APS March Meeting 2016
Volume 61, Number 2
Monday–Friday, March 14–18, 2016;
Baltimore, Maryland
Session S53: Keithley Award Session
11:15 AM–2:15 PM,
Thursday, March 17, 2016
Hilton Baltimore
Room: Holiday Ballroom 4
Sponsoring
Unit:
GIMS
Chair: Francis Hellman, University of California, Berkeley
Abstract ID: BAPS.2016.MAR.S53.3
Abstract: S53.00003 : Ultrasonic techniques for measuring physical properties of fluids in harsh environments
12:27 PM–1:03 PM
Preview Abstract
Abstract
Author:
Cristian Pantea
(Los Alamos National Laboratory)
Ultrasonic-based measurement techniques, either in the time domain or in the
frequency domain, include a wide range of experimental methods for
investigating physical properties of materials. This discussion is
specifically focused on ultrasonic methods and instrumentation development
for the determination of liquid properties at conditions typically found in
subsurface environments (in the U.S., more than 80{\%} of total energy needs
are provided by subsurface energy sources). Such sensors require materials
that can withstand harsh conditions of high pressure, high temperature and
corrosiveness. These include the piezoelectric material, electrically
conductive adhesives, sensor housings/enclosures, and the signal carrying
cables, to name a few. A complete sensor package was developed for operation
at high temperatures and pressures characteristic to geothermal/oil-industry
reservoirs. This package is designed to provide real-time, simultaneous
measurements of multiple physical parameters, such as temperature, pressure,
salinity and sound speed. The basic principle for this sensor's operation is
an ultrasonic frequency domain technique, combined with transducer resonance
tracking. This multipurpose acoustic sensor can be used at depths of several
thousand meters, temperatures up to 250 \textdegree C, and in a very
corrosive environment. In the context of high precision measurement of sound
speed, the determination of acoustic nonlinearity of liquids will also be
discussed, using two different approaches: (i) the thermodynamic method, in
which precise and accurate frequency domain sound speed measurements are
performed at high pressure and high temperature, and (ii) a modified finite
amplitude method, requiring time domain measurements of the second harmonic
at room temperature. Efforts toward the development of an acoustic source of
collimated low-frequency (10-150 kHz) beam, with applications in imaging,
will also be presented.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2016.MAR.S53.3