OUTLINE OF ACOUSTIC EMISSION EXPERIMENTS PERFORMED WITH A PERSON REPUTED TO HAVE PARANORMAL METAL BENDING ABILITIES

I ' I CONFIDENCE =Approved For Release 2000/08/07 : CIA-RDP96-00788RO01 100100001 -9 OUTLINE OF ACOUSTIC EMISSION EXPERIMENTS PERFORMED WITH A PERSON REPUTED TO HAVE PARANORMAL METAL BENDING ABILITIES R. S. Hawke Lawrence Livermore Laboratory, University of California Livermore, CA 94550 January 11, 1979 ABSTRACT This outline summarizes the design, use and results of an acoustic emission experiment intended to investigate para- normal metal bending phenomena. The experiment was designed not merely to verify or refute the occurrence of paranormal metal bending, but rather to gain some insight into the phenomena occurring in a test specimen while bending was attempted. Although large amounts of bending were not observed during the experiments, acoustic emission signals typical of single grain or grain boundary fracture with and without evidence of plastic strain-induced emission were recorded during periods of time when there was no contact with the test' specimens. These results are consistent with those of Crussard (1). Further experiments are warranted. IN STRICT E Approved For Release 2000/08/07 : CIA-RDP96-00788RO01 100100001 -9  KI DENCE ? Approved For Release 2000/08/07 CIA-RDP96-00788RO01 1001,00001 -9 Introduction A. Previous claims: 1. Metal can be paranormally bent without physical contact. 2. Metal seemingly becomes soft and pliable (sub- jective experience of subject). B. Type of research needed: 1. Determine internal phenomenology. 2. Determine physical cause of phenomenology. 3. Develop and test hypothesis of actualization mechanism. C. Reason acoustic emission (A.E.) was chosen: 1. Very sensitive. a. Responds to a single intragranular or inter- granular fracture or grain boundary slip or crystallographic change. b. Good potential for use as a feedback device to subject. c. High sensitivity requires non-contact, hence decreases possibility of deception. 2. Provides continuous record during the event and can be recorded for later analysis. 3. Can distinguish between different types of metal- lurgical phenomenon. 4. A. E. signals are very distinct from all forms of touching, rubbing and other noise. IN TAT CONFIDENCE Approved For Release 2000/08/07 : CIA-RDP96-00788RO01 100100001 -9  Approved For Release 2000/08/07 : CIA-RDP96-00788RO01100100001-9 Experimental design: (Ref. 2) A. Acoustic emission components (See Figure 1). 1. A. E. Sensor a. Lead Zirconate Titinate (PZT) element. b. Bandpass, DC - 1 MHz, low Q, resonant at 140 kHz. co Open circuit sensitivity, 4.47 mV/Pa @ 140 kHz; 0.141 mV/Pa @ 1 kHz. d. Shaped to fit and epoxied to bowl of standard stainless steel spoon. 2. Preamplifier a. Gain 60 db. b. Bandpass 1 kHz - 1 MHz 3. Amplifier a. Gain 35 db. b. Bandpass 1 kHz - 1 MHz 4. Video tape recorder a. Modified. to record positive and negative sig- nals (Standard TV is non-symmetric pulse code). b. Bandpass 30 Hz - 3MHz. c. A. E. and room conversation recorded on video channel. d. Auxiliary audio channel (See Below). 5. Root mean square (RMS) voltmeter. 6. Pulse counter. 7. Strip chart recorders. a. Record RMS voltmeter and pulse counter outputs. E~ E CE . 1' STIZUCT CV Approved For Release 2000/08/07 : CIA-RDP96-00788RO01 100100001 -9  Approved For Rel AT 0 88ROO1100100001-9 B. TV video camera and recorder (Figure 2). , 1. Standard System a. Used to record the location of people and objects. b. Used to record the response of the logic probes used in diagnostics. c. Used to monitor the laser beam position which monitors the degree of bending. C. Other diagnostics: 1. Electric field on spoon. a. Logic probe connected to vise and spoon. b. Light emission whenever input signal is greater than 1 V, DC - 1 GHz. c. Logic probe light output recorded with TV vidicon. d. Background electromagnetic (EM) effects. i. Below logic probe threshold when not touched. ii. Above threshold when touched. 2. Magnetic field near spoon. a. Air core inductor placed beneath spoon handle and connected to logic probe. b. Coil inductance 30 mH. C. Bandpass 1kHz - 10 MHz. d. Background EM effects. i. None. 3. AM radio IN' STRI CONFIDENCE Approved For Release 2000/08/07 : CIA-RDP96-00788RO01 100100001 -9  -5- f- I788R001100100001-9 'Approved For Re"JsfS" ~e G yLh a. Tuned to -1600 kHz at end of band (no broad- cast station). b. Output connected to logic probe and auxiliary audio input to A.E. video recorder. c. Background EM effects. i. None. 4. Laser beam bend detector. a. Helve laser beam reflected off bottom of spoon bowl and down onto table with target. b. Position of beam on target changes with spoon bending. c. Beam position on target recorded by vidicon TV system. III. Experimental protocol A. Spoon and vise could not be moved during experiment. B.. Spoon could be lightly touched by subject for short periods of time but subject was informed that touching obliterated any useful result that might be present while touching occurred and hence was to be minimized if not totally avoided. 1. Logic probe connected to electric field detector provided record of spoon touching. 2. A.E. System provided record of noise if the spoon was rubbed. 3. TV vidicon provided record of hand or finger in proximity of spoon and vise. IN STRICT CO` IN Approved For Release 2000/08/07 : CIA-RDP96-00788R001100100001-9  'Approved For Relel 0& 8117 88R001100100001-9 C. Experimental sessions were about 1 hour long. D. Sessions had subject and 2 or 3 observers present. IV. Experimental results: A. At least 4 clear instances of A.E. events occurred with one subject during one session. 1. Records verified events occurred while spoon and vise were untouched. 2. Sufficient bending to move the reflected laser beam was not observed. a. Normal elastic bending (without A.E.) prior to plastic deformation (with A.E.) would have caused an observable displacement of the laser beam. 3. The events were typical of single grain or grain boundary fracture with and without evidence of plastic strain induced emission following. (See Figure 3A and 3B). 4. No anomalous A.E. events were recorded during dry runs. B. Fewer but similar results were obtained with one other subject. Conclusions A. Acoustic emissions were recorded in the presence of a person who claimed the ability to paranormally bend metals B. Elastic deformation was not observed. C. Observable plastic deformation did not occur. IN cT rTr 1 m- r Approved For Release 2000/08/07 : CIA-RDP96-00788R001100100001-9  `Approved TRjCj7CGMPM M8R001100100001-9 D. Further experiments are warranted. E. Future experiments should be more sensitive to minute bending. F. Other materials and crystalline structures should be investigated. References (1) C. Crussard and J. Bouvaist, Memoires Scientifiques Revue Metallurgie, p. 117, February 1978. (2) The assistance of A. E. Brown and C. A. Tatro through- out the design, implementation and interpretation of the experiments, is greatly appreciated. IM cURIC7 CUA"kiNFIDENCE Approved For Release 2000/08/07 : CIA-RDP96-00788R001100100001-9  I STKCT CONFIDENCE Approved For Release 2000/08/07 : CIA-RDP96-00788RO01100100001-9 CJ) IN STRICT CONFIDENCE W 0 CT+ .7 .r-I Approved For Release 2000/08/07 : CIA-RDP96-00788RO01 100100001 -9  IN STRICT CCU I ENC' 'Approved For Release 2000/08/07 : CIA-RDP96-00788RO01 100100001 -9 ~ U ?~ d f6 L U 1 IN STRICT C I NCE C 0 L 0 S Approved For Release 2000/08/07 : CIA-RDP96-00788RO01 100100001 -9  Approved For Release 2000/08/07 : CIA-RDP96-00788RO01100100001-9- Brittle fracture r- Plastic strain induced I 50?s/cm 20 ?s/cm Figure 3A and 3B Approved For Release 2000/08/07 : CIA-RDP96-00788RO01 100100001 -9