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An oscillating electric dipole in free space emits its energy along straight lines. We have considered the effect of a nearby interface with a material medium. Interference between the directly emitted radiation and the reflected radiation leads to intricate flow line patterns. When the interface is a plane mirror, numerous interference vortices appear, and when the distance between the dipole and the mirror is not too small, these vortices lie on four strings. At the center of each vortex is a singularity, and these singularities are due to the fact that the magnetic field vanishes at these locations. When the interface is a boundary between dielectric media, reflection leads again to interference. The pattern for the transmitted radiation depends on whether the medium is thicker or thinner than the material in which the dipole is embedded. For thicker dielectrics, the field lines bend toward the normal, reminiscent of, but not the same as, the behavior of optical rays. For thinner media, oscillation of energy across the interface appears, and above a crossing point, there is a tiny vortex. We have also considered the case of a dipole in between two parallel mirrors.
Department of Physics, Millersville University, Millersville, PA, USA
Henk F. Arnoldus*
Department of Physics and Astronomy, Mississippi State University, Mississippi State, MS, USA
Zhangjin Xu
Department of Physics and Astronomy, Mississippi State University, Mississippi State, MS, USA
*Address all correspondence to: hfa1@msstate.edu
1. Introduction
The common conception about the propagation of light is that the radiation travels along straight lines. Such a picture certainly seems to hold for a laser beam and for sunlight. The success of ray diagrams for the construction of images by lenses and mirrors also supports this picture. Reflection by and transmission through an interface is another example of a process that can be described by a ray picture of light. However, light is electromagnetic radiation, and ultimately any optical phenomenon must be accounted for by a solution of Maxwell’s equations for the electric and magnetic fields. In the geometrical optics limit of light propagation [1], spatial variations on the scale of a wavelength or less are neglected, and optical rays are defined as the orthogonal trajectories of the wave fronts of a propagating wave. From a different point of view, we can define the direction of light propagation as the direction of the energy flow in the radiation field. This direction is determined by the electromagnetic Poynting vector [2]. It can be shown that in the geometrical optics limit for propagation in vacuum the field lines of the Poynting vector are straight lines and are identical to the optical rays, defined with the help of the propagation of wave fronts.
The concept of optical rays breaks down when spatial variations on the scale of a wavelength or less are of concern, or when coherence in the radiation leads to macroscopic constructive and destructive interference (as for a diffraction grating). We shall consider a small particle, like an atom, molecule, or nano-particle, irradiated by a monochromatic laser beam, oscillating with angular frequency ω. We shall assume that the beam is linearly polarized. The electric field of the laser beam induces an electric dipole moment in the particle, and this dipole moment oscillates with angular frequency ω along the same direction as the electric field of the immersing beam. The oscillating dipole moment emits electromagnetic radiation (expressions for the electric and magnetic fields are given below), and the Poynting vector is easily calculated. It appears that the field lines of the Poynting vector are straight lines, coming out of the dipole and running radially outward to infinity. This is illustrated in Figure 1.
The energy flow lines for a free (linear) dipole are straight at all distances. Any deviation from this radially outgoing pattern is due to the environment of the particle. For instance, when the particle is embedded in an absorbing medium, the imaginary part of the permittivity is responsible for a bending of the field lines in the near field toward the dipole axis [3]. Here we shall consider the case where the particle is located near an interface. Some of the emitted radiation by the dipole will be incident on the interface, and here reflection and transmission takes place. The reflected light will interfere with the incident light, and in the far field this leads to maxima and minima in the radiated power per unit solid angle. The structure of the angular power distribution of the transmitted light in the far field depends on the value of the critical angle and the distance between the particle and the surface. Usually, when a traveling plane wave is incident upon an interface, the transmitted wave is again traveling, and is bent toward the normal. When the angle of incidence approaches 90°, the transmitted wave is still traveling, and the angle of transmission is called the critical angle (for transmission). In the dipole spectrum, evanescent waves are present, and they are still transmitted as traveling waves, provided the wavelength is not too small. Therefore, above the critical transmission angle, all transmitted light comes from evanescent dipole waves, and this can lead to a large lobe in the power distribution above the critical angle [4]. Rather than considering the effects in the far field, we shall here present results for the power flow in the near field. We shall illustrate that interference gives rise to interesting flow patterns, including singularities, vortices, and strings of vortices. We also show that transmission in the near field exhibits interesting features.
where do is the amplitude of the oscillation, and u^ is a unit vector representing the direction of oscillation. Let r be the position vector of a field point, with respect to the location of the dipole, and let r be the length of r. Then, r^=r/r is the unit vector into the direction of the field point. The dimensionless distance between the dipole and the field point is defined as q=kor, with ko=ω/c the wave number of the light. On this scale, a distance of 2π corresponds to one wave length. The emitted electric field has the form
E(r,t)=Re[E(r)e−iωt],E2
with E(r) the complex amplitude, and a similar expression holds for the magnetic field B(r,t). We define the constant
ζ=ko3do4πεo.E3
The dimensionless complex amplitudes e(r) and b(r) of the fields are introduced as
The time-averaged Poynting vector for radiation in free space is given by
S(r)=12μoRe[E(r)×B(r)*].E8
For an electric dipole, we split off a factor:
S(r)=ζ22μocσ(r),E9
so that
σ(r)=Re[e(r)×b(r)*],E10
With the above expressions for e(r) and b(r), we find
σ(r)=1q2r^sin2α,E11
and here α is the angle between the dipole axis (e.g., the direction of vector u^) and the observation direction r^. Since the vector σ(r) is proportional to r^, the field lines of the vector field are straight, and run radially outward from the site of the dipole. This is shown in Figure 1. No power is emitted along the dipole axis (α=0), and the power per unit solid angle is maximum in the direction perpendicular to the dipole axis (α=π/2).
The simplest interface is a flat, infinite, and perfect mirror. We take the surface of the mirror as the xy-plane, and the dipole is located on the positive z-axis, at a distance H above the mirror. The dipole direction vector u^ makes an angle γ with the positive z-axis, and we take u^ in the yz-plane. Therefore,
u^=eysinγ+ezcosγ.E12
The electric field above the mirror is equal to the field of the dipole plus the electric field of an image dipole located at a distance H below the mirror on the z-axis, as illustrated in Figure 2, and the same holds for the magnetic field. The dipole moment direction of the image dipole is
u^im=−eysinγ+ezcosγ.E13
The complex amplitudes of the electric and magnetic fields of the dipole are given by Eqs. (6) and (7), but with r replaced by the position vector of the field point relative to the dipole location. We indicate this vector by r1. Let r be the position vector of the field point where we wish to evaluate the fields. We see from Figure 2 that
r1=r−Hez.E14
The coordinates of the field point only come in through r^ and q in Eqs. (6) and (7), so we replace r^ by r^1, and q by q1=kor1. Similarly, the fields of the image dipole are found by replacing r by
r2=r+Hez,E15
q by q2=kor2, and u^ by u^im. With the fields e(r) and b(r) constructed, the Poynting vector follows from Eq. (10). It is easy to verify that for z = 0, e.g., just above the mirror surface, the Poynting vector is along the surface.
With the above method, the Poynting vector σ(r) can be computed for a given field point r. We shall use dimensionless Cartesian coordinates x¯=kox, y¯=koy and z¯=koz, and the dimensionless distance h=koH. The Poynting vector is a function of x¯, y¯ and z¯. Therefore, it is better to write σ(q) instead of σ(r), with q=kor. We shall do so from now on. The only free parameters are h and γ. A field line of the vector field σ(q) is a curve such that for each point q on the curve the vector σ(q) is on the tangent line. Let q(t) be a parameter representation of a field line, with t an arbitrary dummy variable. Then q(t) must be a solution of
ddtq(t)=σ(q(t)).E16
In Cartesian coordinates this becomes:
ddtx¯(t)=σx(x¯(t),y¯(t),z¯(t)),E17
and similarly for y¯(t) and z¯(t), so this is a set of three differential equations. The independent variable t does not appear explicitly, and such equations are called autonomous. The solution is determined by an initial point (x¯o,y¯o,z¯o).. The field line through this point is found by solving Eq. (16). We set t = 0 at the initial point. The direction of the field line is the direction along the curve that follows from increasing t. So, the field line runs from the initial point into the direction that corresponds to the solution with t>0. The solution with t<0 is the part of the field line that runs toward the initial point.
Obviously, the differential Eq. (16) will in general need to be solved numerically. An interesting exception is the case for an arbitrary (elliptical) dipole in free space for which an analytical solution can be obtained, as reported in Ref. [6]. We use Mathematica to solve the set and produce the field line pictures. For two-dimensional problems, the routine StreamPlot only requires the expression for σ as a function of x¯, y¯ and z¯. The initial points (x¯o,y¯o,z¯o) are called StreamPoints and can be specified. Alternatively, one can let Mathematica select these initial points. This is much faster, and works well to get an initial picture. However, in this approach Mathematica cuts off field lines when they get too close together, and that does not necessarily look too good.
Finally, field lines are determined by the direction of vector σ at a point q, and not by its direction. Therefore, the vector fields σ(q) and f(q)σ(q), with f(q) an arbitrary positive function of q, have the same field lines. This can also be seen by making the change of variables t=f(q)t'. We then get
ddtq(t)=f(q(t))σ(q(t)),E18
and this equation has the same solutions for the field lines as Eq. (16). It just gives a different parametrization of the curves. A popular choice is f(q)=1/|σ(q)|, which makes the right-hand side of Eq. (18) a unit vector. For the mirror problem, the fields diverge in the neighborhood of the dipole, and a good choice seems to be f(q)=q15.
The dipole direction vector u^ and the direction of its image u^im are both in the yz-plane. If we take a field point in the yz-plane, then also r^ is in the yz-plane, and therefore, e(r) from Eq. (6) is in the yz-plane, and the same holds for the complex amplitude of the image electric field. From Eq. (7), we see that the complex amplitudes of the magnetic dipole field and the magnetic image field are along the x-axis if the field point is in the yz-plane. Therefore, the Poynting vector from Eq. (10) is in the yz-plane if the field point is in the yz-plane. Consequently, any field line through a point in the yz-plane stays in the yz-plane. This plane is the symmetry plane for the dipole near the mirror. For field lines off the symmetry plane the field lines will be 3D curves, and the flow pattern is reflection symmetric in the yz-plane. Field lines in 3D are difficult to visualize, so we shall only consider field lines in the symmetry plane.
Figure 3 shows the flow lines of energy for a dipole oscillating along the z-axis (γ=0). The field line pattern is rotation symmetric around the z-axis. The field lines that run toward the surface smoothly bend away from the surface upon approach. At the origin of coordinates we have a singularity, since the field lines that come out of the dipole and run straight down split there. This point is marked with a white circle. Figure 4 shows the flow pattern for a dipole oscillating parallel to the surface (γ=π/2). The pattern is reflection symmetric in the z-axis, so only the region y¯<0 is shown. Just left of the dipole are two singularities. It seems that a field line ends at the lower singularity, but this is essentially a minuscule vortex. The higher of the two is a singularity where field lines ”collide.” There is again a singularity right below the dipole on the mirror surface, and two other singularities appear at greater distances.
Figure 5 shows the field lines for a dipole oscillating under 45° with the z-axis (γ=π/4). Numerous singularities and vortices appear for this case. Vortex c is close to the dipole, and is similar to the small vortex in Figure 4. Vortices a and b have a greater extent, although they are still of subwavelength dimension. Some field lines come out of the dipole and swirl around vortex a, and some pass by vortex b. Interestingly, there are field lines that emanate from vortex a and end up at the center of vortex b. This seems to represent energy flowing from vortex a to vortex b, but that is not the case. Only the dipole is a source for the vector field of the Poynting vector. The singularity at the point labeled S seems like a bump in the road for the field lines that pass nearby. It can be shown analytically [7] that this singularity is a point on a singular circle in the plane of the mirror. The circle goes through the origin of coordinates and singularity S, and singularity S is located at y¯=−htanγ. For γ=π/4 this is at y¯=−h, and for the case of Figure 5 this is at y¯=−h=−2π. To the right of the z-axis, not shown in Figure 5, there seems to be no interesting structure.
When the dimensionless distance h between the dipole and the surface increases, so does the number of vortices. In Figures 3–5, this distance was taken as h=2π, corresponding to one wavelength. In Figure 6, this distance is h=8π, and angle γ is the same as in Figure 5. We notice numerous vortices in the flow line pattern. The field lines rotate counterclockwise around the singularities that are close to the z-axis. Figure 7 shows an enlargement of one of these vortices, and it follows from the pattern that there must be another singularity nearby. The vortices on the left have a clockwise rotation and Figure 8 shows an enlargement. For the vortices on the left the field lines come out of the center of the vortex, and for the vortices on the right the field lines end at the center of the vortex, as in Figures 7 and 8, respectively. In Figure 6, the field lines that start or end at a vortex are drawn in bold. Many other field lines are present. They run from the dipole to infinity, either without coming in the neighborhood of the vortices (the four field lines on top of the picture) or they cross the array of vortices once or twice.
At a singularity, the Poynting vector vanishes. This can be due to E(r)=0 or B(r)=0 or E(r)×B(r)* is imaginary. We have found that for singularities that appear when field lines split or collide, E(r)×B(r)* is imaginary. Singularities at the center of a vortex are due to the vanishing of the magnetic field. For field lines in the xy-plane, the complex amplitude of the magnetic field is along the x-axis. For B(r)x to be zero, both the real and imaginary part have to be zero at the same point. With the expressions for the magnetic field of source and image, we find that Re[B(r)x]=0 leads to
The solutions of Eq. (19) are curves in the yz-plane, and Eq. (20) also represents a set of curves in the yz-plane. At intersections between these sets of curves the magnetic field is zero, and this corresponds to the center of a vortex. Figure 9 shows the curves for the same parameters as shown in Figure 5. The solid lines are the solutions of Eq. (19) and the dashed lines are the solutions of Eq. (20). The three intersections a, b, and c are the centers of the three vortices in Figure 5. Interestingly, at the center of the bump on the mirror, labeled S, the magnetic field also vanishes. This point is located at
y¯=−htanγ,z¯=0,E21
and it is easy to check that this is indeed a solution of both Eqs. (19) and (20). Here, the magnetic field is zero, but there is no vortex. For the case of the parameters for Figure 6, the solutions of Eqs. (19) and (20) are shown in Figure 10.
In Figure 10, the intersections between the solid and dashed curves are not always precisely to determine and this gets worse with increasing h. By manipulating Eqs. (19) and (20), a different set of equations can be obtained. We find [8]
The solid curve in Figure 11 is the solution of Eq. (22) and the dashed curves are the solutions of Eq. (23). Vortices appear at the intersections. The parameters are the same as for Figure 10. Interestingly, Eq. (23) is independent of the orientation angle γ of the dipole. When γ varies, the solid curve rotates with it, but the dashed curves stay the same. The solid curve starts at the location of the dipole and runs to point S on the mirror, as can easily be checked from Eq. (21).
The vortices in Figure 11 appear to lie on two ‘strings’. The left string starts at the dipole and runs to point S on the mirror. The second string is in between the left string and the z-axis. It can be seen from Figure 6 that all the vortices on the left string have a counterclockwise rotation, as in Figure 7. On the right string the vortices have a clockwise rotation, as in Figure 8. Figure 12 shows a larger view of the same graph as in Figure 11. The solid line passes the dipole and continues in the upper right part of the graph. It appears that far away there are also intersections between the solid curve and the dashed curves, and these correspond also to the location of vortices. The vortices appear to lie on a third string. It can be shown that these vortices have a counterclockwise rotation.
The left string ends at point S on the mirror. The location of this point depends on the dipole angle γ, according to Eq. (21). When γ increases, the point moves to the left, and for γ→π/2 the point moves to infinity. Figure 13 shows the string pattern for γ=π/2 and h=30π. The field line pattern must be reflection symmetric in the z-axis, and so is the string pattern. We see that a fourth string of vortices appears, and from symmetry it follows that these have a clockwise rotation. When we look again at Figure 12, the solid curve must intersect the dashed curves outside the picture in the upper right corner. Therefore, there is a fourth string very far away, and outside the picture. Apparently, there are always four vortex strings in electric dipole radiation near a mirror.
An interesting generalization of the free dipole near the mirror is the case of a dipole embedded in a dielectric medium, and near an interface with another dielectric material. For this problem, we reverse the z-axis, as compared to Figure 2, and we place the dipole on the negative z-axis, at a distance H below the interface. This is illustrated in Figure 14. The dielectric constant of the embedding medium is ε1 and the substrate has dielectric constant ε2. The corresponding indices of refraction are n1=ε1 and n2=ε2, respectively. The analysis of this system is considerably more complicated than the mirror problem. For simplicity of notation, we shall assume that the dipole oscillates along the z-axis, e.g., u^=ez. The approach here is to represent the source fields (6) and (7) by an angular spectrum of plane waves. The reflection and transmission of each partial wave is accounted for by the appropriate Fresnel coefficients. A partial wave can be traveling or evanescent, and in Figure 14 this is schematically indicated by vectors and dashed parallel lines, respectively. In each triad of partial source, reflected and transmitted waves the parallel component of each of the three wave vectors is the same. Upon reflection and transmission only the z-component of a wave vector can change. Set α=k||/ko, which is the dimensionless magnitude of the parallel component of each wave vector. The dimensionless z-components of the wave vectors can be expressed in terms of the functions
vi=ni2−α2,i=1,2.E24
The wave vector of an incident partial wave of the source field has a z-component of kov1. Similarly, the reflected and transmitted waves have wave vectors with z-components −kov1 and kov2, respectively. For α<ni, vi is real, and the corresponding wave is traveling. For α>ni, vi is positive imaginary, and the corresponding wave is evanescent. The Fresnel reflection and transmission coefficients for an incident p-polarized plane wave with parameter α are
Rp(α)=ε2v1−ε1v2ε2v1+ε1v2,E25
Tp(α)=n2n12ε1v1ε2v1+ε1v2.E26
For the dipole oscillating along the z-axis, all partial waves are p polarized.
The setup is rotation symmetric around the z-axis, so we only need to consider the solution in the yz-plane, with y>0. Then the electric field is in the yz-plane, the magnetic field is along the x-axis, and the Poynting vector is in the yz-plane. We obtain for the complex amplitudes of the dimensionless electric and magnetic reflected fields [9]
Here, J0 and J1 are Bessel functions. These four fields are integral representations of the solutions, and, obviously, these integrals need to be computed numerically. On the z-axis we have y¯=0, and since J1(0)=0 we see that the magnetic fields vanish on the z-axis. The magnetic source field, Eq. (7), also vanishes on the z-axis. Therefore, the Poynting vector is zero on the z-axis, and so the z-axis is a singular line of the flow lines pattern.
For the case of Figure 15, we have n1=1 and n2=2. The energy flows from a thinner to a thicker medium. Upon transmission, the field lines of the Poynting vector bend toward the normal, just like optical rays would do for this case. However, the angle of incidence and the angle of transmission for the Poynting vector are not related by Snell’s law, as the corresponding angles for optical rays are. The critical angle for this interface is 30∘, and we see that away from the z-axis the field lines leave the interface under approximately 30∘. This critical angle corresponds to an angle of incidence of 90∘, and we see from the figure that the field lines do not approach the interface under 90∘. The reason that the field lines leave the interface under approximately the critical angle is that the Fresnel transmission coefficient has a sharp maximum at this angle. The angular spectrum is a superposition of waves with all angles of incidence, and extends into the evanescent region as well. The transmission coefficient favors partial waves that approach the interface under about 90∘. These are the partial waves that are on the borderline of the traveling and the evanescent regions of the angular spectrum.
More interesting is the case for transmission into a thinner medium, as illustrated in Figure 16. The indices of refraction are n1=2 and n2=1. On crossing the interface, the field lines bend away from the normal, just like optical rays. We see here that the field lines are more curved than in Figure 15. Some of the field lines that entered the n2 medium bend down, and then cross the interface again. The field lines run through the n1 material for a short distance and then bend up and cross the interface again into the n2 region. This oscillation of energy back and forth through the interface persists over long distances. Figure 17 shows an enlargement of the first dip of the field lines below the interface. We see that a vortex appears in medium n2, just above the dip of the field lines under the interface. And just above the vortex, we necessarily have a singularity because near this point the field lines run in opposite directions.
An interesting variation of the mirror problem is the case for a dipole in between parallel mirrors, as depicted in Figure 18. A second mirror is placed at a distance D above the first mirror. Now, the dipole has a mirror image in both mirrors. In order to satisfy the boundary conditions at both mirrors, a mirror image must have again an image in the other mirror, and so on. This leads to an infinite sequence of images. Let us label the images with m. We then find that the images are located at
zm=(m+12)D+(−1)m(H−12D),E31
with m integer. For m = 0, this is the actual dipole in Figure 18. The image with m = −1 is the image dipole from Figure 2. Images with m even have a dipole orientation vector u^ and images with m odd have u^im as orientation vector.
This can be combined as
u^m=(−1)meysinγ+ezcosγ,E32
for the orientation of image m. The dimensionless distance between the mirrors is denoted by δ=koD.
Figure 19 shows the energy flow pattern for a horizontal dipole midway between the mirrors. The distance between the mirrors is δ=4π. Most of the radiation is emitted in the vertical direction. It travels to the mirrors, and there the field lines bend and continue horizontally. No radiation is emitted along the dipole axis, and we see that the line z¯=2π is a singular line. Field lines approach this line from above and below, and then stop at this line. Consequently, the Poynting vector has to be zero on this line. For Figure 20, we have γ=π/4 and δ=π, and the dipole is midway between the mirrors. We notice the appearance of two vortices very close to the dipole (subwavelength distance), and the rotation is counterclockwise for both. Some of the field lines run downward to the right swing up turn around (outside the figure) and end up running to the left. Similarly, some field lines start toward top-left, and then turn around, swing by the dipole, and then run off to the right. In Figure 21, we have again a horizontal dipole, but it is now closer to the mirror on the bottom. Numerous vortices appear in the flow pattern.
An oscillating electric dipole in free space emits its energy along straight lines. Most radiation is emitted perpendicular to the dipole axis, and none comes out along the dipole axis. We have studied the effect of a nearby interface on this flow pattern. Reflection of radiation at the interface leads to interference between the directly emitted radiation and the reflected radiation. A mirror is impenetrable for radiation, and so all radiation bounces back at the interface. This also implies that the field lines of energy flow must be parallel to the mirror at the mirror surface. This effect is shown in Figure 3 for a dipole oscillating perpendicular to the surface, and one wavelength away from the surface. The radiation comes out of the dipole, more or less as for emission in free space, but at the mirror surface the field lines bend, and the energy flows away along the mirror surface. For a dipole oscillating parallel to the surface, a typical flow pattern is shown in Figure 4. Again, at the mirror surface the field lines run away parallel to the surface, but in between the surface and the dipole several singularities appear, and there is also a vortex very close to the dipole. For the case shown in Figure 5, the dipole oscillates under 45° with the normal to the surface, and we see that two large vortices appear and one very small one. The rotation direction of the energy flow in the two large vortices is in opposite directions, and some energy flows from one vortex to the other. When the distance between the dipole and the surface is much larger than a wavelength, numerous tiny (subwavelength) vortices appear, and we found that the vortices are located on a set of four strings. This is shown most clearly in Figure 13.
When the surface is an interface between two dielectrics, we also need to consider the radiation transmitted into the substrate. Here, we only consider the simplest case of a dipole oscillating perpendicular to the interface. This can be generalized to arbitrary oscillation directions, and also to the case where the surface is an interface with a layer of material, and this layer is located on a substrate of yet another kind of material [10]. Figure 15 illustrates a typical case of transmission into a thicker medium. The field lines bend toward the normal, just like optical rays would. However, the refraction angle for the flow lines does not follow Snell’s law for optical rays. Figure 16 shows field lines for transmission into a thinner medium. Now the field lines bend away from the normal, but some field lines bend so much that they return to the other side of the interface. There is oscillation of energy back and forth through the interface. An enlargement is shown in Figure 17, and we observe that a vortex appears just above the location where the energy goes back and forth through the interface.
We have also considered the case where the oscillating dipole is located in between two mirrors. For a horizontal dipole, the emitted radiation bends near the surfaces of the two mirrors, and then flows away horizontally, as shown in Figure 19. For the case in Figure 20, the dipole oscillates under 45° with the normal. Two vortices appear. Some of the radiation that is emitted to the bottom-right of the picture originally flows to the right along the surface of the lower mirror, but then turns around, swings by the dipole, and then continues to the left, along the surface of the top mirror. When the dipole is not located midway between the mirrors, as in Figure 21, numerous vortices appear, and the pattern repeats indefinitely to the left and right in the range outside the picture.
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Written By
Xin Li, Henk F. Arnoldus and Zhangjin Xu
Submitted: 26 March 2016Reviewed: 21 October 2016Published: 01 March 2017