 3) to determine correlations between positron annihilation measurements and number of fatigue cycles. Examination of fatigued samples by transmission electron microscopy indicates some correlation between dislocation density and positron annihilation lineshape parameter (determined by the Doppler broadening technique). However, annealing studies of deformed samples indicate that positron annihilation response in 316 stainless steel is sensitive primarily to excess vacancies generated during the deforma-tion and is less sensitive to dislocation density. Data on deformed nickel show sensitivity to both vacancies and dislocations. In general, lineshape parameter values tend to achieve a constant level at approximately 10 per cent of fatigue life. INTRODUCTION Elevated temperature design for advanced nuclear reactor components must incorporate creep and fatigue and their interaction. Current ASME Design Codes utilize the concept of damage accumu-lation to treat combined creep-fatigue loadings. This approach assumes that bulk changes occur during the service life that represent "damage". One question addressed by this study has been: Is there a measure of the bulk changes that occur during service that could be correlated to the accumulated "damage"? Flaw detection is not the purpose of such a technique. Several candidate schemes have been surveyed with positron annihilation appearing to have more promise than the others (1,2). Positron annihila-tion has been shown (3) to be sensitive to vacancies, vacancy clusters and dislocations induced by irradiation or deformation of metals. RESULTS AND DISCUSSION Positrons injected into a metal annihilate with electrons emitting two gamma photons. The momentum of the annihilating electron causes a Doppler shift in the energy of the emitted photons. The sensitivity of positron annihilation to vacancy and dislocation concentrations in crystals arises from differences between electron momentum distri-butions in the perfect lattice and at defects. Figure 1 shows a schematic drawing of the apparatus used to measure the Doppler broadening of the annihilation line. Positrons are produced in the source by the ~+ decay of a naturally radioactivive isotope. For this study, 22Na was the isotope used. These positrons penetrate relatively short dis-tances into the metal sample (Fig. 2) where they annihilate with electrons within about 100 psec. Test specimens examined in this study were sectioned normal to the stress axis so that the material sampled by the positrons was originally at the interior of the gauge section. The result of the Doppler broadening measure-ment is a distribution of gamma energies around the 511 keV line. The parameter chosen to characterize this curve is the lineshape parameter, S. Details concerning this characterization can be found in reference 1, however, it is important to note that the value of S depends on the density of disloca-tions and vacancies. The larger the value of s, the higher is the density of vacancies and disloca-tions. To initiate this study, a number of fatigue tests on type 316 stainless steel were conducted at room temperature and the dislocation density monitored for comparison with lineshape data. The lineshape parameter, S, is plotted versus number of fatigue cycles in Fig. 3 together with trans-mission electron micrographs of representative dislocation substructures. For these test condi-tions the dislocation density and the lineshape parameter both increase with increasing number of fatigue cycles. Figure 4 shows the results of fatigue tests conducted under several different conditions. For each set of conditions, the lineshape parameter followed the dislocation density changes; however, comparison of the values of S and the dislocation densities among the several conditions did not reflect a correlation (Fig. 5). In addition, the observed changes in S saturated at about 10% of life. As pointed out earlier, the positron annihila-tion response is known to be sensitive to the presence of both dislocations and vacancies. In order to distinguish the relative magnitude of each contribution, isochronal annealing was conducted on samples of cold worked 316 stainless steel and pure nickel. Figure 6 shows the changes in lineshape parameter induced by cold work for both materials. In the present study, a pure Ni specimen was cold rolled to a 25% reduction in thickness and iso-chronally annealed (Fig. 7). Together with electron microscopy results, these data show that after annealing the Ni to 600 K to remove the excess vacancies, the lineshape parameter has noticeably decreased due to the loss of vacancies. However, about 60% of the total initial increase remains due to the dislocations. Figure 8 shows that after annealing 316 stainless steel at 873 K, the lineshape parameter has nearly completely recovered whereas electron microscopy and microhardness have shown that the dislocation structure has not 115 changed. From this we conclude that most of the initial response was due to the vacancies and only a very small fraction could be caused by the dis-locations in the 316 stainless steel. Figures 9 and 10 show the annealing response of 316 stainless steel cycled at room temperature and 866 K. As anticipated, the material fatigued at room temperature undergoes significant annealing of the lineshape parameter due to the large number of excess vacancies present after cycling. In contrast, cycling at 866 K results in a minimal accumulation of excess vacancies and, accordingly, the annealing treatment produced very little change in the lineshape parameter. CONCLUSIONS This study has shown that positron annihila-tion sensitivity to dislocation density must be established for each alloy. Even when such sensitivity is present, the response may be domi-nated by the presence of excess vacancies. Trans-mission electron microscopy has shown that the density and distribution of dislocations reaches a steady-state condition in the first lo% of the fatigue life so that, even with good dislocation sensitivity, the positron annihilation response would saturate at about lo% of total fatigue life. ACKNOWLEDGEMENTS Sandia Laboratories is aU. S. Department of Energy facility. This article was sponsored by the U. S. Nuclear Regulatory Commission under contract DE-AC04-DP00789. 1. 2. 3. 4. 5. REFERENCES w. B. Gauster, W. R. Wampler, W. B. Jones, and J. A. Van Den Avyle, Sandia Laboratories Report SAND-77-1570, May 1978. J. A. Van Den Avyle, W. B. Jones, and J. H. Gieske, Sandia Laboratories Report SAND-77-1557, July 1978. c. F. Coleman and A. E. Hughes, in Research Techniques in Nondestructive Testing, R. S. Sharpe, ed., (Academic Press, New York) Vol. 3, 1977. G. Dlubek, 0. Brummer, and E. Hensel, Phys. Stat. Sol. (a), 34, 737 (1976). W. Wysick and M. Feller-Kniepmeier, J·. of. Nuc. Mat., 69 and 70, 616 (1978). 116 SOURCE POSITRON ANNIHILAnON DOPPLER BROADENING ~~· f S~luiV l LIN£ i \ SAMPLE ............ . ....... .... , 1 \ muv,. / \FROM Cu ,...... \., .... . ... ... 3800 3900 CHANII{I. NUMBER Figure -'-· Depths of Penetration of Positrons in Copper (Values lor Steel will be -10 to 2~ Higher) e-loldi ng distance' maximum penetration 23.11/m • 0.0009 in 0.31 mm • 0.012 in 165 11m • 0. 006 in 1.42 mm • 0. 056 in • Depth in material at which positron nux is lie (37'/ol of its value at the surface. Figure 2. "' ~ ::;:: "" "' "" Cl. ..... Cl. "" :J: Vl ..... z ... w 1-w lE <I( ... <I( .... w .... <I( ::J: II) w z ::::; -~~--.· I • .1 -32. 50 32.00 31. 50 31.00 30.50 30.00 29.50 29.00 o .1t I ":t. 0. 9'J., 27.50 0.1 32.5 32.0 31.5 31.0 30.5 -30.0 2941( 6E=1.8" 10 100 1000 FATIGUE CYCLES Figure 3. ------------o--• 0 ... . 0--------29.5 /• o/~ _.-- 0-L._ 0' • 0 29.0 27.5 0.1 ------c;;.--•••• FAILED ------ .... 10 ~--­10-6E=0.5" t -6E=1.0" I. -.O.E=O.S" + 10 MIN TENSILE HOLD 100 1000 FA TIGUE CYCLES POSITRON ANNIHILATION RESPONSE OF FATIGUED 316 STAINLESS STEEL Figure 4. 10000 Ill. O!Hl 117 294 K .1E=1.8'l6 N =3700 S=32.3 294 K 11E= 0.8% N=47173 S=31.8 _,;:;~ 888K .1E=0.5% N =iOOOO $ ~29.2 Figure 5. 40 . ~ .. 39 "' "' ... ... ... :E 38 c "' c ... ... ... c 37 :1: "' ... z ::; p 36 250 300 2 POSITRON ANNIHILATION RESPONSE OF COLD WORKED 316 STAINLESS STEEL AND NICKEL o ANNEALED 316 SS · o AS RECEIVED 316 SS o NICKEL (Diubek elal.) (4) 60 REDUCTION IN THICKNESS A.!!. (%) do Figure 6. 70 80 90 12 10 8 Ill! ~'"'0 ... 6 ... " S! z 4 2 0 32.0 r--r----..--__;_r---,.--1-..--.----r-.---.-.--r-, vacancy annealing ~ dislocation annealing ~ s Ni. 25% COLD WORKED ~ .o 0 / 0 • 0 • 0 • 0 • 0 0 00 • • 00 • • 0 ••• QUENCHED /• •••. • 0 Ni . . • • (Wycisk et. al.) (S) 0 • oo o• - 1.0 t:J.p - !:J.po - 0.6 - 0.4 0.2 0 • • 0 400 500 600 700 800 900 1000 ANNEALING TEMPERATURE (K) Figure 7. "' "' ... :;; 31.0 :E 30.0 : : ~ 29.0 ~ z ::; II) "' ... t:; :E c "' : ... ... c :1: II) ... z ::; 118 28.0 27.0 40.0 39.01-38.01-37.01-36.0 1-35.0 I • • • • • 316 ss •• • COLD WORKED 25% t1 0 I 300 0 0 0 0 I 400 • • ••• 000 0 0 • •• • I 0 oo 0 0 oo 600 ANNEALING TEMPERATURE Figure 8. • • • • I I l I I I I I I 316 ss COLD WORKED 75%--0 0 0 0 0 -0 -800 1000 1200 (K) 1.0 f • 31655 • • • .. ROOM • . . TEMPERATURE FATIGUED . • • ALt ~ 0.6% ~ 0.5 .. ... . "' •• z . ... a: • ... ... ... • • .. i5 . • a: 0.0 ~ :IE c 31655 a: • ROOM ~ • • • • TEMPERATURE ... • • ... 1.0 • FATIGUED c !1: A<t = 1.8% "' ... z • ::; .. . . 0.5 .. • • . . . .. • • • 0.0 300 400 500 600 700 800 1000 1200 1400 ANNEALING TEMPERATURE (K) Figure 9 . . (/) <> 316 STAINLESS STEEL w FATIGUED AT 866 K 0 1.0 .1<:0.5% ~ w It i5 a: w 0.5 t-w ~ OoOOo 0 < ~ 0 0 oooo a: < 0 oOO 0 0 0 000 0.. 0 0 0 w 0 0.. 0.0 < :r (/) w z ::J 300 400 600 800 1000 1400 ANNEALING TEMPERATURE (K) Figure 10. 119 

Jones, W

Van Den Avyle, J

Bauster, W

Wampler, W

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Assessment of Positron Annihilation as a Potential Non-Destructive Examination Technique

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Iowa State University Computer Science Technical Reports

Digital Repository @ Iowa State University (ISU)

Digital Repository @ Iowa State University (ISU)