Introduction

Reference McTigue, McTigue, Passman and JonesMcTigue and others (1985) studied the possibility of normal stress effects in the creep of polycrystalline ice. Normal stress effects are phenomena that follow from non-zero and unequal normal stress differences in shearing flow; they are among the first manifestations of non-linearity in many fluids. McTigue and others criticized Glen’s flow law, because it necessarily excludes consideration of normal stress effects. They adopted as a tentative model for ice the second-order fluid (i.e. one of the simplest models that can represent normal stress effects) and estimated the three material parameters in the model from data of four triaxial creep tests. (Their creep tests were performed at the same temperature and the same deviatoric stress, but at different confining pressures. Here we follow common usage and call those creep tests “triaxial”. McTigue and others used the adjective “biaxial”.) McTigue and others reported that the resulting model gave an excellent representation of their data for both primary and secondary creep. Using the same model, they reached the conclusion that normal stress effects could influence the development of crevasses and could lead to measurable depression of the surface of glaciers on sufficiently steep slopes.

As noted by McTigue and others, the second-order fluid is in no way a replacement for, nor a generalization of, Reference GlenGlen’s (1952, Reference Glen1955) flow law. Indeed, the second-order fluid “fails to represent the non-linear rate dependence of ice in shear”; as such, it is in fact not a suitable constitutive model for glacier ice in shearing flow. Take, for instance, Nye’s first model of a glacier as an infinite slab of ice of uniform thickness flowing down a rough inclined plane (Reference NyeNye, 1952, Reference Nye1957). Consider steady laminar flow. For a slab of second-order fluid, the velocity field will be identical to that of an incompressible linearly viscous fluid. Such an implication is certainly undesirable. Since McTigue and others used the second-order fluid to model ice when they discussed the possible significance of normal stress effects in the flow of glaciers, the conclusion they reached, namely that normal stress effects may be discernible in natural glacier flow, is questionable.

Glen’s flow law, as extended to cover multi-axial states of stress by Reference NyeNye (1953, Reference Nye1957), in effect models poly-crystalline ice as an incompressible power-law fluid (cf. Reference Bird, Bird, Armstrong and HassagerBird and others, 1977, p. 208). It is the most widely used empirical flow law for polycrystalline ice under stress. While its successes are well documented (Reference HookeHooke, 1981), it has its shortcomings, namely: it can only describe secondary creep, and it does not predict any normal stress effect in shearing flow of ice (cf. Reference McTigue, McTigue, Passman and JonesMcTigue and others (1985) for a more detailed criticism).

Motivated by a preliminary version of the paper of Reference McTigue, McTigue, Passman and JonesMcTigue and others, Reference Man, Man, Shields, Kjartanson, Sun and RasmussenMan and others (1985) initiated are search program in 1984, the purpose of which has been to seek a simple modification of Glen’s flow law that obviates the aforementioned shortcomings. Based on results of pressuremeter creep tests performed by Kjartanson and Shields at the University of Manitoba (Reference KjartansonKjartanson, unpublished) and with the help of Sun in numerical work, Man has proposed two tentative modifications of Glen’s flow law. The purpose of the present note is to re-examine the issues discussed by Reference McTigue, McTigue, Passman and JonesMcTigue and others (1985) when the second-order fluid in their paper is replaced by the two new tentative models (I) and (II). For ease of comparison, material parameters in models (I) and (II) will be estimated by fitting data of the four triaxial creep tests of McTigue and others.

The specific choice of tentative models (I) and (II) was mainly guided by empiricism and the requirement of simplicity. We want to seek a simple model which will combine the merits of the partially successful power-law and second-order fluid models. Compared with the second-order fluid, which follows from the rational approximation scheme of Reference Coleman and NollColeman and Noll (1960), some readers will find models (I) and (II) much less appealing to their intellect. All mathematical theorems, however, are logical deductions from specific assumptions. The assumptions upon which the approximation scheme of Coleman and Noll is based need not apply to the creep of polycrystalline ice. And apparently they do not, as we can gather from what is known about the creep behavior of ice. In the history of physics, it is more common than otherwise that empirical laws were discovered long before any rationale could be found to justify their existence.

In this note, by Glen’s flow law we shall mean either the formulation in terms of “octahedral strain-rate” and octahedral shear stress (see Equation (5) below) or the generalization due to Reference NyeNye (1953, Reference Nye1957), i.e. the power-law fluid model, which is sometimes known as “the generalized flow law“ in the literature (e.g. Reference PatersonPaterson, 1981, p. 30). It should be clear from the context which of the two versions we really mean when we refer to Glen’s flow law below.

Two Modifications of Nye’s Generalization of Glen’s Flow Law

In what follows we shall, with few exceptions, adopt the notation of Reference McTigue, McTigue, Passman and JonesMcTigue and others (1985). Tensors will be denoted by Cartesian indicial notation. To conserve space, we shall not reproduce definitions of terms such as normal stress differences and Rivlin–Ericksen tensors, which are given in the paper of McTigue and others and in texts of non-Newtonian fluid mechanics (e.g. Reference SchowalterSchowalter, 1978).

Man has proposed the following two constitutive equations as tentative modifications of “the generalized flow law”:

here T_ij is the Cauchy stress tensor; p is the indeterminate pressure due to incompressibility; A_ij ⁽¹⁾ and A_ij ⁽²⁾ are the first and the second Rivlin–Ericksen tensor, respectively; because of incompressibility; μ, α₁, α₂, and m are material parameters, which are constants for polycrystalline ice of given temperature and given structural features such as texture and fabric; the parameter m is related to the exponent n in Glen’s flow law by n = 1/(m + 1) (thence n = 3 corresponds to m = ‒2/3). When α₁ = α₂ = 0, both models (I) and (II) reduce to the power-law fluid, i.e. Glen’s flow law. When m = 0, both models (I) and (II) become the second-order fluid. Both models (I) and (II) belong to a class of fluids introduced by Reference Rivlin and EricksenRivlin and Ericksen (1955); they are special instances of (incompressible) Rivlin–Ericksen fluids of complexity 2 and are formally included in a class of fluids studied by Reference DunnDunn (1982). They are also special instances of a class of fluids proposed by Reference Morland and SpringMorland and Spring (1981) for modeling the deformation of ice. Both models satisfy the principle of material frame-indifference (Reference Truesdell, Noll and FlügeTruesdell and Noll, 1965, section 19). Both models are meant for the description of primary and secondary creep, but not tertiary creep.

The specific choice of models (I) and (II) is mainly guided by empiricism and the requirement of simplicity. Model (II), however, can be viewed as the second in a hierarchy of more and more complex models, the first or simplest of which is the usual power-law fluid. We shall call it the power-law fluid of grade 2. In general, by the power-law fluid of grade k we mean the constitutive equation that results when the terms between parentheses in Equation (2) are replaced by terms appropriate to the fluid of grade k in the approximation scheme of Reference Coleman and NollColeman and Noll (1960), The usual power-law fluid is then of grade 1. We call model (I) the modified second-order fluid.

Both models (I) and (II) gave good fits to data of single-stage and multi-stage pressuremeter creep tests (Reference Man, Man, Shields, Kjartanson, Sun and RasmussenMan and others, 1985; Reference KjartansonKjartanson, unpublished), which were performed at ‒2° C with cavity pressure ranging from 1.0 to 2.5 MPa. Between them, model (II) consistently gave better fits. Complete details of fitting have been given by Reference SunSun(unpublished).

For steady laminar flow in Reference NyeNye’s (1952, Reference Nye1957) first model of a glacier, both models (I) and (II) deliver a velocity field identical to that which pertains to Glen’s flow law. The stress distribution, however, is different for all of the three models.

Determination of Material Parameters

The material parameters m, μ, and α₁ in both models(I) and (II) can be determined unambiguously from data of pressuremeter creep tests (Reference Man, Man, Shields, Kjartanson, Sun and RasmussenMan and others, 1985; Reference KjartansonKjartanson, unpublished; Reference SunSun, unpublished); the parameter α₂ does not appear in the differential equation that governs pressuremeter creep tests. The purpose of the present note, however, is to re-examine the conclusions of Reference McTigue, McTigue, Passman and JonesMcTigue and others (1985) in the light of models (I) and (II). For comparison purposes, we should determine the material parameters in models (I) and (II) by fitting data of the triaxial creep tests of McTigue and others.

For triaxial creep tests, we shall adopt the same kinematical assumptions as McTigue and others, namely: during the test the cylindrical specimen undergoes a homogeneous, isochoric, uniaxial elongational flow so that its shape always remains cylindrical. We shall neglect body forces and adopt the creeping-flow approximation.

Under the above assumptions it is straightforward to deduce the differential equations that govern triaxial creep tests for models (I) and (II), respectively. Since the derivation is similar to that presented by McTigue and others for the second-order fluid, here we are content to write down the end equations only. For model (I), the differential equation in question is

here a superposed dot denotes differentiation with respect to time; a = j/l, where l(t) is the length of the cylindrical specimen at the instant t; σ is the axial stress in excess of the confining pressure. For model (II) or the power-law fluid of grade 2, the creep equation is

When m = 0, both Equations (3) and (4) reduce to equation(13) of McTigue and others, i.e. the creep equation for the second-order fluid.

Let be the “octahedral strain-rate”; here 3α ₁ ȧ + 3 μa + 3(α ₁ + α ₂)a ² − (3a ²)^-m/2 σ = 0 is the stretching tensor or “strain-rate” tensor. Let be the octahedral shear stress; here T′ _ij denotes the deviatoric stress tensor. Glen’s flow law is often expressed in terms of and τ in the form

where B and n are material constants (Reference HookeHooke, 1981). For compression tests, the quantity a in Equations (3) and (4) is related to by , whereas σ is related to τ by . When the absolute value of a is at its minimum | a |_min, ȧ = 0. In order that Equations (3) and (4) should deliver Glen’s flow law in secondary creep, the estimates below must be valid for models (I) and (II), respectively:

Models (I) and (II) are meant to be modifications of Nye’s generalization of Glen’s flow law. They should be consistent with laboratory data and field measurements which support Glen’s flow law. Henceforth we shall assume that estimates (6) and (7) be valid for triaxial creep tests with octahedral shear stresses between 0.1 and 1 MPa (Reference HookeHooke, 1981). After setting ȧ = 0 and ignoring the term 3(α₁ + α₂) a ², both Equations (3) and (4) reduce to the equation

Equation (8) will agree with Equation (5) if and only if

All four creep tests of Reference McTigue, McTigue, Passman and JonesMcTigue and others (1985) were done at σ = ‒0.47 MPa and at essentially the same temperature (‒9.5 °C to ‒9.8 °C), but at different confining pressures. Within the framework of either of our models, which assume incompressibility of ice, the four tests would ideally produce the same creep curve should the initial conditions of the tests be identical. With σ fixed, tests under different confining pressures will certainly tell us something about the assumption of incompressibility. Besides that, the four tests will have no more information content than repeating one single test four times.

Indeed, we immediately face the problem of over-parameterization when we attempt to estimate the material parameters in Equations (3) and (4) by fitting the data of McTigue and others. The parameters are ill-determined because of insufficient data. ^* Fortunately, we can still proceed after making some reasonable assumptions.

In fitting the data of McTigue and others, our first assumption was that the value of the parameter m was close to ‒2/3 (i.e. n ≅ 3). This assumption is in line with Reference HookeHooke’s (1981) conclusion in his review on Glen’s flow law.

Only those data (day 1 to day 17) pertaining to primary and secondary creep were used in the fitting. In each test, the initial value of | a | on day 1 was less than 3|a|_min. Equation (8) the value of |a|_min which corresponds to σ = ‒0.47 MPa will be only about 0.01 times that which corresponds to τ = 1 MPa. Since estimates (6) and (7) should still be valid when τ = 1 MPa, it follows that the term 3(α₁ +α₂)a ² in Equations (3) and (4) can be ignored in the present data-fitting. That was exactly what we did; as a result, only three parameters, namely m (≅ ‒2/3), μ, and α₁, were left to be determined.

We can easily recast the data of McTigue and others in terms of the stretch ratio λ(t)= l(t)/L; here L is the original length of the specimen and l(t) is its length at the instant t. By substituting a = and ignoring the term 3(α₁ +α₂)a ² in Equations (3) and (4), we obtain for models (I) and (II) the following second-order differential equations:

The data-fitting problem for model (I) is as follows: for each test we are given a set of data points (t _i, λ_i), where t _i = 1, 2, …, 17 day, and λ_i is the measured valueof λ at t _i From the data we can determine the rate of stretching λ_i at t _i by polynomial interpolation. For a given set of parameters (m, μ, α₁), let λ(t; m, μ, α₁ ) be thesolution to Equation (10) with initial conditions λ(l; m, μ, α₁) = λ₁ and . We want to determine values of the parameters, m, μ, and α₁ which minimize the function

The data-fitting problem for model (II) is similar.

We solved the data-fitting problem for model (I) iteratively by using IMSL (International Mathematical and Statistical Library) sub-routine ZXSSQ (a finite-difference analogue of the Levenberg–Marquardt method). We arrived at a set of initial guesses for (m, μ, α₁) by the following procedure: first we chose a value of m close to ‒2/3. Using this value of m, we calculated the corresponding value of μ from Equation (8) and the measured value of a _min. By polynomial interpolation of the given data, we estimated and at t = 2. From these estimates, λ₂ and the first estimates of m and μ, we obtained a rough first estimate of α₁ from Equation (10). To evaluate the function F at each iteration, the corresponding values λ((t _i; m, μ, α₁) are required. We obtain these values through numerical integration of Equation (10) by using the fifth-order Runge–Kutta–Nyström method (cf. Reference LambertLambert, 1973, p. 122). Similarly, we solved the data-fitting problem for model (II). Complete details of the data-fitting with computer programs have been given by Reference SunSun (unpublished).

The problem of over parameterization persists in the data-fitting even after the parameter α₂ is dropped from the picture. For both models and for each test there are many combinations of m (≅ ‒2/3), μ, and α₁, which give essentially the same value to the sum of squared residuals F. For a given test and for a fixed value of m, however, the estimates of μ and α₁ are sharp for both models. More-over, when m ranges over values close to ‒2/3, the scatter in the numerical estimates of μ and α₁, is rather narrow. For instance, for test 1, as m ranges from ‒0.65 to ‒0.68, we found that for model (I) μ ranges from 2.82 × 10³ to 2.31 × 10³ kPa d^1+m, and α₁ increases from 1.26 × 10⁵ to 1.40 × 10⁵ kPad²; for model (II) μ decreases from 2.84 × 10³ to 2.32 × 10³ kPa d^1+m, and α₁ decreases from 2.75 × 10³ to 2.03 × 10³ kPad^2+m .

In this note we shall be content to obtain for models (I) and (II) an order-of-magnitude estimate of the normalstress effects discussed by McTigue and others. Moreover, we shall be interested only in situations where the normal stress effects have a sufficiently large magnitude to be practically significant. Since the data of McTigue and others all pertain to the same σ and are not sufficient to give a sharp estimate of m, in what follows we shall take m = ‒2/3 (i.e. n = 3) and estimate μ and α₁, on that basis. While this specific choice of m is somewhat arbitrary, it is our best choice and is certainly good enough for our present purpose; our conclusions below are insensitive to variations of m near ‒2/3. For instance, as the reader can easily do the calculations himself, taking m = ‒0.65 or m = ‒0.68 and the corresponding values of μ and α₁ (estimated from test 1) given above will not affect the qualitative conclusions to be drawn below where we take m = ‒ 2/3. Indeed, a sampling of other choices of m in the range ‒0.65 to ‒0.71 all leads to the same qualitative conclusions; cf. Reference SunSun (unpublished).

The least-squares estimates of μ and α₁ when m is fixed at ‒2/3 are listed in Tables I and II. The scatter in the estimated values of the parameters is much narrower than that reported by McTigue and others. Under the estimated values of the material parameters, the fits are excellent for all four tests and for both models. The percentage errors in the fitted values of λ as compared with the measured values are mostly under ±0.02%; the highest percentage errors are about ±0.04%.

Having obtained the value of μ for models (I) and (II), respectively, we can now look at estimates (6) and (7) in detail. Let us consider estimate (6) first. Within the range of octahedral shear stresses under which Glen’s flow law is presumed to be valid (i.e. 0.1 MPa τ 1 MPa), the maximum value of | a |_min corresponds to τ = 1 MPa Substituting σ = ‒3/2^½ MPa and μ = 2.41 × 10³kPa d^1/3, we calculate from Equation (8) that | a | _min = 0.0758 d^‒1 for which the right-hand side of estimate (6) is equal to 1.23 × 10⁵ kPa d². Since a, is estimated to be equal to 1.61 × 10⁵ kPa d², estimate (6) dictates that for model (I) | α₁ + α₂ |should be at least an order of magnitude smaller than α₁. Similarly, for model (II), corresponding to τ = 1 MPa and μ = 2.43 × 10³ kPa d^1/3, the right-hand side of estimate (7) is equal to 3.29 × 10⁴ kPa d^4/3. Thence, we infer that for model (II) | α₁ + α₂ | should be at most of the same order of magnitude as α₁.

Normal Stress Differences in Shearing Flow

Both models (I) and (II) can exhibit non-zero and un-equal normal stress differences in shearing flow (cf. Reference SchowalterSchowaller (1978, p. 71) for the definition of normal stress differences). For models (I) and (II), respectively, the normal stress differences are given by

here k is the shear rate. The formulae for model (I) will be identical to those for the second-order fluid (Reference McTigue, McTigue, Passman and JonesMcTigue and others, 1985) if we replace α₁ and α₂ in Equation (13) by the parameters μ ₂ and μ ₃ of McTigue and others. It is thus possible to compare directly the magnitudes of N ₁ and N ₂ according to our model (I) with those reported by McTigue and others for the second-order fluid model.

For model (I), by using the mean value of α₁ in Table I and by changing units, we obtain

where the shear rate k is in units of s⁻¹. Since all that we know about the parameter α₂ is the estimate (6), we can atbest give an order-of-magnitude estimate of N ₂. Since | α₁ + α₂ | is estimated to be at least an order of magnitude smaller than α₁, | N ₂ | will have the same order of magnitude as | N ₁ |.

For the second-order fluid model, McTigue and others found that N ₁ = 2.1 × 10¹⁹ k² Pa and N ₂ = 3.4 × 10²¹ k² Pa(cf. their equations (23a) and (23b)). Their value of N ₁ is one order of magnitude bigger than the first normal stress difference in our model (I); moreover, it has a different sign. Their value of N ₂ is three orders of magnitude bigger than that in our model (I).

The tremendous discrepancy in the estimates of normal stress differences, we believe, is due in part to the problem of over-parameterization in the data-fitting. As noted by McTigue and others, “good fits … to the creep data can be found for broad ranges of [the] parameters [μ ₂ and μ ₃]”. We overcame the problem of over-parameterization by fixing the value of m at −2/3 (i.e. n = 3) and by ignoring in Equations (3) and (4) the term 3(α₁ + α₂)a ², which should be negligible for consistency with Glen’s flow law. Working with the second-order fluid model is like setting m = 0 in our models at the outset, but there is no longer Glen’s flow law to lean on, for the second-order fluid model is inconsistent with Glen’s flow law. There does not seem to be any convincing way to evade the problem of over-parameterization when one attempts to fit the data of McTigue and others to the second-order fluid model.

Over-parameterization was not a problem in the pressuremeter study of Man and the Manitoba team on polycrystalline ice at −2°C (Reference Man, Man, Shields, Kjartanson, Sun and RasmussenMan and others, 1985; Reference KjartansonKjartanson, unpublished; Reference SunSun, unpublished). For both models(1) and (II), the parameter α₂ simply does not appear in therespective differential equation that governs pressuremeter creep tests. With data of single-stage and multi-stage creeptests in which the cavity pressure ranged from 1.0 to 2.5 MPa and the early time responses were recorded in detail, the parameters m, μ, and α₁ could be determined unambiguously for both models. For the specimens of ice they studied, they found that m was indeed close to −2/3 and α₁ was positive for both models. For model (I), the value of was estimated to be 9.17 ‒ l0¹⁴ Pa s², for which N ₁ = −1.83 ‒ 10¹⁵ k² Pa. The discrepancy between Equation (15) and this estimate of N ₁ results from the corresponding difference between the value of α₁ given earlier in Table I and the value estimated from the pressuremeter tests. For a discussion on the possible implications of the latter difference, cf. the remark at the end of the next section.

Free-surface depression (or heave) in open-channel flow

McTigue and others made use of an approximation scheme (due to Reference Wineman and PipkinWineman and Pipkin (1966), and Reference TannerTanner(1970); cf. also Reference SchowalterSchowalter (1978, p. 255–57)) to calculate the free-surface depression or heave of a second-order fluid when it flows steadily down an inclined open semi-circularchannel. Using the values of material parameters which they estimated from their creep tests, they applied their surface-depression formula to the flow of glaciers.

The free-surface depression or heave studied by McTigue and others is due to a nonvanishing second normal-stress difference N ₂. Both models (I) and (II) can also exhibit the same phenomenon. Indeed, by following the same approximation procedure, it is straightforward to work out the corresponding formulae for these two models. In our derivation, the usual power-law fluid assumes a role parallel to that of the Newtonian fluid in the derivation of McTigue and others.

Let ρ be the density of ice, g be the acceleration due to gravity, h be the central (maximum) rise or fall, β be the channel slope, and R be the channel radius (see figure 3 of McTigue and others). The formulae in question are found for models (I) and (II), respectively, to be as follows:

When m = 0, both Equations (16) and (17) reduce to the formula for the second-order fluid, i.e. equation (26) of McTigue and others. For the usual power-law fluid, which is the special instance of our models with α₁ = α₂ = 0, both Equations (16) and (17) give h = 0.

Earlier we have argued that for model (I) | α₁ + α₂ | should be at least an order of magnitude smaller than α₁; for model (II) | α₁ + α₂ | should at most have the same order of magnitude as α₁. For a given R and β, we can easily obtain an order-of-magnitude estimate of | h | for models (I) and (II). Let us consider model (I). First, we set α₁ + α₂ =0. The righthand side of Equation (16) can then be evaluated. Let us denote the resulting value by h ₀. Since | α₁ + α₂ | is at least an order of magnitude smaller than α₁, | h ₀ | and | h | should have the same order of magnitude. Similarly, for a given R and β, we infer that for model (II) | h ₀ | can at most have the same order of magnitude as | h ₀ |.

Let us evaluate |h ₀| for some sample channel slopesand channel radii. We take ρ = 9 × 10² kg/m³, g = 9.8 m/s², m = ‒2/3, and give µ and α₁ the mean values given in Tables I and II. For β = 10° and R = 500 m, we obtain the following values for models (I) and (II), respectively: (I) | h ₀ | = 0.35 m; (II) | h ₀ | = 0.07 m. For the same β and R, McTigue and others estimated h = ‒42m. For β = 5° and R = 250 m, McTigue and others obtained h = ×2.6 m; for models (I) and (II) we get (I) | h ₀ | = 0.08 mm, and (II) | h ₀ | = 0.26 mm.

For a given R and β, let h* be the value of h estimated by McTigue and others. In general | h* | isrelated to | h ₀ | of models (I) and (II) by what follows:

here R is in units of meters. For the usual ranges of R and β of glaciers on Earth, the free-surface depression orheave according to both of our models is much smaller in magnitude than the prediction of McTigue and others. Indeed, according to either model (I) or (11) (with values of material parameters given in Tables I and II), the free-surface depression or heave induced by the second normal-stress difference will usually be negligible for glaciers.

For both models (I) and (II), the velocity field in the flow under consideration is, to the order of approximation adopted in the derivation of Equations (16) and (17), identical to that which pertains to Glen’s flow law. Forboth models, the stress distribution is different from that of the usual power-law fluid. With the values of material parameters adopted above, however, the difference in stress distribution is found to be negligible for the usual ranges of R and β for glaciers. Thus, we cannot accept the argument of McTigue and others as regards the possible significance of normal stress effects in the formation of crevasses.

Remark. The values of | h ₀ | are even smaller if we use values of m, µ, and α₁ estimated by Man and the Manitoba team from pressuremeter creep tests on polycrystalline ice at ‒2°C. The estimates were as follows (cf. Sun, unpublished): m = ‒0.711, μ = 2.97 × 10⁷Pa s^1+m; for model (I), α₁ = 9.17 × 10¹⁴Pa s²; for model (II), α₁ = 2.46 × 10¹⁰ Pa s^2+m. For β = 10° and R = 500 m, it follows that for model (I) | h ₀ | = 9.8 mm and for model (II) | h ₀ | = 2.3 mm. For β = 5° and R = 250 m, | h ₀ | = 0.7 × 10^‒3 mm for model (I), and |h₀| = 4.8 × 10^‒3 mm for model(II). These values of | h ₀ | are about 30 to 100 times smaller than those calculated above. Do these discrepancies in prediction indicate a basic flaw in the modeling, namely, that different tests would deliver different values of the coefficients m, μ, and α₁? Probably not. In fact, there are encouraging signs. Recall that for both models (I) and(II) m and μ should be related to the coefficients n and B in Glen’s law through Equation (9). Many researchers have performed uniaxial compression tests on ice specimens at various temperatures. A range of values of n and B (and thus also of m and μ) has been reported in the literature. The values of m and μ estimated from the pressuremeter tests are in good agreement with what other researchers have found from uniaxial compression tests (cf. Reference Kjartanson, Kjartanson, Shields, Domaschuk and ManKjartanson and others, in press). The values of μ given in Tables I and II also fall in the range of values reported in the literature (cf. Reference HookeHooke, 1981, fig. 2). Of course, since B and thence also μ vary appreciably with temperature, when we compare the values of μ, comparison is made only among those values that pertain to the same temperature. A problem remains with the coefficient α_1. The discrepancy is enormous between the values of a, reported earlier in this paragraph and those given in Tables I and II (i.e. α₁ = 1.20 × 10¹⁸ Pa s² for model (I); α₁ = 1.15 × 10¹³Pa s^4/3 formodel (II)). To clarify this point, more tests are necessary. Before results of new tests are available, allow us to dosome speculation. Of all factors that could possibly account for this discrepancy (for instance, the specimens of the pressuremeter tests would have structural features differentfrom those of the triaxial tests), temperature would be the most interesting. If temperature should be the main source of the discrepancy, then the significant difference in the estimated values of | h ₀ | could be attributed to the difference in temperature between the pressuremeter tests (‒2° C) and the triaxial tests (‒9.5 to ‒9.8° C). In other words, lowering of temperature might greatly enhance normal stress effects in the creep of ice.

Conclusion and Discussion

Reference McTigue, McTigue, Passman and JonesMcTigue and others (1985) identified a possible problem in the type of constitutive equation usually used for modeling the creep behavior of polycrystalline ice. They pointed out that Glen’s flow law necessarily excludes the consideration of normal stress effects, which are of great significance in other disciplines that consider non-Newtonian fluids. Using the second-order fluid (with material parameters evaluated from triaxial creep tests) as a tentative model for ice, they reached the conclusion that normal-stress effects may be discernible in natural glacier flow. The argument which led them to the preceding conclusion, however, can be challenged on the following grounds: (i) As noted by McTigue and others themselves, the second-order fluid “fails to represent the nonlinear rate dependence of icein shear”; therefore, it is in fact not a suitable constitutive model for glacier ice in shearing flow. The creep tests with which they quantified the material parameters in the second-order fluid were performed at the same deviatoric stress. Had they used data of creep tests which pertained to a range of deviatoric stresses, they would have had a hard time in finding a single set of parameters that could fit the data. (ii) The conclusion of McTigue and others naturally depends very much on the numerical values of material parameters which they put in the second-order fluid model. They obtained those numerical values by fitting data of their creep tests. Their data analysis, however, seemingly had inconsistencies (c f. footnote above). Moreover, they did not indicate how they handled the problem of over-parameterization in their data-fitting.

The preceding criticism is not meant to play down the contribution of McTigue and others. They have identified and asked an important question, which, as they fully realize, has no simple immediate answer. They concluded their paper by envisaging that their results should “serve as a point of departure for further investigation”, to which our present note bears witness.

In this note we have re-examined the issues discussedby McTigue and others in the light of two new tentative models, namely (I) the modified second order fluid and (II) the power-law fluid of grade 2, both of which can be taken as simple modifications of Glen’s flow law. For ease of comparison with the work of McTigue and others, we have used the same creep data in quantifying the material parameters in models (I) and (II). As indicated above, there is a problem of over parameterization in the data-fitting, and we have shown how we can circumvent that problem to obtain order-of-magnitude estimates for the normal stress effects discussed by McTigue and others. For both models (I) and (II), the normal stress effects are found to be far less pronounced than the estimates of McTigue and others. Indeed, should glacier ice have creep properties similar to the specimens of McTigue and others, models (I) and (II) indicate that, except for extremely thick ice and steep slopes, normal stress effects of the type discussed by McTigue and others would not play a significant role in glacier flow.

The preceding conclusion remains valid, should we use values of material parameters estimated by Man and the Manitoba team from data of pressuremeter creep tests on polycrystalline ice at ‒2° C (Reference Man, Man, Shields, Kjartanson, Sun and RasmussenMan and others, 1985; Reference KjartansonKjartanson, unpublished; Reference Kjartanson, Kjartanson, Shields, Domaschuk and ManSun, unpublished); cf. the remark at the end of the preceding section. The problem of over-parameterization did not appear in their pressuremeter work. Pressuremeter creep tests, however, can only deliver estimates for the parameters m, μ, and α₁. As indicated above, by appealing to Glen’s law, we do not need to know the value of α₂ to obtain an order-of-magnitude estimate of the normal stress effects discussed in this note. On the other hand, procurement of experimental data that suffice for the estimation of all the material parameters will not only tighten our argument; it will also provide a more stringent test for the models. For a given ice specimen, it should be possible to obtain the values of m, μ, α₁ and α₂ for models (I) and (II) by performing both pressuremeter and triaxial creep tests which record early time response in detail.

A correct assessment of the significance of normal stress effects in glacier flow can be made only after asufficiently accurate flow law is established and values of material parameters in the flow law are ascertained for various ice forms and temperatures. At present it is premature on both counts to give a sweeping conclusion. Models (I) and (II) are still tentative. A lot more theoretical and experimental work remains to be done before we canclarify their status. Even if one of them turns out to be a good model for ice in creep, our analysis above still does not necessarily imply that normal stress effects can beignored when we consider the creep behavior of polycrystalline ice. For instance, as pointed out in the preceding section, lowering of temperature might greatly enhance normal stress effects in the creep of ice.