1. Introduction
Metallic glasses working as magnetoelastic resonators show excellent magnetomechanical behavior due to their good values of spontaneous magnetization and saturation magnetostriction, and low magnetocrystalline anisotropy [
1,
2,
3,
4]. These properties arise during their fabrication process by ultra-fast cooling after the melt, a procedure that makes the single-roller quenching method the most used one and yields a metallic glass product fabricated in the form of long ribbons.
When working as sensing magnetic materials, the magnetoelastic resonance frequency of a metallic glass element is extremely sensitive to any mass added to the resonator [
5,
6]. This configuration allows remote query and answer [
7], as well as low manufacturing cost and low power consumption [
8] for the interrogation. For this reason, they have been used to detect a wide range of environmental, physical, chemical and biological parameters (see, for example, references in [
9,
10]). Nevertheless, little work has been done using such materials as actuators. The possibility to control metallic glass strip elongation by using an externally applied or bias magnetic field opens new application possibilities as a simple two-state open/close gas valve [
11] or an extremely precise light flux shutter controller (see
Figure 1).
There is a clear influence of the geometric shape of amorphous ferromagnetic materials in the observed magnetic and magnetoelastic behavior. In particular, for rectangular ribbon-shaped strips of metallic glasses, several authors [
12,
13,
14] have already demonstrated that a value of
R > 5,
R being the length-to-width ratio, is needed for a good magnetic and magnetoelastic response of the material. In many practical applications this condition is rarely applied.
In order to gain a better understanding of the dependence of magnetoelastic properties on resonator geometry, we performed an exhaustive study of the main parameters involved in the resonance: change E(H) of the apparent Young modulus with the applied field, ΔE effect, maximum magnetoelastic coupling coefficient kmax, and corresponding quality factor of the resonance, Q. For this study, strips of different length-to-width ratio R = L/w (ranging from 2 to 20.6) were cut from a single long ribbon of Metglas® 2826MB3 to ensure they shared the same basic properties. The results indicate large differences in the measured main magnetoelastic parameters, differences that will be qualitatively analyzed as a function of the length-to-width ratio R value of each strip.
2. Materials and Methods
Metglas
® 2826MB3 (Fe
37Ni
42Mo
4B
17, see [
15]), was chosen for the experiments. It is a commercial material often used in magnetoelastic sensor applications due to its good magnetic and magnetoelastic properties, and resistance to corrosion [
16,
17]. Room-temperature hysteresis loops of the material were measured by a classical induction method, obtaining a saturation magnetization
μ0MS = 0.88 T and initial susceptibility
= 15,000. Saturation magnetostriction was determined by using strain gages connected to an electronically balanced bridge, obtaining a value of
λS = 12 ppm.
Starting from a long ribbon of Metglas® 2826MB3 of 30 µm thickness in as-cast state, strips were laser cut with perfect rectangular shape of length varying from L = 35 mm to L = 10 mm in steps of 5 mm, and in four different widths: w = 5.0 mm, 3.33 mm, 2.5 mm and 1.66 mm. That is, the initial value of w = 5 mm of the long ribbon was reduced in a factor of 2/3, 1/2 and 1/3, respectively. Following this procedure, we obtained a set of 24 different rectangular strips and subsequently a set of magnetoelastic resonators with different length-to-width ratios R = L/w, ranging from 2 to 20.6.
We used a home-mounted magnetoelastic resonance detection apparatus to measure the magnetoelastic resonant (
fr) and anti-resonant (
fa) frequencies, at an external applied magnetic field (or bias)
H. Precise determination of frequencies was performed using a Hewlett Packard 3589A Spectrum Analyzer, working in the 50–250 kHz range. A detailed description of the set-up can be found in [
9,
18]. Due to magnetoelasticity, the measured resonant frequency (
fr) will vary with the bias field
H, and so too will the Young’s modulus, determined as
[
19], where
L and
ρ are the length and density of the sample. This field-dependence of the elastic modulus is known as
ΔE effect and is usually given in % variations:
,
ES being the Young’s modulus measured at magnetic saturation. Other important magnetoelastic parameters that can be determined from these measurements are the magnetomechanical coupling coefficient (
) [
20] and quality factor of the resonance
, all quantities being function of the applied external magnetic field.
Finally, for some applications (such as electronic article surveillance [
21]) high-anisotropy fields combined with a wide
ΔE effect curve are necessary. Consequently we have also followed the behavior of the effective anisotropy field
[
14] or bias field necessary to reach the minimum of the
E(H) value (corresponding to the maximum value of the
ΔE effect) and the width
ΔH of this
E(H) curve at half of its maximum depth.
3. Results
The drastic influence of the geometric shape (as indicated by the
R factor) on the magnetoelastic behavior of the studied strips is clearly observed in
Figure 2, where
E(H) and
k(H) bias field dependence, Young’s modulus and magnetoelastic coupling coefficient respectively, are shown for the highest (best) and lowest (worst)
R values.
The magnetoelastic behavior of the strip with the lowest R (corresponding to L = 10 mm, w = 5 mm) value is worse than that measured for the strip with the highest R (corresponding to L = 35 mm, w = 1.66 mm). The saturation Young’s modulus value ES and ΔE effect magnitude decrease from 164.5 GPa and 9.6% to 159.9 GPa and 4%. Similarly, maximum magnetoelastic coupling reduces from 0.3 to 0.14. All these changes are accompanied by an evident increase in the bias external field necessary to reach those minima in the E(H) and maxima in the k(H) behaviors, from 400 to 1435 A/m.
Considering all the lengths and widths of the strips used in this study,
Figure 3 shows the continuous change observed in the measured
E(H) curves when keeping the length
L of the strips constant (
L = 35 mm,
Figure 3a) and when keeping the width
w of the strips constant (
w = 5 mm,
Figure 3b). Curves for different lengths
L and different widths
w of the strips behave in a similar way, that is to change the R ratio by changing
L or
w, influencing the
ΔE effect magnitude, the applied bias external field necessary to reach the minima, and also the width of the
E(H) curve.
All the magnetoelastic parameters estimated from the measured
E(H) and resonance/anti-resonance frequency measurements performed for all the studied Metglas
® 2826MB3 strips with different lengths
L and different widths
w are summarized in
Table 1.
In the following we will plot and analyze the behavior of these quantities: ΔE effect, effective anisotropy field , maximum magnetoelastic coupling kmax, the quality factor of the corresponding resonance, Q(kmax), and the width ΔH of the measured E(H) curves, as a function of the length-to-width ratio R.
Figure 4 and
Figure 5 show that all these parameters have a strong dependence on the value of
R. The condition
R ≥ 5 is insufficient to guarantee a good magnetoelastic behavior: the
ΔE effect reaches its maximum value (about 10%) at
R > 15, being almost 67% higher than the measured one at
R = 5 (about 6–7%). In an analogous way, the maximum magnetoelastic coupling
kmax reaches its maximum value (about 0.3) at
R > 12, while at
R = 5, it remains at about 0.2–0.25. Corresponding
Q(
kmax) at those same
R values are the lowest measured, with a value about 20, while strips with value of
R = 5 had resonance quality factors ranging from about 30 to 35.
The parameters that are less influenced by the change in the length-to-width ratio
R are the effective anisotropy field
(see
Figure 4b) and the width
ΔH of the measured
E(H) curves (see
Figure 6). This effective anisotropy field
is, in our case, intrinsic to the material and arises from its fabrication process, so any observed change must arise from the different shapes (
R values) studied.
In both cases the observed behavior is analogous, that is, the field and the width ΔH decrease as the R value increases. Nevertheless—and despite the previously described behavior of the magnetoelastic parameters—it is enough to use strips with R 7–8 in order to obtain the lowest effective anisotropy field (about 400–560 A/m) and width ΔH (about 440–560 A/m).
4. Discussion
It is already well-established that the dimensions of ribbon-shaped magnetoelastic materials affect their magnetomechanical response—that is, the resulting shape anisotropy for resonant platforms of different aspect ratios reflects different demagnetizing factors that can severely reduce the observed magnetomechanical coupling and related properties. The demagnetizing factor
N relates the
H bias field applied to our magnetoelastic specimen, its magnetization
M and the internal effective field
Heff through the expression:
The quantity “
” is known as the internal demagnetizing field. Strictly speaking, unless the specimen has a revolution ellipsoidal shape, this demagnetizing field will be non-uniform along the strip length. This observation in the case of soft amorphous magnetic microwires (of cylindrical symmetry) has been extensively reported by Usov [
22] and Zhukova et al. [
23]. In the following example, intended to give an adequate interpretation of our experimental results, let us assume the demagnetizing factor
N to be constant through the section of our ribbons. The corresponding value (for each
R value case) will be taken from the extensive previous works performed by Chen [
24,
25] in which a deep reasoning about the variation of the demagnetizing factor
N of rectangular prisms together with its calculation is reported.
From Equation (1) it is inferred that the higher the demagnetizing effect, the lower the measured susceptibility
[
26] given as:
where
is the true or intrinsic susceptibility of the material. Similarly, this will happen with the magnetoelastic properties of the ribbon [
27] like the
ΔE effect, that will reduce in the form:
The quantity 1/(
) has been already defined as a “reduction factor,
RF” that affects any property concerning magnetostrictive/magnetoelastic constituents, e.g., the magnetoelectric effect observed in laminated PVDF/Metglas composites [
14].
So, the measured magnitude of the (magnetoelastic) properties of these type of materials will be close to the true value (e.g.,
) when the demagnetizing factor
N → 0, that is, when the ribbon-shaped magnetoelastic specimen has a large length-to-width aspect ratio
R. Following the works by Schmidt et al. [
12,
13], a length-to-width aspect ratio of 5:1 was considered enough to guarantee accurate magnetoelastic resonance measurements. They justified their argument in Figure 9 of their work [
12], in which, for
R > 5 values, a constant velocity of sound (about 4400 m/s) in Metglas
® 2826MB3 was found, so a uniform applied bias
H field along the longitudinal axis of the ribbon was assumed.
As we will show in the following,
R and
N do not have direct proportionality, and even in the case of
R > 5, where a constant sound velocity through the strips is achieved [
12,
13], other magnetoelastic parameters can still vary. This can be clearly seen in
Table 2, where strips with values of
R equal or close to 6, but with different lengths, have been extracted from
Table 1 and compared.
It can be observed that the random and small changes in Emin, Es and ΔE effect (about 1% for all of them) is accompanied by a monotonous decrease of and ΔH, and also an increase in the magnetoelastic coupling, kmax, mainly due to the different L and w values.
In fact, and following previous works performed by Chen et al. [
24,
25], which report variation in the demagnetizing factor
N with
and the aspect ratio of the sample, we can check by extrapolation the fluxmetric demagnetizing factor
Nf of a general rectangular prism of dimensions 2
a × 2
b × 2
c along
x,
y,
z axis respectively, so that
L = 2
c,
w = 2
a and 2
b = 30 μm, the thickness of the ribbon of Metglas
® 2826MB3. Obtained values of
Nf appear in
Table 3.
These
Nf values have been obtained assuming
= 0, but the error generated by Chen et al’s. [
25] calculations when assuming
is within 1%. From
Table 3 it is clear that despite the almost constant value of
R = 6, the fluxmetric demagnetizing factor changes by almost one order of magnitude, from
(for the longest strip) to
(for the shortest one). Hence, despite the strong influence of the length-to-width ratio
R on the magnetoelastic properties of Metglas
® 2826MB3 strips, the most important parameter is actually the demagnetizing factor of each strip,
N.
So, from our measurements, we must infer that in order to have magnetoelastic resonant platforms showing almost their intrinsic or true ΔE effect, we need ribbons with values in the 15 < R < 20 range. For such high R values the measured ΔE 10%, but when R = 5 it reduces to only 6%. The other most-affected parameter is the magnetoelastic coupling coefficient, that reaches 0.3 for 12 < R < 20, and reduces to 0.2–0.25 for R = 5. The length-to-width aspect ratio has much less influence seems on the width of the measured ΔE curve, which remains almost constant (480–560 A/m) for values ranging from 7 < R < 20, and increases to 640–800 A/m for R 5. That is, the R > 5 criterion must be regarded as a lower limit for this parameter in order to obtain good magnetomechanical response in this type of material. It is the demagnetizing factor of each strip, N, that actually determines the magnetoelastic response of the strip material. Having rectangular-shaped magnetoelastic strips with sufficiently high R values only guarantees almost-constant values of Young’s moduli (Emin, Es) and ΔE effect, while the best magnetoelastic parameters are only guaranteed for the strips with the lowest demagnetizing factors.
Following the line of reasoning of our work, future research points toward the determination of true magnetoelastic parameters for magnetoelastic strips with high-enough length-to-width aspect ratio R values, along with an adequate estimation of the demagnetizing factor N of long rectangular prisms, enabling prediction of the reduction in the magnetoelastic properties of low R strips—information of interest when investigating magnetic core materials for remote sensing applications.
5. Conclusions
The influence of different length and width (2 < R = L/w < 20) commercial Metglas® 2826MB3 magnetoelastic strips in the magnetoelastic properties they exhibit has been extensively analyzed. A significant variation in Young’s modulus and the ΔE effect with changing geometry has been observed. Saturation Young’s modulus value ES and ΔE effect magnitude change from 159.9 GPa and ΔE = 4% (worst magnetoelastic case, L = 10 mm, w = 5 mm and R = 2), to 164.5 GPa and 9.6% (best magnetoelastic case, L = 35 mm, w = 1.7 mm and R = 20.6). In order to obtain the highest values of the ΔE effect, k and Q magnetoelastic parameters, we have observed that a value of R > 14 is needed. However, the effective anisotropy field from the minimum of the E(H) curve and its width ΔH, seems not to be so strongly influenced by the length-to-width ratio parameter, and a value R > 7 is enough to reach their lowest value. This is due to the strong influence—even higher than the influence of the R parameter—of the demagnetizing factor, N. Thus, a rectangular strip with moderate length-to-width ratio, but with a low demagnetizing factor value, can show an acceptable magnetoelastic response.
From our measurements we infer that the reported value of
R > 5 needed for a good magnetic and magnetoelastic material response predicted in previous studies [
8,
9] must be regarded as a lower limit for magnetoelastic resonators. The best magnetoelastic performance is achieved only if the strip
R ratio is high enough and its demagnetizing factor low. So, when using such amorphous alloys in extremely precise length-controlled magnetic field-controlled actuators, our findings on the variation of magnetoelastic properties with the geometry (size) of the actuator material must be taken into account.