“Broadband viscoelastic spectroscopy”的意思、由来-开放百科全书

BVS was developed primarily to overcome shortcomings in the functional ranges of other viscoelastic characterization techniques. For example, resonant ultrasound spectroscopy (RUS), another popular technique for studying viscoelastic solids, experiences difficulty in determining a material's parameters below its resonant frequency.^[6] Furthermore, BVS is less sensitive to sample preparation than RUS.

History

BVS was first developed by C. P. Chen and R. S. Lakes in 1989 in order to address the shortcomings of existing laboratory techniques for studying viscoelastic materials.^[1] It was later refined by M. Brodt et al. to improve the rigidity and resolution of the apparatus, which were sources of error in the original design.^[1]^[7] First used to study poly(methyl methacrylate) (PMMA),^[1]^[6] it has since seen applications in determining the properties of bone,^[2] capacitor dielectrics,^[3] high damping metals,^[4] and other such viscoelastic materials.

Design

The BVS apparatus consists of a specimen surrounded by Helmholtz coils and isolated from external vibrations by a framework constructed from insulating foam and either lead or brass.^[1]^[2]^[4] The specimen is affixed with both a permanent magnet and a mirror. The orientation of the coils with respect to the magnet when a current is driven through them determines whether the specimen undergoes bending or torsion. Angular displacement of the specimen is measured by an interferometer that detects the spatial movement of a reflected laser. This spatial waveform is converted to an electrical one by a light detector and read out on an oscilloscope. This oscilloscope also displays the torque or force waveform from the capacitor driving the current in the Helmholtz coils. Phase delay is determined by comparing these waveforms.

Resonance is minimized through the use of short specimens—which have higher resonant frequencies—and by reducing the inertia (magnetic and mass moments) of the magnet. Cubic samarium-cobalt magnets are ideal for high frequency studies.^[1]^[4] Due to the sample geometry being a short rectangular bar or cylinder, the equation governing the resonance of the BVS specimen geometry has an exact analytic solution, which allows the technique to yield results even for high loss materials.^[1]^[4] This exact solution provides a relationship between dynamic moduli, angular displacement, and geometric parameters.^[4] The inherent lack of drift and friction in the apparatus is responsible for its large range of operating frequencies.

References

1. ^¹²³⁴⁵⁶⁷{{Cite journal|last=Chen|first=C. P.|last2=Lakes|first2=R. S.|date=1989|title=Apparatus for Determining the Viscoelastic Properties of Materials Over Ten Decades of Frequency and Time|url=|journal=Journal of Rheology|volume=33|issue=8|pages=1231–1249|via=|bibcode=1989JRheo..33.1231C|doi=10.1122/1.550071}}
2. ^¹²³⁴⁵{{Cite journal|last=Buechner|first=P. M.|last2=Lakes|first2=R. S.|last3=Swan|first3=C.|last4=Brand|first4=R. A.|date=August 2001|title=A Broadband Viscoelastic Spectroscopic Study of Bovine Bone: Implications for Fluid Flow|url=|journal=Annals of Biomedical Engineering|volume=29|pages=719–728|via=}}
3. ^¹²³⁴{{Cite journal|last=Dong|first=Liang|last2=Stone|first2=Donald S.|last3=Lakes|first3=Roderic S.|date=November 2008|title=Broadband viscoelastic spectroscopy measurement of mechanical loss and modulus of polycrystalline BaTiO₃ vs. temperature and frequency|url=|journal=Physica Status Solidi B|volume=245|pages=2422–2432|via=}}
4. ^¹²³⁴⁵⁶⁷⁸⁹{{Cite journal|last=Wang|first=Y. C.|last2=Ludwigson|first2=M.|last3=Lakes|first3=R. S.|date=April 2004|title=Deformation of extreme viscoelastic metals and composites|url=|journal=Materials Science and Engineering: A|volume=370|pages=41–49|via=}}
5. ^¹²{{Cite journal|last=Lee|first=T.|last2=Lakes|first2=R. S.|last3=Lal|first3=A.|date=July 2000|title=Resonant ultrasound spectroscopy for measurement of mechanical damping: Comparison with broadband viscoelastic spectroscopy|url=http://digital.library.wisc.edu/1793/9850|journal=Review of Scientific Instruments|volume=71|issue=7|pages=2855–2861|via=|bibcode=2000RScI...71.2855L|doi=10.1063/1.1150703}}
6. ^¹²{{Cite journal|last=Aksoy|first=Hüseyin Gökmen|date=April 2016|title=Broadband ultrasonic spectroscopy for the characterization of viscoelastic materials|url=|journal=Ultrasonics|volume=67|pages=168–177|via=|pmid=26859428|doi=10.1016/j.ultras.2016.01.012}}
7. ^{{Cite journal|last=Brodt|first=M.|last2=Cook|first2=L. S.|last3=Lakes|first3=R. S.|date=1995|title=Apparatus for measuring viscoleastic properties over ten decades: Refinements|url=|journal=Review of Scientific Instruments|volume=66|issue=11|pages=5292|via=|bibcode=1995RScI...66.5292B|doi=10.1063/1.1146101}}