Hostname: page-component-586b7cd67f-dlnhk Total loading time: 0 Render date: 2024-11-22T06:40:00.106Z Has data issue: false hasContentIssue false

Increasing contribution of grain boundary compliance to polycrystalline ice elasticity as temperature increases

Published online by Cambridge University Press:  18 July 2018

COLIN M. SAYERS*
Affiliation:
Houston, TX, USA
*
Correspondence: Colin M. Sayers <[email protected]>
Rights & Permissions [Opens in a new window]

Abstract

Measured elastic stiffnesses of ice polycrystals decrease with increasing temperature due to a decrease in grain boundary stiffness with increasing temperature. In this paper, we represent grain boundaries as imperfectly bonded interfaces, across which traction is continuous, but displacement may be discontinuous. We express the additional compliance due to grain boundaries in terms of a second-rank and a fourth-rank tensor, which quantify the effect on elastic wave velocities of the orientation distribution as well as the normal and shear compliances of the grain boundaries. Measurement of the elastic stiffnesses allows determination of the components of these tensors. Application of the method to resonant ultrasound spectroscopy measurements made on ice polycrystals enables determination of the ratio BN/BS of the normal to shear compliance of the grain boundaries, which are found to be more compliant in shear than in compression. The ratio BN/BS is small at low temperatures, but increases as temperature increases, implying that the normal compliance increases relative to the shear compliance as temperature increases.

Type
Papers
Creative Commons
Creative Common License - CCCreative Common License - BYCreative Common License - NCCreative Common License - ND
This is an Open Access article, distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives licence (http://creativecommons.org/licenses/by-nc-nd/4.0/), which permits non-commercial re-use, distribution, and reproduction in any medium, provided the original work is unaltered and is properly cited. The written permission of Cambridge University Press must be obtained for commercial re-use or in order to create a derivative work.
Copyright
Copyright © The Author(s) 2018

NOTATION

a

radius of a pore represented as an oblate spheroid

A (r)

the area of the r-th grain boundary

B

grain boundary compliance tensor with components B ij

B N

normal compliance of a grain boundary

B S

shear compliance of a grain boundary

c

half-thickness of a pore represented as an oblate spheroid

c/a

aspect ratio (thickness divided by lateral extent)

C

fourth-rank elastic stiffness tensor with components C ijkl

C ij

components of the fourth-rank elastic stiffness tensor in the two-index notation (Voigt, Reference Voigt1910; Nye, Reference Nye1985)

k

wavenumber

K

bulk modulus

K 0

bulk modulus of the sample when the ice crystals are fully bonded as occurs at low temperatures

K r

permeability of the medium including the contribution of the grain boundaries

n

the unit normal (vector) to a grain boundary

$n_i^{(r)} $

the i-th component of the normal to the r-th grain boundary

S

fourth-rank elastic compliance tensor with components S ijkl

$S_{ijkl}^0 $

components of the fourth-rank elastic compliance tensor that polycrystalline ice would have if the ice crystals formed a continuous framework

ΔS ijkl

components of the fourth-rank excess compliance tensor that results from the presence of grain boundaries

t

traction vector

t i

the i-th component of the traction vector

u

displacement vector

u i

the i-th component of the displacement vector

[u]

difference in displacement between opposing sides of a grain boundary

[u N]

component of the difference in displacement between opposing sides that is normal to a grain boundary

[u S]

component of the difference in displacement between opposing sides that is parallel to a grain boundary

V

volume

V P

compressional velocity; P-wave velocity

V S

shear velocity; S-wave velocity

X 1, X 2, X 3

reference set of Cartesian axes with X 3 normal to a grain boundary

x 1, x 2, x 3

reference set of Cartesian axes fixed in the sample

α ij

components of the second-rank compliance tensor α representing the mechanical effect of the grain boundaries in polycrystalline ice

β ijkl

components of the fourth-rank compliance tensor β representing the mechanical effect of the grain boundaries in polycrystalline ice

δ ij

Kronecker delta with the property that δ ij = 1 if i = j, and δ ij = 0 if i ≠ j

η f

fluid viscosity

κ f

fluid bulk modulus

μ

shear modulus

μ 0

shear modulus of the sample when the ice crystals are fully bonded as occurs at low temperatures

ν

Poisson's ratio

ρ

density

ω

angular frequency

INTRODUCTION

Grain boundaries in polycrystalline ice influence various mechanical phenomena such as creep, yield and fracture (Higashi, Reference Higashi1978). Grain boundaries may affect the use of elastic waves to investigate the properties of ice sheets and glaciers such as ultrasonic velocity measurements on cores (Bennett, Reference Bennett1968; Gow and Kohnen, Reference Gow and Kohnen1979; Kohnen and Gow, Reference Kohnen and Gow1979; Langway and others, Reference Langway, Shoji and Azuma1988; Anandakrishnan and others, Reference Anandakrishnan, Fitzpatrick, Alley, Gow and Meese1994), sonic logs (Bentley, Reference Bentley1972; Gusmeroli and others, Reference Gusmeroli, Pettit, Kennedy and Ritz2012; Kluskiewicz and others, Reference Kluskiewicz2017) and seismic methods (Bentley, Reference Bentley1972; Bentley and Kohnen, Reference Bentley and Kohnen1976; Blankenship and Bentley, Reference Blankenship and Bentley1987; Horgan and others, Reference Horgan2008; Wittlinger and Farra, Reference Wittlinger and Farra2012; Picotti and others, Reference Picotti, Vuan, Carcione, Horgan and Anandakrishnan2015; Smith and others, Reference Smith2017). Above −10°C, Duval and others (Reference Duval, Ashby and Anderman1983) report a large change in grain boundary mobility, which they suggest may be due to grain boundary melting that involves a zone with liquid-like structure at the grain boundaries. Such liquid-like water may exist at grain boundaries at temperatures as low as −30°C (Hobbs, Reference Hobbs1974; Dash and others Reference Dash, Fu and Wettlaufer1995; Vaughan and others, Reference Vaughan, Wijk, Prior and Bowman2016). This may play a role in the mechanical behavior of ice sheets, since temperatures at the base may exceed the melting point even though near-surface temperatures are typically below −20°C (Iken and others, Reference Iken, Echelmeyer, Harrison and Funk1993; Engelhardt, Reference Engelhardt2004; Joughin and others, Reference Joughin, Tulaczyk, MacAyeal and Engelhardt2004; Cuffey and Paterson, Reference Cuffey and Paterson2010; Pattyn, Reference Pattyn2010; Vaughan and others, Reference Vaughan, Wijk, Prior and Bowman2016).

The purpose of this paper is to obtain information of the variation in the elastic compliance of grain boundaries in polycrystalline ice as a function of temperature from elastic wave measurements. For this, the measurements of Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) are used. These authors employ resonant ultrasound spectroscopy and ultrasonic transmission measurements to determine the temperature dependence of the elastic and anelastic properties of samples of polycrystalline ice with homogeneous texture and grain size <1 cm. Electron backscatter diffraction showed that the samples used had a close to random orientation distribution of ice crystals. Estimates of elastic anisotropy indicated a P-wave anisotropy of order 0.1%, so that the samples may be treated as elastically isotropic (Vaughan and others, Reference Vaughan, Wijk, Prior and Bowman2016).

Resonant ultrasound spectroscopy measurements were performed on polycrystalline ice by Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) between −26°C and −5°C. Estimates of the compressional elastic stiffness C 11, corresponding to the P-wave velocity $V_{\rm P} = \sqrt {C_{11}/\rho} $, where ρ is density, and shear stiffness C 55, corresponding to the S-wave velocity $V_{\rm S} = \sqrt {C_{55}/\rho} $, obtained by Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) using these measurements, assuming the samples are isotropic, are shown in Figure 1. The elastic stiffnesses are seen to decrease with increasing temperature. However, the elastic stiffness C 11 is more sensitive to temperature than the elastic stiffness coefficient C 55, and Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) attribute this to liquid phases on ice grain boundaries associated with pre-melting conditions.

Fig. 1. Elastic stiffness coefficients C 11 (circles and left scale) and C 55 (squares and right scale) as a function of temperature estimated by Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) based on resonant ultrasound spectroscopy measurements.

To estimate the mechanical properties of the grain boundaries based on the measured elastic stiffnesses, we use a model in which the grain boundaries are represented as imperfectly bonded interfaces, across which traction is continuous, but displacement may be discontinuous (Schoenberg, Reference Schoenberg1980; Kachanov, Reference Kachanov1992). The elastic anisotropy caused by the presence of the grain boundaries is represented in terms of a second-rank and a fourth-rank tensor (Sayers and Kachanov, Reference Sayers and Kachanov1995) that quantify the dependence of the elastic stiffness coefficients on the normal and shear compliances of the grain boundaries and their orientation distribution. The model allows components of these tensors to be estimated from measurements of the elastic stiffness coefficients of polycrystalline ice as a function of temperature. The next section describes the model used. Following this, results from applying the model to estimate the mechanical properties of the grain boundaries from the elastic stiffness estimates of Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) are presented, followed by the conclusions of this work.

MODEL DESCRIPTION

We represent the effects of the grain boundaries on the elastic stiffnesses in the presence of melt, by modeling the grain boundaries as locally flat imperfectly bonded interfaces, across which traction t is continuous as shown schematically in Figure 2. The displacement u may be different on opposing sides of the grain boundary due to the deformation of the boundary (Schoenberg, Reference Schoenberg1980). It is convenient to introduce a Cartesian reference set of axes x 1, x 2, x 3, fixed in the sample. The difference in displacement of opposing sides of the grain boundary is denoted by [u], with Cartesian components [u i], i = 1,  2,  3. For small deformations, as occurs in the resonant ultrasound spectroscopy measurements of Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016), [u] is linear in the traction, and the i-th component may be written as

(1)$$[u_i] = B_{ij}t_j.$$

In this equation, as elsewhere in this paper, the Einstein summation convention, in which a summation is made over repeated indices (i,  j,  k,  l = 1,  2,  3), is used. The quantity t j is the j-th component of the traction vector, and B ij are components of the second-rank grain boundary compliance tensor B. Equation (1) describes the mechanical behavior of a grain boundary modeled as an imperfectly bonded interface between grains, and depends on the nature of the contacts between grains, the number of contacts per unit area, the deformability of any open regions between grain contacts, any fluids within the grain boundary, etc. If there is rotational symmetry around the normal to the grain boundary, it follows from Schoenberg (Reference Schoenberg1980) and Kachanov (Reference Kachanov1992) that B ij may be represented in terms of a normal compliance B N and shear compliance B S as follows:

(2)$$B_{ij} = B_{\rm N}n_in_j + B_{\rm S}(\delta _{ij} - n_in_j),$$

where n i is the i-th component of the unit normal n to the grain boundary. The Kronecker delta δ ij has the property that δ ij = 1 if i = j, and δ ij = 0 if i ≠ j. The normal and shear grain boundary compliances B N and B S will be used below to determine the contribution of grain boundaries to the elastic stiffness coefficients of polycrystalline ice.

Fig. 2. Schematic representation of part of a grain boundary in ice modeled as a locally flat imperfectly bonded interface. The normal and shear displacements of the upper face of the grain boundary are denoted by $u_{\rm N}^ + $ and $u_{\rm S}^ + $, whereas those of the lower face are denoted by $u_{\rm N}^ - $ and $u_{\rm S}^ - $. The normal and shear components of the difference in displacement between opposing sides of the grain boundary are given by $[u_{\rm N}] = u_{\rm N}^ + - u_{\rm N}^ - $ and $[u_{\rm S}] = u_{\rm S}^ + - u_{\rm S}^ - $, and are related to the normal and shear tractions t N and t S by the equations shown in the figure.

We denote the components of the fourth-rank elastic stiffness tensor C of polycrystalline ice by C ijkl (i, j, k, l = 1, 2, 3), and the components of the fourth-rank elastic compliance tensor S of polycrystalline ice by S ijkl.

In the presence of grain boundaries having different orientation, the S ijkl may be written in the form:

(3)$$S_{ijkl} = S_{ijkl}^0 + \Delta S_{ijkl},$$

where $S_{ijkl}^0 $ are the components of the elastic compliance tensor S(0) for the case in which the effect of grain boundary compliance may be considered negligible, as will be assumed to be the case at the lowest temperature (−26°C) in the experiments of Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016). For an anisotropic orientation distribution of ice crystals, S(0) is anisotropic, although estimates of elastic anisotropy in their samples by Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) indicated a P-wave anisotropy of order 0.1%, so that the samples may be treated as elastically isotropic. S(0) includes also the effect of any porosity in the interior of the ice crystals, which is assumed not to vary with temperature. This porosity is estimated by Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) to be of order 1%. The components ΔS ijkl of the excess compliance tensor due to the presence of the grain boundaries can be written in terms of a second-rank tensor α and fourth-rank tensor β (Sayers and Kachanov, Reference Sayers and Kachanov1995) as:

(4)$$\Delta S_{ijkl} = \displaystyle{1 \over 4}(\delta _{ik}\alpha _{\,jl} + \delta _{il}\alpha _{\,jk} + \delta _{\,jk}\alpha _{il} + \delta _{\,jl}\alpha _{ik}) + \beta _{ijkl}.$$

The components α ij and β ijkl of α and β are defined by

(5)$$\alpha _{ij} = \displaystyle{1 \over V}\sum\limits_{r = 1}^N {B_{\rm S}^{(r)} n_i^{(r)} n_j^{(r)} A^{(r)}}, $$
(6)$$\beta _{ijkl} = \displaystyle{1 \over V}\sum\limits_{r = 1}^N {\left( {B_{\rm N}^{(r)} - B_{\rm S}^{(r)}} \right)n_i^{(r)} n_j^{(r)} n_k^{(r)} n_l^{(r)} A^{(r)}}. $$

The sum is over the N grain boundaries in volume V. The quantities $B_{\rm N}^{(r)} $ and $B_{\rm S}^{(r)} $ are the normal and shear compliance of the r-th grain boundary in volume V, $n_i^{(r)} $ is the i-th component of the local unit normal to the r-th grain boundary, and A (r) is the local area of the grain boundary (Sayers and Kachanov, Reference Sayers and Kachanov1995). Because the components of the unit normal to the grain boundaries appear as products in (5) and (6), it follows that α ij and β ijkl are symmetric with respect to all rearrangements of the indices so that β 1122 = β 1212,  β 1133 = β 1313 , etc.

This model allows information on grain boundary compliance to be obtained from measured elastic stiffnesses, as will be illustrated next using the elastic stiffnesses of polycrystalline ice measured by Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) as a function of temperature. The samples used by Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) were found to be close to isotropic. Assuming an isotropic orientation distribution of grain boundaries, several components α ij and β ijkl are zero, and the non-vanishing components can be written in terms of quantities α and β, defined as follows (Sayers and Kachanov, Reference Sayers and Kachanov1995):

(7)$$\alpha _{11} = \alpha _{22} = \alpha _{33} = \alpha, $$
(8)$$\beta _{1111} = \beta _{2222} = \beta _{3333} = \beta $$

and

(9)$$\beta _{1122} = \beta _{1133} = \beta _{2233} = \beta _{1212} = \beta _{1313} = \beta _{2323} = \beta /3.$$

The non-vanishing components ΔS ijkl follow from (4) as (Sayers, Reference Sayers2002):

(10)$$\Delta S_{1111} = \Delta S_{2222} = \Delta S_{3333} = \alpha + \beta, $$
(11)$$\Delta S_{1122} = \Delta S_{1133} = \Delta S_{2233} = \beta /3,$$
(12)$$\Delta S_{1212} = \Delta S_{1313} = \Delta S_{2323} = \alpha /2 + \beta /3.$$

The elastic stiffness tensor C is obtained as the inverse of the compliance tensor S with components S ijkl given by (3) with the ΔS ijkl given by (10)–(12).

The symmetry of the elastic stiffness tensor C and the elastic compliance tensor S enables use of a condensed 6 × 6 two-index notation (Voigt, Reference Voigt1910; Nye, Reference Nye1985) in which pairs of subscripts ij and kl are abbreviated by single subscripts according to the convention, 11 → 1, 22 → 2, 33 → 3, 23, 32 → 4, 13, 31 → 5 and 12, 21 → 6. For an isotropic medium, the elastic stiffness components C ij in two-index notation may be written in terms of the isotropic bulk modulus K and shear modulus μ as

(13)$$\left[ {C_{ij}} \right] = \left[ {\matrix{ {K + 4\mu /3} & {K - 2\mu /3} & {K - 2\mu /3} & 0 & 0 & 0 \cr {K - 2\mu /3} & {K + 4\mu /3} & {K - 2\mu /3} & 0 & 0 & 0 \cr {K - 2\mu /3} & {K - 2\mu /3} & {K + 4\mu /3} & 0 & 0 & 0 \cr 0 & 0 & 0 & \mu & 0 & 0 \cr 0 & 0 & 0 & 0 & \mu & 0 \cr 0 & 0 & 0 & 0 & 0 & \mu \cr}} \right].$$

It then follows from (3), (4) and (10)–(12) that the bulk modulus K and shear modulus μ are given in terms of the bulk modulus K 0 and shear modulus μ 0 of the sample when the ice crystals are fully bonded, as will be assumed to be the case at the lowest temperature (−26°C) in the experiments of Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016), by

(14)$$K = \displaystyle{{K_0} \over {1 + 3K_0(\alpha + 5\beta /3)}},$$
(15)$$\mu = \displaystyle{{\mu _0} \over {1 + 2\mu _0(\alpha + 2\beta /3)}}$$

(Sayers and Han, Reference Sayers and Han2002). These equations allow α and β to be determined from measurements of the elastic stiffness coefficients C 11 = K + 4μ/3 and C 44 = μ, and knowledge of K 0 and μ 0. For an isotropic orientation distribution of grain boundaries, it follows from (5) and (6) that B N/B S = 1 + 5β/3α (Sayers and Han, Reference Sayers and Han2002), where the average normal and shear compliance are denoted by B N and B S, and this estimate is valid when the shear compliance of the grain boundaries is non-zero. This allows B N/B S to be estimated from the ratio β/α obtained from (14) and (15).

RESULTS

Since α and β have units of compliance, it is more convenient to plot the dimensionless quantities μ 0α and μ 0β where μ 0 is the shear modulus of the sample when the ice crystals are fully bonded. Figure 3 shows the values of μ 0α and μ 0β obtained from (14) and (15), where K and μ are calculated from C 11 and C 44 shown in Figure 1 using the isotropic equations K = C 11 − 4C 44/3, μ = C 44. Note that α and β are of opposite sign, and this implies that B N/B S < 1, as seen from (5) and (6). The grain boundaries appear, therefore, to be more compliant in shear than under a normal stress.

Fig. 3. Values of normalized grain boundary compliance tensor components μ 0α (circles) and μ 0β (squares) estimated from the elastic stiffness coefficients C 11 and C 55 measured by Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) based on resonant ultrasound spectroscopy.

The theory used to estimate μ 0α and μ 0β from the measured elastic stiffnesses C 11 and C 55 is a general representation of the mechanical behavior of a grain boundary modeled as an imperfectly bonded interface between grains, and includes the mechanical behavior of the contacts between grains, the number of contacts per unit area, the deformability of any open regions between grain contacts, the fluid distribution within the grain boundary, etc. It is interesting, however, to compare the results for B N/B S obtained from the measurements of Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) with a simple model in which the grain boundaries are considered to be porous, the pores being assumed to be oblate spheroids with radius a and aspect ratio c/a in a homogeneous background medium with shear modulus μ and Poisson's ratio ν. An oblate spheroid is an ellipsoid obtained by rotating an ellipse about its minor axis, with equatorial dimension a greater than the polar dimension c. The additional compliance introduced by the spheroid depends on the properties of the host medium and the fluid within the spheroid. For the case of spheroidal voids with the ability of fluid exchange via small pathways, Hudson and others (Reference Hudson, Liu and Crampin1996) show that for a random distribution of coplanar spheroids in an infinite domain, the ratio B N/B S is

(16)$$\displaystyle{{B_{\rm N}} \over {B_{\rm S}}} = \displaystyle{{\left( {1 + A} \right)\left( {1 - \nu /2} \right)} \over {1 + B}},$$

where

(17)$$A = \displaystyle{{4a} \over {\pi c}}\left( {\displaystyle{{i\omega \eta _{\rm f}} \over \mu}} \right)\left( {\displaystyle{{1 - \nu} \over {2 - \nu}}} \right),$$
(18)$$B = \left[ {\displaystyle{{2a} \over {\pi c}}\displaystyle{{\kappa _{\rm f}} \over \mu} \left( {1 - \nu} \right)} \right]\left( {1 - \displaystyle{{3i\kappa _{\rm f}k^2K_r} \over {4\pi \nu a^2c\omega \eta _{\rm f}}}} \right)^{ - 1}.$$

In (17) and (18), $i = \sqrt { - 1} $, κ f and η f are the bulk modulus and viscosity of the fluid, respectively, ω is the angular frequency, k is the wavenumber and K r is the permeability of the medium including the contribution of the grain boundaries. Because (16)–(18) are frequency dependent and have a real and imaginary part, this will lead to dispersion and attenuation of the elastic wave. These effects lie outside the scope of the current work, however, whose objective is to examine the dependence of the real part of the elastic stiffness coefficients on the grain boundary compliances.

For low permeability, as would occur if the aspect ratio c/a is small, or if the grain boundaries are poorly connected, the compliance ratio in (16) simplifies to

(19)$$\displaystyle{{B_{\rm N}} \over {B_{\rm S}}} = \displaystyle{{\left( {1 + A} \right)\left( {1 - \nu /2} \right)} \over {\left[ {1 + \displaystyle{{2a} \over {\pi c}}\displaystyle{{\kappa _{\rm f}} \over \mu} \left( {1 - \nu} \right)} \right]}}.$$

A decrease in the aspect ratio c/a and an increase in the bulk modulus of the fluid κ f both lead to a decrease in compliance ratio.

Figure 4 shows the variation in B N/B S as a function of temperature determined from the results shown in Figure 3. It is seen that B N/BS < 1 implying that the grain boundaries are more compliant in shear than in compression. The ratio B N/B S is seen to be small at low temperatures, but increases as temperature increases, implying that the normal compliance increases relative to the shear compliance with increasing temperature.

Fig. 4. Variation in the ratio B N/B S of the normal compliance B N to shear compliance B S as a function of temperature determined from the results shown in Figure 3.

CONCLUSION

This paper presents a determination of the normal and shear compliance of grain boundaries in polycrystalline ice from the temperature-dependent elastic stiffness measured by Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016). The approach is formulated in terms of a second-rank tensor α and fourth-rank tensor β that depend on the orientation distribution as well as the normal and shear compliance of the grain boundaries. This allows one to obtain the normal and shear compliance of the grain boundaries as a function of temperature from measurements of the elastic stiffness coefficients. We applied the method to estimates of elastic stiffness coefficients based on resonant ultrasound spectroscopy measurements on polycrystalline ice between −26°C and −5°C. Notably, α and β were found to have opposite signs. This implies that the ratio of the normal to shear compliance B N/B S < 1. Grain boundaries in polycrystalline ice are, therefore, more compliant in shear than in compression. The ratio B N/B S is small at low temperatures, but increases as temperature increases implying that the normal compliance increases relative to the shear compliance as temperature increases.

It should be noted that the results presented are obtained for a single sample investigated by Vaughan and others (Reference Vaughan, Wijk, Prior and Bowman2016) that has a particular grain size distribution. It would be interesting to repeat these calculations for other samples having a different size distribution of ice crystals, once such measurements become available, since this will allow the grain size dependence of the grain boundary compliance to be investigated. Also, since the number of grain boundaries will increase with decreasing grain size, measurements of ultrasonic attenuation on samples having different grain size distributions may allow the effects of scattering to be separated from attenuation due to viscous damping resulting from the effects of the viscosity of the fluid at the grain boundaries. This appears to be a promising area for future work.

ACKNOWLEDGEMENT

I thank Professor David J Prior, University of Otago, for many helpful suggestions that led to a significant improvement of the manuscript.

References

REFERENCES

Anandakrishnan, S, Fitzpatrick, JJ, Alley, RB, Gow, AJ and Meese, DA (1994) Shear-wave detection of asymmetric c-axis fabrics in the GISP2 ice core, Greenland. J. Glaciol., 40(136), 491496Google Scholar
Bennett, HF (1968) An investigation into velocity anisotropy through measurements of ultrasonic wave velocities in snow and ice cores from Greenland and Antarctica. (PhD thesis, University of Wisconsin, [Madison])Google Scholar
Bentley, CR (1972) Seismic wave velocities in anisotropic ice: a comparison of measured and calculated values in and around the deep drill hole at Byrd Station, Antarctica. J. Geophys. Res., 77(23), 55065520Google Scholar
Bentley, CR and Kohnen, H (1976) Seismic refraction measurements of internal friction in Antarctic ice. J. Geophys. Res., 81, 15191526Google Scholar
Blankenship, DD and Bentley, CR (1987) The crystalline fabric of polar ice sheets inferred from seismic anisotropy. In The physical basis of ice sheet modelling, IAHS Publ., 170, 1728Google Scholar
Cuffey, KM and Paterson, WSB (2010) The physics of glaciers. Elsevier, New YorkGoogle Scholar
Dash, JG, Fu, H and Wettlaufer, JS (1995) The premelting of ice and its environmental consequences. Rep. Prog. Phys., 58(1), 115Google Scholar
Duval, P, Ashby, MF and Anderman, I (1983) Rate-controlling processes in the creep of polycrystalline ice. J. Phys. Chem., 87(21), 40664074Google Scholar
Engelhardt, H (2004) Thermal regime and dynamics of the West Antarctic ice sheet. Ann. Glaciol., 39(1), 8592Google Scholar
Gow, AJ and Kohnen, H (1979) The relationship of elastic stiffnesses to c-axis fabrics and relaxation characteristics of ice cores from Byrd Station, Antarctica. J. Glaciol., 24, 147153Google Scholar
Gusmeroli, A, Pettit, EC, Kennedy, JH and Ritz, C (2012) The crystal fabric of ice from full-waveform borehole sonic logging. J. Geophys. Res. Earth Surf., 117(F3), F03021Google Scholar
Higashi, A (1978) Structure and behaviour of grain boundaries in polycrystalline ice. J. Glaciol., 21(85), 589605Google Scholar
Hobbs, PV (1974) Ice physics. Clarendon Press, OxfordGoogle Scholar
Horgan, HJ and 6 others (2008) Complex fabric development revealed by englacial seismic reflectivity: Jakobshavn Isbræ, Greenland. Geophys. Res. Lett., 35, L10501Google Scholar
Hudson, JA, Liu, E and Crampin, S (1996) The mechanical properties of materials with interconnected cracks and pores. Geophys. J. Int., 124(1), 105112Google Scholar
Iken, A, Echelmeyer, K, Harrison, W and Funk, M (1993) Mechanisms of fast flow in Jakobshavns Isbræ, West Greenland: Part I. Measurements of temperature and water level in deep boreholes. J. Glaciol., 39(131), 1525Google Scholar
Joughin, I, Tulaczyk, S, MacAyeal, DR and Engelhardt, H (2004) Melting and freezing beneath the Ross ice streams, Antarctica. J. Glaciol., 50(168), 96108Google Scholar
Kachanov, M (1992) Effective elastic properties of cracked solids: critical review of some basic concepts. Appl. Mech. Rev., 45, 304335Google Scholar
Kluskiewicz, D and 5 others (2017) Sonic methods for measuring crystal orientation fabric in ice, and results from the West Antarctic ice sheet (WAIS) Divide. J. Glaciol., 63(240), 603617Google Scholar
Kohnen, H and Gow, AJ (1979) Ultrasonic velocity investigations of crystal anisotropy in deep ice cores from Antarctica. J. Geophys. Res. Oceans, 84(C8), 48654874Google Scholar
Langway, CC, Shoji, H and Azuma, N (1988) Crystal size and orientation patterns in the Wisconsin-age ice from Dye 3, Greenland. Ann. Glaciol., 10, 109115Google Scholar
Nye, JF (1985) Physical properties of crystals. Oxford University Press, OxfordGoogle Scholar
Pattyn, F (2010) Antarctic subglacial conditions inferred from a hybrid ice sheet/ice stream model. Earth Planet. Sci. Lett., 295(3), 451461Google Scholar
Picotti, S, Vuan, A, Carcione, JM, Horgan, HJ and Anandakrishnan, S (2015) Anisotropy and crystalline fabric of Whillans Ice Stream (West Antarctica) inferred from multicomponent seismic data. J. Geophys. Res. Solid. Earth, 120, 42374262Google Scholar
Sayers, CM (2002) Stress-dependent elastic anisotropy of sandstones. Geophys. Prospect., 50, 8595Google Scholar
Sayers, CM and Han, DH (2002) The effect of pore fluid on the stress-dependent elastic wave velocities in sandstones. In SEG technical program expanded abstracts 2002. Society of Exploration Geophysicists 72nd meeting, Salt Lake City, pp. 1842–1845Google Scholar
Sayers, CM and Kachanov, M (1995) Microcrack-induced elastic wave anisotropy of brittle rocks. J. Geophys. Res., 100, 41494156Google Scholar
Schoenberg, M (1980) Elastic wave behavior across linear slip interfaces. J. Acoust. Soc. Am., 68, 15161521Google Scholar
Smith, EC and 12 others (2017) Ice fabric in an Antarctic ice stream interpreted from seismic anisotropy. Geophys. Res. Lett., 55, 37103718Google Scholar
Vaughan, MJ, Wijk, KV, Prior, DJ and Bowman, MH (2016) Monitoring the temperature-dependent elastic and anelastic properties in isotropic polycrystalline ice using resonant ultrasound spectroscopy. Cryosphere, 10, 28212829Google Scholar
Voigt, W (1910) Lehrbuch der Krystallphysik: (mit Ausschluss der Krystalloptik). BG Teubner-Verlag, LeipzigGoogle Scholar
Wittlinger, G and Farra, V (2012) Observation of low shear wave velocity at the base of the polar ice sheets: evidence for enhanced anisotropy. Geophys. J. Int., 190, 391405Google Scholar
Figure 0

Fig. 1. Elastic stiffness coefficients C11 (circles and left scale) and C55 (squares and right scale) as a function of temperature estimated by Vaughan and others (2016) based on resonant ultrasound spectroscopy measurements.

Figure 1

Fig. 2. Schematic representation of part of a grain boundary in ice modeled as a locally flat imperfectly bonded interface. The normal and shear displacements of the upper face of the grain boundary are denoted by $u_{\rm N}^ + $ and $u_{\rm S}^ + $, whereas those of the lower face are denoted by $u_{\rm N}^ - $ and $u_{\rm S}^ - $. The normal and shear components of the difference in displacement between opposing sides of the grain boundary are given by $[u_{\rm N}] = u_{\rm N}^ + - u_{\rm N}^ - $ and $[u_{\rm S}] = u_{\rm S}^ + - u_{\rm S}^ - $, and are related to the normal and shear tractions tN and tS by the equations shown in the figure.

Figure 2

Fig. 3. Values of normalized grain boundary compliance tensor components μ0α (circles) and μ0β (squares) estimated from the elastic stiffness coefficients C11 and C55 measured by Vaughan and others (2016) based on resonant ultrasound spectroscopy.

Figure 3

Fig. 4. Variation in the ratio BN/BS of the normal compliance BN to shear compliance BS as a function of temperature determined from the results shown in Figure 3.