Crystal and magnetic structures of R2Ni1.78In compounds (R = Tb, Ho, Er and Tm)

Baran, S.; Deptuch, A.; Hoser, A.; Penc, B.; Tyvanchuk, Y.; Szytuła, A.

doi:10.1107/S2052520621008179

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ISSN: 2052-5206

Volume 77| Part 5| October 2021| Pages 824-832

https://doi.org/10.1107/S2052520621008179

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Crystal and magnetic structures of R₂Ni_1.78In compounds (R = Tb, Ho, Er and Tm)

Stanisław Baran,^a ^* Aleksandra Deptuch,^b Andreas Hoser,^c Bogusław Penc,^a Yuriy Tyvanchuk ^d and Andrzej Szytuła ^a

^aM. Smoluchowski Institute of Physics, Jagiellonian University, Prof. Stanisława Łojasiewicza 11, PL-30-348 Kraków, Poland, ^bInstitute of Nuclear Physics, Polish Academy of Sciences, Radzikowskiego 152, PL-31-342 Kraków, Poland, ^cHelmholtz-Zentrum Berlin für Materialien und Energie GmbH, Hahn-Meitner Platz 1, D-14109 Berlin, Germany, and ^dAnalytical Chemistry Department, Ivan Franko National University of Lviv, Kyryla i Mefodiya 6, 79005 Lviv, Ukraine
^*Correspondence e-mail: stanislaw.baran@uj.edu.pl

Edited by J. Lipkowski, Polish Academy of Sciences, Poland (Received 31 March 2021; accepted 9 August 2021; online 18 September 2021)

The crystal and magnetic structures in R₂Ni_1.78In (R = Ho, Er and Tm) have been studied by neutron diffraction. The compounds crystallize in a tetragonal crystal structure of the Mo₂FeB₂ type (space group P4/mbm). At low temperatures, the magnetic moments, localized solely on the rare earth atoms, form antiferromagnetic structures described by the propagation vector k = [k_x, k_x, ½], with k_x equal to ¼ for R = Er and Tm or 0.3074 (4) for R = Ho. The magnetic moments are parallel to the c axis for R = Ho or lie within the (001) plane for R = Er and Tm. The obtained magnetic structures are discussed on the basis of symmetry analysis. The rare earth magnetic moments, determined from neutron diffraction data collected at 1.6 K, are 6.5 (1) μ_B (Er) and 6.09 (4) μ_B (Tm), while in the incommensurate modulated magnetic structure in Ho₂Ni_1.78In the amplitude of modulation of the Ho magnetic moment is 7.93 (8) μ_B. All these values are smaller than those expected for the respective free R³⁺ ions. A symmetry analysis of the magnetic structure in Tb₂Ni_1.78In is also included, as such information is missing from the original paper [Szytuła, Baran, Hoser, Kalychak, Penc & Tyvanchuk (2013 ). Acta Phys. Pol. A, 124, 994–997]. In addition, the results of magnetometric measurements are reported for Tm₂Ni_1.78In. The compound shows antiferromagnetic ordering below the Néel temperature of 4.5 K. Its magnetic properties are found to originate from magnetic moments localized solely on the thulium atoms (the nickel atoms remain non-magnetic in Tm₂Ni_1.78In). The reduction of rare earth magnetic moments in the ordered state in R₂Ni_1.78In (R = Tb, Ho, Er and Tm) and the change in direction of the moments indicate the influence of the crystalline electric field (CEF) on the stability of the magnetic order in the investigated compounds.

Keywords: magnetic structure; antiferromagnetism; neutron diffraction; magnetometric measurements; symmetry analysis.

1. Introduction

Intermetallic compounds of the R–Ni–In systems are the subject of intensive studies with respect to their crystal structures, chemical bonds and magnetic properties (Kalychak et al., 2004 ). Within these systems, the compounds with a stoichiometry close to 2:2:1 have been observed to crystallize in two different crystal structures:

(i) A tetragonal one of the Mo₂FeB₂ type (space group P4/mbm) found for both the R₂Ni₂In (R = La–Nd) stoichiometric composition and the R₂Ni_2−xIn (x = 0.22, R = Y, Sm, Gd–Tm, Lu) nonstoichiometric composition (Kalychak et al., 1990 ).

(ii) An orthorhombic one of the Mn₂AlB₂ type (space group Cmmm) found exclusively for the R₂Ni₂In (R = Y, Sm, Gd–Tm, Lu) stoichiometric composition (Kalychak et al., 1990; Zaremba et al., 1988 ).

The R₂Ni_2−xIn (R = Gd–Er) nonstoichiometric compounds order antiferromagnetically below the Néel temperatures (T_N) of 26.4 K (Gd), 20.2 K (Tb), 8.3 K (Dy), 7.1 K (Ho) and 6.3 K (Er) (Tyvanchuk et al., 2012 ).

Studies of the physical properties of R₂Ni₂In reveal that Ce₂Ni₂In is a non-magnetic intermediate-valence system (Hauser et al., 1997 ; Kaczorowski et al., 1996 ), while Nd₂Ni₂In orders antiferromagnetically below 8 K (Maskova et al., 2014 ). Magnetic and thermodynamic studies of R₂Ni₂In (R = Gd–Tm) report an antiferromagnetic order with Néel temperatures between 5 K (Tm) and 40 K (Tb) (Szytuła et al., 2015 ).

Neutron diffraction data confirm the antiferromagnetic ground state in selected members of both stoichiometric and nonstoichiometric families of compounds. The antiferromagnetic structure corresponds to the following propagation vectors: k = [¼, ¼, ½] in Tb₂Ni_1.78In, [½, ½, ½] in Tb₂Ni₂In (Szytuła et al., 2013) and [½, 0, ½] in R₂Ni₂In (R = Er, Tm) (Baran et al., 2017 ).

A recent paper on magnetism in the 2:2:1 compounds reports a ferromagnetic order for R = Pr and Nd, and an antiferromagnetic order for R = Dy and Ho. A considerable magnetocaloric effect is detected in the vicinity of the magnetic transition in all four compounds (Zhang et al., 2019 ).

This work is a continuation of our investigation of the magnetic properties of the compounds belonging to the R–Ni–In systems. We report here for the first time the low-temperature magnetic structures of R₂Ni_1.78In (R = Ho, Er, Tm) as determined from powder neutron diffraction. The validity of the structures is verified by symmetry analysis. In addition, we present a symmetry analysis of the Tb₂Ni_1.78In magnetic structure which was missing from the original paper (Szytuła et al., 2013). The magnetic properties of Tm₂Ni_1.78In, as derived from DC magnetic measurements, are also reported.

2. Experimental details

Polycrystalline samples of R₂Ni_1.78In (R = Ho, Er and Tm) of a total weight of 5 g each were obtained by arc melting of the constituent elements (purity 99.9 wt% or better) under an argon atmosphere. The obtained ingots were encapsulated in evacuated silica tubes and annealed at 870 K for one month, then quenched in cold water. Finally, the samples' quality was checked by X-ray powder diffraction performed at room temperature using a PANalytical X'Pert PRO diffractometer (Cu K_α radiation).

DC magnetic measurements were carried out using a commercial vibrating sample magnetometer (VSM) option installed on the PPMS platform by Quantum Design. The data were collected in the temperature range 2–300 K in magnetic fields up to 90 kOe.

Powder neutron diffraction patterns were taken at low temperature (1.6 K) and in the paramagnetic state (above the respective Néel temperature) on the E6 diffractometer at Helmholtz-Zentrum Berlin für Materialien und Energie GmbH. The incident neutron wavelength was 2.432 Å.

For Rietveld analysis of X-ray and neutron diffractograms the computer program FULLPROF was utilized (Rodríguez-Carvajal, 1993 , 2001 $[Rodríguez-Carvajal, J. (2001). Newsletter of the Commission for Powder Diffraction of the IUCr, 26, 12-19.]$ ), while for symmetry analysis the computer program BASIREPS, which is distributed together with FULLPROF, was used.

No new data were collected for the Tb₂Ni_1.78In sample. The previously reported neutron diffraction patterns (Szytuła et al., 2013) were re-analyzed on the basis of symmetry analysis.

3. Results

3.1. Crystal structure

The X-ray diffraction data collected at room temperature confirm the previously reported tetragonal crystal structure of the Mo₂FeB₂ type. Detailed analysis of the powder neutron diffraction patterns taken in the paramagnetic state provided information on both the samples' phase composition and their crystal structure parameters. The investigated samples contain about 80% of the R₂Ni_1.78In phase with a small content of the 2:2:1 and 5:2:4 phases. In addition, in the Er- and Tm-based samples small amounts of the R₂O₃ oxides were detected (see Table 1).

Table 1
Phase compositions (wt%) of the investigated R₂Ni_1.78In samples

	R
Phase	Tb	Ho	Er	Tm
2:1.78:1	84.8 (9)	88.0 (1.4)	76.9 (1.0)	80.3 (1.8)
2:2:1	15.2 (9)			6.6 (8)
5:2:4		12.0 (1.4)	16.8 (2.3)	10.8 (1.4)
R₂O₃			6.3 (5)	2.4 (5)

A typical neutron powder diffraction pattern in the paramagnetic state (taken at T = 7.2 K for Tm₂Ni_1.78In) is shown in Fig. 1. Similar patterns are observed for the other investigated samples. The tetragonal crystal structure of the Mo₂FeB₂ type (space group P4/mbm) is shown in Fig. 2. The determined unit-cell parameters and atomic positional parameters are listed in Table 2. They are in good agreement with the previously reported data (Kalychak et al., 1990; Tyvanchuk et al., 2012).

Table 2
Crystal structure parameters for R₂Ni_1.78In (R = Tb, Ho, Er, Tm; space group P4/mbm) determined by Rietveld refinement from neutron diffraction patterns collected in the paramagnetic state

For R = Tb, Er the nearest-neighbour distances (NN) are between atoms R1 and R4 and between atoms R2 and R3, and the next-nearest neighbour distance (NNN) is equal to the c lattice parameter. For R = Ho, Tm there is a reverse relationship: NN = c and NNN = R1–R4 and R2–R3 distances.

	R/T (K)
Parameter	Tb/29.9	Tb/1.6	Ho/12.2	Ho/1.6	Er/12.0	Er/1.6	Tm/7.2	Tm/1.6
a (Å)	7.3517 (7)	7.3459 (7)	7.3327 (9)	7.328 (1)	7.320 (3)	7.300 (2)	7.2930 (9)	7.285 (1)
c (Å)	3.6571 (4)	3.6696 (6)	3.6084 (5)	3.6078 (6)	3.603 (1)	3.5912 (9)	3.5770 (5)	3.5724 (6)
V (Å³)	197.66 (3)	198.02 (4)	194.02 (4)	193.74 (5)	193.1 (1)	191.39 (7)	190.26 (4)	189.57 (5)
x_R	0.1756 (8)	0.175 (1)	0.1758 (8)	0.176 (1)	0.173 (2)	0.174 (2)	0.1741 (8)	0.174 (1)
x_Ni	0.3788 (6)	0.3785 (9)	0.3794 (6)	0.3791 (8)	0.380 (1)	0.380 (1)	0.3799 (6)	0.3798 (8)
NN (Å)	3.65 (1)	3.63 (1)	3.6084 (5)	3.6078 (6)	3.58 (2)	3.59 (2)	3.5770 (5)	3.5724 (6)
NNN (Å)	3.6571 (4)	3.6696 (6)	3.646 (7)	3.64 (1)	3.603 (1)	3.5912 (9)	3.591 (9)	3.58 (1)
R_Bragg	0.0357	0.0280	0.0426	0.0376	0.0756	0.0519	0.0480	0.0435
R_f	0.0310	0.0177	0.0325	0.0299	0.0590	0.0413	0.0428	0.0261

Figure 1
The neutron diffraction pattern of Tm₂Ni_1.78In collected at T = 7.2 K in the paramagnetic state (open circles), together with the results of the Rietveld refinement (red line) and the difference curve (bottom line). The first row of vertical bars refers to the peak positions originating from the Tm₂Ni_1.78In main phase [80.3 (1.8) wt%], while the second, third and fourth rows correspond to reflections from the Tm₅Ni₂In₄ (Szytuła et al., 2014

) [10.8 (1.4) wt%], Tm₂Ni₂In (Baran et al., 2017

) [6.6 (8) wt%] and Tm₂O₃ (Maslen et al., 1996

) [2.4 (5) wt%] impurity phases, respectively.

Figure 2
The crystal unit cell of Tm₂Ni_1.78In, typical of other R₂Ni_1.78In compounds (tetragonal crystal structure of the Mo₂FeB₂ type, space group P4/mbm).

3.2. Magnetic properties

Magnetic measurements were performed for the R₂Ni_1.78In (R = Ho, Er and Tm) samples. The data for R = Ho and Er are in agreement with those reported previously (Tyvanchuk et al., 2012) and so they are not presented in this work. The results of magnetic measurements for Tm₂Ni_1.78In are presented in Fig. 3. At high temperatures the reciprocal magnetic susceptibility obeys the Curie–Weiss law with a negative value of the paramagnetic Curie temperature (−9.8 K) and the effective magnetic moment per Tm atom (7.77 μ_B) being close to that predicted for the free Tm³⁺ ion (7.56 μ_B). In the low-temperature range (see the upper inset in Fig. 3) a maximum typical of an antiferro- to paramagnetic transition is clearly visible at 4.5 K. The lower inset in Fig. 3 presents the hysteresis loop of magnetization versus external magnetic field up to 90 kOe. The data were taken at 2.0 K. It is worth noting that the value of the magnetic moment per Tm atom, as derived from the measurements at T = 2.0 K and H = 90 kOe, equals 3.4 μ_B and is significantly smaller than that of the free Tm³⁺ ion, which equals 7.0 μ_B. The initial magnetization curve shows a metamagnetic transition at the critical field of 13.7 kOe.

Figure 3
The reciprocal magnetic susceptibility for Tm₂Ni_1.78In (circles), together with a fitted line representing the Curie–Weiss law. The upper inset shows the low-temperature behaviour, while the lower one shows the hysteresis loop of the magnetization versus external magnetic field up to 90 kOe. The vertical line indicates the metamagnetic transition.

3.3. Magnetic structures

The magnetic moments in R₂Ni_1.78In (R = Tb, Ho, Er, Tm) are expected to be localized on the rare earth atoms, as the effective magnetic moments per rare earth atom R are close to the values predicted for the free R³⁺ ions [see Section 3.2, as well as the data in Table II of Tyvanchuk et al. (2012)]. The rare earths in R₂Ni_1.78In occupy the 4h Wyckoff site in the crystal unit cell (space group P4/mbm, see Fig. 2) (Szytuła et al., 2013). The coordinates of the four R atoms in the unit cell are as follows:

(i) R1 at (x_R, x_R + ½, ½).

(ii) R2 at (x_R + ½, 1 − x_R, ½).

(iii) R3 at (½ − x_R, x_R, ½).

(iv) R4 at (1 − x_R, ½ − x_R, ½).

Propagation vectors describing the magnetic ordering were obtained based on the positions of magnetic reflections in the neutron diffraction patterns of R₂Ni_1.78In. Subsequently, the allowed magnetic structures were calculated using the BASIREPS program from the FULLPROF package. The program generates possible irreducible representations (IRs) for a given propagation vector, space group and Wyckoff position of magnetic atoms. The proper IRs, describing the magnetic structure for a selected R₂Ni_1.78In compound, were chosen as those giving the best agreement between the experimental and calculated patterns (the full symmetry analysis is available in the supporting information). The final magnetic structures in R₂Ni_1.78In (R = Tb, Ho, Tm) were obtained by Rietveld refinement applied to the difference patterns (i.e. those obtained by subtraction of the neutron diffraction pattern in the paramagnetic state from the low-temperature pattern) as containing purely the magnetic contribution. The only exception was made for R = Er, where the full low-temperature neutron diffraction pattern was used for Rietveld refinement of the magnetic structure because of the high noise in the difference pattern.

3.3.1. Tb₂Ni_1.78In

The low-temperature magnetic structure has been reported by Szytuła et al. (2013). What is missing from the original paper is a symmetry analysis of the magnetic structure. Thus, a detailed symmetry analysis with a new refinement of the neutron powder diffraction data is presented below. A comparison with the previously reported data is presented at the end of this section.

The magnetic reflections in the neutron diffraction pattern registered at 1.6 K can be indexed by the propagation vector k₁ = [¼, ¼, ½], as shown for the difference pattern 1.6 K − 29.9 K in Fig. 4(a). The large magnetic unit cell consists of 32 crystal unit cells. It is enlarged four times along the a and b directions and twice along the c direction. For the k₁ = [¼, ¼, ½] propagation vector and the 4h site of the P4/mbm space group, the Tb atoms are divided into three independent orbits: atom Tb1 in orbit I, a (Tb2, Tb3) pair in orbit II and atom Tb4 in orbit III. Therefore the magnetic ordering of the (Tb2, Tb3) atoms is constrained by symmetry, while the magnetic moments of Tb1 and Tb4 are independent.

Figure 4
Neutron diffraction patterns for R₂Ni_1.78In collected at T = 1.6 K for R = (a) Tb, (b) Ho, (c) Er and (d) Tm (open circles), with the results of the Rietveld refinements (red lines) and the difference curves (bottom blue lines). In panels (a), (b) and (d) the difference patterns are obtained by subtraction of the pattern collected in the paramagnetic state from the pattern collected in the magnetically ordered state at T = 1.6 K. The first and second rows of vertical bars refer to the positions of reflections of nuclear and magnetic origin, respectively (the positions of nuclear reflections in the difference patterns are shown for reference only). The propagation vectors describing the magnetic structure are as follows: (a) k₁ = [¼, ¼, ½] and (b) k₂ = [0.31, 0.31, ½], while in (c) and (d) two propagation vectors (k₁ = [¼, ¼, ½] and $[{\bf k}_{1}^{\prime\prime\prime}]$ = [−¼, ¼, −½]) are taken into consideration. In addition, the third row in (a) refers to magnetic reflections arising from magnetic ordering in the Tb₂Ni₂In impurity phase (Szytuła et al., 2013

). The third and fourth rows in (c) indicate nuclear reflections related to the Er₅Ni₂In₄ (Gondek et al., 2012

) [16.8 (2.3) wt%] and Er₂O₃ (Maslen et al., 1996

) [6.3 (5) wt%] impurities. The third and fourth rows in (d) refer to the magnetic ordering in Tm₅Ni₂In₄ (Szytuła et al., 2014

) [10.8 (1.4) wt%] and Tm₂Ni₂In (Baran et al., 2017

) [6.6 (8) wt%]. Selected 2θ regions in (a) have been excluded from the refinement as they contain anomalies arising from shifts in nuclear reflections due to thermal evolution of the unit-cell parameters.

Theory predicts four irreducible representations, namely IR1 and IR3, related to the ordering of magnetic moments within the ab plane, and IR2 and IR4, related to the ordering along the c axis. The best agreement with the experimental pattern [Fig. 4(a)] is obtained for an antiferromagnetic ordering along the c direction, described by the IR2 representation (Table 3). Although the symmetry analysis allows for different amplitudes of modulation for the magnetic moments of atoms belonging to different orbits, it was reasonable to assume an identical absolute value of the C₁ parameter (see Table 3) for all Tb atoms.

Table 3
The magnetic structure of Tb₂Ni_1.78In described by the IR2 representation for the 4h Wyckoff site of the P4/mbm space group and propagation vector k₁ = [¼, ¼, ½]

C₁ and Φ are, respectively, an amplitude and a phase factor of modulation of the magnetic moment along the BV1 vector, μ is the magnetic moment of the rare earth atom, and R_magn is the magnetic reliability factor of the Rietveld refinement.

	k₁ = [¼, ¼, ½]	BV1
4h	Tb1 (x_Tb, x_Tb + ½, ½)	0 0 1
	Tb2 (x_Tb + ½, 1 − x_Tb, ½)	0 0 −i
	Tb3 (½ − x_Tb, x_Tb, ½)	0 0 1
	Tb4 (1 − x_Tb, ½ − x_Tb, ½)	0 0 1

T (K)	Tb₂Ni_1.78In	C₁ (μ_B)	Φ (2π)	μ (μ_B)	R_magn
1.6	Tb1	10.67 (7)	0.125	7.55 (5)	0.0542
	Tb2	10.67 (7)	0.625	7.55 (5)
	Tb3	10.67 (7)	0.375	7.55 (5)
	Tb4	−10.67 (7)	0.375	7.55 (5)

As only the relative phase shifts between atoms influence the intensities of the magnetic peaks, the absolute value of the magnetic phase factor of the Tb1 reference atom can be chosen arbitrarily, taking into account the physical validity of the proposed magnetic structure. For the zero phase factor of atom Tb1 and the magnetic phase factors of Tb2, Tb3, Tb4 fixed to ½, ¼, ¼ (in 2π units), respectively, the magnetic moment on a particular Tb atom, as determined for T = 1.6 K, is equal either to zero or to the modulation amplitude |C₁| = 10.67 (7) μ_B.

A more realistic magnetic structure [see Fig. 5(a)] is obtained while assuming a magnetic phase factor of atoms Tb1 of $[{1 \over 8}]$ , with the phase factors of atoms Tb2, Tb3, Tb4 fixed to $[{5 \over 8}]$ , $[{3 \over 8}]$ and $[{3 \over 8}]$ , respectively. For the latter magnetic structure model, all terbium magnetic moments equal μ = |C₁|/(2^1/2) = 7.55 (5) μ_B at T = 1.6 K.

Figure 5
Magnetic structures in R₂Ni_1.78In as described in Tables 3

, 4

and 5

: (a) R = Tb, (b) R = Ho and (c) R = Er, Tm (presented here for R = Tm). The magnetic unit cell is shown for commensurate structures in panels (a) and (c), while for the incommensurate structure in (b) a representative fragment of the structure is shown. Atoms R₁, R₂, R₃ and R₄ are depicted in red, black, yellow and blue, respectively.

The magnetic structure presented above for Tb₂Ni_1.78In coincides with the structure reported originally by Szytuła et al. (2013), although the new refinement leads to a better value of the reliability factor (R_magn = 0.054) than the one originally reported (0.081).

3.3.2. Ho₂Ni_1.78In

The magnetic contribution to the Ho₂Ni_1.78In diffraction pattern at T = 1.6 K is shown in Fig. 4(b). The propagation vector indexing the magnetic reflections observed for Ho₂Ni_1.78In is an incommensurate one, k₂ = [k_x, k_x, ½], where k_x = 0.3074 (4).

The symmetry analysis shows that the Ho atoms are divided into three orbits, namely, Ho1 in orbit I, the (Ho2, Ho3) pair in orbit II and Ho4 in orbit III, and that the ordering of magnetic moments is allowed both within the ab plane (IR1, IR3) and along the c direction (IR2, IR4). The agreement with the experimental difference pattern 1.6 K − 12.2 K [Fig. 4(b)] is obtained for the IR2 irreducible representation, i.e. the ordering of magnetic moments along the c axis (see Table 4).

Table 4
The magnetic structure of Ho₂Ni_1.78In described by the IR2 representation for the 4h Wyckoff site of the P4/mbm space group and propagation vector k₂ = [k_x, k_x, ½], where k_x = 0.3074 (4) at 1.6 K

C₁ and Φ are, respectively, an amplitude and a phase factor of modulation of the magnetic moment along the BV1 vector, μ_max is the maximum magnetic moment of the rare earth atom and R_magn is the magnetic reliability factor of the Rietveld refinement. The parameter α is defined as α = 2πk_x.

	k₂ = [0.31, 0.31, ½]	BV1
4h	Ho1 (x_Ho, x_Ho + ½, ½)	0 0 1
	Ho2 (x_Ho + ½, 1 − x_Ho, ½)	0 0 (cosα − isinα)
	Ho3 (½ − x_Ho, x_Ho, ½)	0 0 1
	Ho4 (1 − x_Ho, ½ − x_Ho, ½)	0 0 1

T (K)	Ho₂Ni_1.78In	C₁ (μ_B)	Φ (2π)	μ_max (μ_B)	R_magn
1.6	Ho1	7.93 (8)	0†	7.93 (8)	0.0552
	Ho2	7.93 (8)	0.55 (2)	7.93 (8)
	Ho3	7.93 (8)	0.24 (2)	7.93 (8)
	Ho4	7.93 (8)	−0.297 (7)	7.93 (8)

†Fixed to define a point of reference.

The amplitude of modulation of the magnetic moments, constrained to be identical for all Ho atoms, is equal to C₁ = 7.93 (8) μ_B. As for an incommensurate magnetic structure, the absolute values of the magnetic phase factors Φ_i have no physical meaning. Thus, the phase factor of Ho1 was fixed to zero in order to define a point of reference, while the phase factors of all remaining atoms were refined. The magnetic phase factors for Ho3 and Ho4 have opposite signs, but absolute values close to ¼ (while assuming Φ₁ = 0), and for Ho2 the phase factor is Φ₃ + k_x ≃ ½. A fragment of the antiferromagnetic structure of Ho₂Ni_1.78In (a magnetic unit cell cannot be defined due to incommensurability) is presented in Fig. 5(b).

In the case of Ho₂Ni_1.78In, the thermal evolution of its neutron diffraction pattern was also recorded. Based on these data, the temperature dependences of the amplitude of modulation (C₁ parameter) and the k_x component of the propagation vector were determined and are presented in Fig. 6. The temperature dependence of C₁ yields T_N = 7.5 K. It is also worth noting that the k_x component of the propagation vector increases noticeably while approaching T_N.

Figure 6
Ho₂Ni_1.78In: temperature dependence of (a) the amplitude of modulation of the magnetic moment (C₁ parameter) and (b) the k_x component of the propagation vector k₂ = [k_x, k_x, ½].

3.3.3. Er₂Ni_1.78In and Tm₂Ni_1.78In

The magnetic contributions to the neutron patterns of Er₂Ni_1.78In and Tm₂Ni_1.78In are similar to one another, indicating the same magnetic structure in both compounds, with the only difference being in the absolute values of the magnetic moments. The magnetic reflections observed at T = 1.6 K for Er₂Ni_1.78In [Fig. 4(c)] and Tm₂Ni_1.78In [Fig. 4(d)] can be indexed by the propagation vector k₁ = [¼, ¼, ½].

In contrast to what was found for R = Tb, agreement with the experimental patterns for R = Er, Tm was obtained for the magnetic moments constrained to the ab plane according to the IR1 representation. However, this initial model of the magnetic structure in R₂Ni_1.78In (R = Er, Tm) leads to unreliable values of the magnetic moments, i.e. following the results of Rietveld refinement, the moments on atoms R1 and R4 equal 9.2 (2) and 8.62 (5) μ_B for R = Er and Tm, respectively, while atoms R2 and R3 do not contribute at all to the intensity of the magnetic peaks as they have zero magnetic moments. This non-physical result points to the necessity of taking into consideration additional propagation vectors, similar to what was previously reported for TmAgGe (Baran et al., 2009 ).

The k₁ = [¼, ¼, ½] vector forms a star containing three other propagation vectors, namely, $[{\bf k}_{1}^{\prime}]$ = [−¼, −¼, ½], $[{\bf k}_{1}^{\prime\prime}]$ = [¼, −¼, ½] and $[{\bf k}_{1}^{\prime\prime\prime}]$ = [−¼, ¼, −½]; all these propagation vectors provide the same positions of Bragg reflections of the magnetic origin. $[{\bf k}_{1}^{\prime}]$ is equivalent to −k₁ while $[{\bf k}_{1}^{\prime\prime\prime}]$ is equivalent to $[- {\bf k}_{1}^{\prime\prime}]$ . It is worth noting that taking a combination of the propagation vectors from the first (k₁, $[{\bf k}_{1}^{\prime}]$ ) and second ( $[{\bf k}_{1}^{\prime\prime}]$ , $[{\bf k}_{1}^{\prime\prime\prime}]$ ) pairs leads to new magnetic structures that cannot be obtained with the use of the propagation vectors originating from a single pair. The Rietveld refinement shows that both good agreement with the experimental patterns and reasonable values of the magnetic moments can be obtained for a combination of the k₁ and $[{\bf k}_{1}^{\prime\prime\prime}]$ vectors. The final structure is presented in Fig. 5(c).

The magnetic ordering of atoms R1 and R4 is described by k₁ = [¼, ¼, ½], while that involving atoms R2 and R3 is related to $[{\bf k}_{1}^{\prime\prime\prime}]$ = [−¼, ¼, −½] (see Table 5). According to the symmetry analysis reported by the BASIREPS program, in the discussed structure the magnetic moments of R1, …, R4 are independent with respect to the amplitude of modulation and the magnetic phase factor. However, in order to get a physically valid magnetic structure the amplitudes of modulation of all R_i were constrained to be equal. The Rietveld refinement yields a difference of ¼ between the magnetic phase factors of atoms R2 and R4 and those of atoms R1 and R3. In order to obtain identical absolute values of the magnetic moments for all rare earth atoms, equal to |C₁|, the magnetic phases were fixed to $[{1 \over 8}]$ for R1 and R3 and to $[{3 \over 8}]$ for R2 and R4. The magnetic moments derived from refinement of the neutron diffraction patterns collected at T = 1.6 K equal 6.5 (1) μ_B for R = Er and 6.09 (4) μ_B for R = Tm.

Table 5
The magnetic structure of R₂Ni_1.78In (R = Er, Tm) described by the pair of propagation vectors k₁ = [¼, ¼, ½] (atoms R1 and R4) and $[{\bf k}_1^{\prime \prime \prime}]$ = [−¼, ¼, −½] (atoms R2 and R3)

The ordering of magnetic moments is related to the IR1 representation for each propagation vector. The C_i coefficients describe individual contributions to the rare earth magnetic moment μ along the respective basis vectors, while Φ is the magnetic phase factor. R_magn denotes the magnetic reliability factor of the Rietveld refinement

		k₁ = [¼, ¼, ½]		$[{\bf k}_1^{\prime \prime \prime}]$ = [−¼, ¼, −½]
		BV1	BV2	BV1	BV2
4h	R1 (x_R, x_R + ½, ½)	1 −1 0		1 0 0	0 1 0
	R2 (x_R + ½, 1 − x_R, ½)	0 i 0	i 0 0	1 1 0
	R3 (½ − x_R, x_R, ½)	1 0 0	0 1 0	1 1 0
	R4 (1 − x_R, ½ − x_R, ½)	1 −1 0		0 i 0	i 0 0

T (K)	Er₂Ni_1.78In	C₁ (μ_B)	C₂ (μ_B)	C₁ (μ_B)	C₂ (μ_B)	Φ (2π)	μ (μ_B)	R_magn
1.6	Er1	6.5 (1)				0.125	6.5 (1)	0.142
	Er2			−6.5 (1)		0.375	6.5 (1)
	Er3			6.5 (1)		0.125	6.5 (1)
	Er4	−6.5 (1)				0.375	6.5 (1)

T (K)	Tm₂Ni_1.78In	C₁ (μ_B)	C₂ (μ_B)	C₁ (μ_B)	C₂ (μ_B)	Φ (2π)	μ (μ_B)	R_magn
3.6	Tm1	3.73 (7)				0.125	3.73 (7)	0.121
	Tm2			−3.73 (7)		0.375	3.73 (7)
	Tm3			3.73 (7)		0.125	3.73 (7)
	Tm4	−3.73 (7)				0.375	3.73 (7)

2.6	Tm1	5.76 (4)				0.125	5.76 (4)	0.0746
	Tm2			−5.76 (4)		0.375	5.76 (4)
	Tm3			5.76 (4)		0.125	5.76 (4)
	Tm4	−5.76 (4)				0.375	5.76 (4)

1.6	Tm1	6.09 (4)				0.125	6.09 (4)	0.0476
	Tm2			−6.09 (4)		0.375	6.09 (4)
	Tm3			6.09 (4)		0.125	6.09 (4)
	Tm4	−6.09 (4)				0.375	6.09 (4)

4. Discussion

The X-ray and neutron diffraction data confirm that the R₂Ni_1.78In (R = Tb, Ho, Er and Tm) compounds crystallize in the tetragonal Mo₂FeB₂-type structure (space group P4/mbm) in a broad temperature range down to 1.6 K. In this structure, the rare earth atoms occupy the 4h Wyckoff site in the ab plane (z = ½) separated by planes containing the Ni and In atoms (z = 0). The structure is highly anisotropic with a short c lattice parameter (the c/a ratio is close to 0.5). The atomic arrangement is formed from slabs of CsCl-type (RIn) and AlB₂-type (RNi₂). The rare earth atoms form triangles and squares within the ab plane (see Fig. 7). The resultant natural anisotropic multilayer structure suggests a high anisotropy of physical properties, especially those of magnetic character.

Figure 7
A projection of the crystal and magnetic structures in Ho₂Ni_1.78In on the (001) plane. The + and − symbols indicate the parallel and antiparallel orientations, respectively, of the Ho magnetic moments with respect to the c axis. Triangles and squares formed by the rare earth atoms are also marked.

Magnetic susceptibility measurements, taken in the paramagnetic state, show that the effective magnetic moments per rare earth atom are close to the free R³⁺ ion values, and therefore suggest that only the rare earth atoms carry magnetic moments. This result is in agreement with the results of Rietveld refinement of the low-temperature neutron diffraction data. Therefore, the magnetism in the investigated compounds is related to the rare earth magnetic moments, while the Ni atoms either remain non-magnetic, as predicted by ab initio calculations of the electronic structure in U₂Ni₂X (X = p-electron element) (Diviš et al., 1995 ; Matar, 1995 ), or their magnetic moments are too small to be detected by the experimental methods used in this study, especially considering that the Ni atoms are accompanied by rare earth atoms carring large moments.

The paramagnetic Curie temperatures in R₂Ni_1.78In are found to be negative, suggesting that antiferromagnetic interactions are predominant. The antiferromagnetic ordering in the investigated compounds is confirmed by both the low-temperature magnetic data (see the upper inset in Fig. 3) and the neutron diffraction data (see Tables 3, 4 and 5). Detailed analysis of the low-temperature neutron diffraction data shows that the magnetic structures are related to the following propagation vectors: k₁ = [¼, ¼, ½] for R = Tb and k₂ = [k_x, k_x, ½] for R = Ho, where k_x = 0.3074 (4) at 1.6 K and increases with increasing temperature, while for R = Er and Tm a combination of two propagation vectors (k₁ = [¼, ¼, ½] and $[{\bf k}_{1}^{\prime\prime\prime}]$ = [−¼, ¼, −½]) has to be taken into consideration. All these vectors have the k_z component equal to ½, indicating simple antiferromagnetic coupling between neighbouring (001) planes, while the ordering within the planes is much more complex [see Figs. 5(a)–5(c) and 7].

As the rare earth interatomic distances exceed 3.5 Å, they are high enough to exclude any direct interactions, and therefore the interactions between magnetic atoms are expected to be indirect of the Ruderman–Kittel–Kasuya–Yosida (RKKY) type. One of the predictions of the RKKY theory is proportionality between the critical temperature of magnetic ordering (i.e. the Curie or Néel temperature) and the de Gennes factor defined as (g_J − 1)²J(J + 1), where g_J is the Lande splitting factor and J is the total angular momentum of the corresponding magnetic ion (De Gennes, 1962 ). This relation is not fulfilled in R₂Ni_1.78In [see Fig. 4 of Tyvanchuk et al. (2012)], indicating an influence of the crystalline electric field (CEF) in the stabilization of the magnetic structure. The impact of the CEF also manifests itself in the reduction of the rare earth magnetic moment in the magnetically ordered state when compared with the moments of the free R³⁺ ions – see Section 3.2 and the data in Table II of Tyvanchuk et al. (2012). A change in direction of the magnetic moment, from parallel to the c axis in the Tb- and Ho-based compounds to perpendicular to this axis for R = Er and Tm, is further proof of the important role of the CEF, as it coincides with a change in sign of the Stevens factor α_J from negative in Tb and Ho to positive in Er and Tm (Stevens, 1952 ).

Antiferromagnetic structures have also been observed in isostructural compounds with the P4/mbm space group. The propagation vector k = [0, 0, ½] describes the magnetic order in Pr₂Pd₂In (Fischer et al., 2000 ) and in the low-temperature magnetic phase in Tb₂Pd_2.05Sn_0.95 (Laffargue et al., 1997 ), while the high-temperature magnetic phase in Tb₂Pd_2.05Sn_0.95, which appears near the Néel temperature, is related to k = [k_x, k_x, ½], where k_x equals 0.075 (5) at T = 20.8 K and 0.115 (5) at 26.3 K. The magnetic order in Nd₂Pd₂In is described by the propagation vector k = [¼, ¼, 0] (Fischer et al., 2000).

The observed variety of magnetic orderings within the (001) plane can be understood while taking into account the results of the theoretical analysis of the magnetic structure in the TbCo₂B₂ compound with a tetragonal crystal structure (space group P4/mmm). The magnetic order in TbCo₂B₂ is described by the propagation vector k = [k_x, k_x, 0], where k_x equals ¼ at 1.5 K and 0.244 at 14 K (André et al., 1991 ). The theoretical model considering interactions within the (001) plane between the first-, second- and third-nearest neighbours, described by the exchange integrals J₁, J₂ and J₃, respectively, shows that the magnetic phase related to k = [¼, ¼, 0] is stabilized by a relatively large positive value of J₃ (Plumer & Caillé, 1992 ).

5. Conclusions

The results presented in this work confirm that the ternary R₂Ni_1.78In (R = Tb, Ho, Er, Tm) compounds crystallize in the tetragonal Mo₂FeB₂-type structure (space group P4/mbm). The magnetic and neutron diffraction data indicate that the rare earth magnetic moments in these compounds order antiferromagnetically at low temperatures, with the magnetic structures described by the propagation vector k = [k_x, k_x, ½], where k_x equals ¼ for R = Tb, Er and Tm and about 0.3 for R = Ho. The impact of the crystalline electric field (CEF) manifests itself in a reduction of the rare earth magnetic moments in the ordered state, a change in the direction of the magnetic moments from parallel to the c axis for R = Tb and Ho to perpendicular for R = Er and Tm, and deviation from proportionality between the Néel temperature and the de Gennes factor. Therefore, the observed magnetic structures result from competition between indirect exchange interactions of the RKKY-type and the CEF.

Supporting information

Symmetry analysis of the magnetic structures as reported by the BasIreps program. The input data for FP_Studio are also included. DOI: https://doi.org/10.1107/S2052520621008179/lo5091sup1.pdf

Acknowledgements

Kind hospitality and financial support extended to two of us (SB and AS) by the Helmholtz-Zentrum Berlin für Materialien und Energie (HZB) is gratefully acknowledged. Our special thanks go to Professor Wiesława Sikora from the AGH University of Science and Technology (Kraków, Poland) for fruitful discussions of symmetry analysis of magnetic structures.

Funding information

This research was partially carried out with equipment purchased thanks to the financial support of the European Regional Development Fund in the framework of the Polish Innovation Economy Operational Program (contract No. POIG.02.01.00-12-023/08). The open-access publication of this article was funded by the Priority Research Area SciMat under the program "Excellence Initiative – Research University" at the Jagiellonian University in Krakow.

References

André, G., Thuéry, P., Pinot, M., Oleś, A. & Szytuła, A. (1991). Solid State Commun. 80, 239–241. Google Scholar
Baran, S., Kaczorowski, D., Arulraj, A., Penc, B. & Szytuła, A. (2009). J. Magn. Magn. Mater. 321, 3256–3261. Web of Science CrossRef ICSD CAS Google Scholar
Baran, S., Szytuła, A. & Hoser, A. (2017). J. Alloys Compd. 696, 1278–1281. CrossRef ICSD CAS Google Scholar
De Gennes, P. (1962). J. Phys. Radium, 23, 510–521. CrossRef CAS Google Scholar
Diviš, M., Olšovec, M., Richter, M. & Eschrig, H. (1995). J. Magn. Magn. Mater. 140–144, 1365–1366. Google Scholar
Fischer, P., Herrmannsdörfer, T., Bonelli, T., Fauth, F., Keller, L., Bauer, E. & Giovannini, M. (2000). J. Phys. Condens. Matter, 12, 7089–7098. CrossRef CAS Google Scholar
Gondek, L., Przewoźnik, J., Czub, J., Tyvanchuk, Yu., Szytuła, A. & Arurlaj, A. (2012). Intermetallics, 21, 10–17. CrossRef ICSD CAS Google Scholar
Hauser, R., Michor, H., Bauer, E., Hilscher, G. & Kaczorowski, D. (1997). Physica B, 230–232, 211–213. CrossRef CAS Google Scholar
Kaczorowski, D., Rogl, P. & Hiebl, K. (1996). Phys. Rev. B, 54, 9891–9902. CrossRef CAS Google Scholar
Kalychak, Ya. M., Zaremba, V. I., Baranyak, V. M., Zavalii, P. Yu., Bruskov, V. A., Sysa, L. V. & Dmytrakh, O. V. (1990). Izv. Akad. Nauk SSSR Neorg. Mater. 26, 94–96. [English translation: (1990). Inorg. Mater. 26, 74–76.] Google Scholar
Kalychak, Ya. M., Zaremba, V. I., Pöttgen, R., Lukachuk, M. & Hoffmann, R.-D. (2004). Handbook on the Physics and Chemistry of Rare Earths, edited by K. A. Gschneidner Jr., J.-C. G. Bünzli & V. K. Pecharsky, Vol. 34, ch. 218, pp. 1–133. Amsterdam: Elsevier. Google Scholar
Laffargue, D., Roisnel, T., Chevalier, B. & Bourée, F. (1997). J. Alloys Compd. 262–263, 219–224. CrossRef ICSD CAS Google Scholar
Maskova, S., Danis, S., Llobet, A., Nakotte, H. & Havela, L. (2014). Acta Phys. Pol. A, 126, 282–283. CrossRef Google Scholar
Maslen, E. N., Streltsov, V. A. & Ishizawa, N. (1996). Acta Cryst. B52, 414–422. CrossRef ICSD CAS Web of Science IUCr Journals Google Scholar
Matar, S. F. (1995). J. Magn. Magn. Mater. 151, 263–272. CrossRef CAS Google Scholar
Plumer, M. L. & Caillé, A. (1992). Phys. Rev. B, 46, 203–206. CrossRef CAS Google Scholar
Rodríguez-Carvajal, J. (1993). Physica B, 192, 55–69. CrossRef Web of Science Google Scholar
Rodríguez-Carvajal, J. (2001). Newsletter of the Commission for Powder Diffraction of the IUCr, 26, 12–19. Google Scholar
Stevens, K. W. H. (1952). Proc. Phys. Soc. A, 65, 209–215. CrossRef Web of Science Google Scholar
Szytuła, A., Baran, S., Hoser, A., Kalychak, Ya. M., Penc, B. & Tyvanchuk, Yu. (2013). Acta Phys. Pol. A, 124, 994–997. Google Scholar
Szytuła, A., Baran, S., Kaczorowski, D., Sikora, W. & Hoser, A. (2014). J. Alloys Compd. 617, 149–153. Google Scholar
Szytuła, A., Baran, S., Przewoźnik, J., Tyvanchuk, Yu. & Kalychak, Ya. (2015). J. Magn. Magn. Mater. 387, 83–89. Google Scholar
Tyvanchuk, Yu., Baran, S., Jaworska-Gołąb, T., Duraj, R., Kalychak, Ya. M. & Szytuła, A. (2012). Acta Phys. Pol. A, 121, 678–681. CrossRef CAS Google Scholar
Zaremba, V. I., Bruskov, V. A., Zavalii, P. Yu. & Kalychak, Ya. M. (1988). Izv. Akad. Nauk SSSR Neorg. Mater. 24, 409–411. [English translation: (1988). Inorg. Mater. 24, 330–332.] Google Scholar
Zhang, Z., Wang, P., Rong, H. & Li, L. (2019). Dalton Trans. 48, 17792–17799. CrossRef CAS PubMed Google Scholar