1 Introduction

One of the most important issues in laser powder bed fusion (LPBF) additive manufacturing (AM) is the influence of residual stress (RS) on parts during production and service.[1] High-temperature gradients and cooling rates during production often lead to tensile RS.[2,3,4] Such stresses may reach values close to the yield limit in the subsurface region,[5,6] thereby decreasing the performance of the material, especially during cyclic loading. Moreover, RS can induce severe geometrical distortions and cracking,[4] thus nullifying the main advantage of freeform fabrication. Therefore, quantification of RS and validation of thermomechanical models by experimental results are among the greatest challenges for qualification of AM parts.

The nondestructive (diffraction-based) experimental determination of RS is directly connected to the microstructure of the part. The complicated thermal history and high anisotropy of LPBF parts lead to microstructures and mechanical properties different from conventionally manufactured materials (wrought or cast).[7] The microstructure in LPBF materials is additionally highly dependent on process parameters.[8,9,10] Therefore, the elastic properties may differ from conventional materials and even vary with the production parameters of LPBF. The knowledge about elastic properties is important for RS analysis by diffraction techniques, where the so-called diffraction elastic constants (DECs) are used[11] to connect the measured microstrain (diffraction based, i.e., averaged over grains of a particular family) with the macrostress (at the component length scale). Therefore, the use of incorrect DECs can lead to erroneous RS values[12] and misestimation of the material performance.

In-situ synchrotron X-ray diffraction (SXRD) or neutron diffraction (ND) is particularly suited for the experimental determination of DECs.[13,14] However, the available literature lacks information about the DECs of AM materials, with the consequence that values only valid for cast or wrought alloys are used for RS determination or modeling. Recently, in-situ tensile tests with SXRD have been reported on Ti-6Al-4V LPBF samples in as-built condition, targeted at studying the effect of different build orientations,[15] but the DECs have not been discussed. Dumontet et al.[16] first attempted evaluating the DEC of martensitic α′ LPBF Ti-6Al-4V material and found a difference of DECs up to 32 pct between pure α-Ti and α′-Ti in LPBF Ti-6Al-4V.

It has been shown that the experimentally determined DECs of wrought Ti alloys differ from theoretical values.[14] One of the reasons is the influence of the alloy composition, because some theoretical models consider single-crystal elastic constants of pure Ti. Indeed, the authors of Reference 12 have found a discrepancy between modeled and experimentally determined DECs for Ti-2.5Cu alloy and explained it by the influence of the Cu addition. The second reason of the discrepancy between theory and experiment is the influence of the specific microstructure and of the crystallographic texture (i.e., anisotropy). In Reference 17, a difference of lattice strain evolution between a unidirectionally rolled plate and some forged bar samples has been reported and ascribed to the presence of texture. LPBF materials are generally highly textured owing to the temperature gradients across the deposited layers (such gradients induce epitaxial growth along the building direction).[18,19,20,21] Also, the change of microstructure by means of heat treatment and its influence on the elastic behavior of grains is not captured by classic theoretical models, which are mostly used for RS calculation (e.g., Voigt, Reuss, and Kröner).[22] Much work has been conducted to improve those classic schemes for calculation of DECs,[23,24] and recently, some work to calculate single-crystal elastic constants[25,26] from in-situ experiments, taking into account the particular microstructural features (such as grain size and crystallographic texture). A detailed discussion of such models is out of the scope of this work and will be presented in a companion publication. Here, we focus on the experimental determination of DECs of LBPF Ti-6Al-4V as a tool to understand the elastic anisotropy of AM materials and the use of the appropriate assumptions for modeling. Such DECs can then be directly used for RS determination of that particular material.

We performed in-situ SXRD investigations on specimens in as-built conditions and after heat treatment. The link between the diffraction (micro-)strain response to an externally applied macrostress was rationalized in terms of a stress-microstrain conversion tensor (SµECT), as used in micromechanics. We show that such a tensor generalizes the concept of DECs and allows a critical discussion on the validity of the approximations made in the current models.

2 Experimental

2.1 Material

Ti-6Al-4V rods (8 mm in diameter, 95 mm in length) and cuboids (with size 5 × 5 × 15 mm3) were printed on a steel base plate (preheated to 200 °C) with the use of support structures and with their long axis along the build direction. An SLM Solutions 280HL machine was employed, using plasma-atomized Ti-6Al-4V ELI grade 23 powder from AP&C with a particle size of d90 < 50 μm. The characterization of the powder has been reported elsewhere.[27] The production parameters were set to the following: laser power of 175 W, laser velocity of 500 mm/s, hatch distance of 100 µm, and layer thickness of 30 µm (this parameter set is named A4 in our previous studies[10,28]). These manufacturing conditions were optimized in order to achieve minimum porosity and acceptable RS values.[10,29] The chess scanning strategy was used with a field size of 5 mm and rotating 90 deg from layer to layer.

Two samples were instigated in as-built conditions (labeled AB) and two samples were subjected to heat treatment at 530 °C for 2 hours after production (labeled 530C). The heat treatment was performed under Argon atmosphere with heating and cooling rate around 7 °C/min. For the in-situ mechanical tests, compression (_c) and tensile (_t) specimens were machined by turning without additional surface finishing applied (the geometry and dimensions are shown in Figure 1(a)).

Fig. 1
figure 1

(a) Sketch of tension (_t) and compression (_c) specimens with their coordinate system (all dimensions are in millimeters). (b) Picture of the in-situ setup with a tensile sample mounted in the load rig (to measure εax, ψ = 0 deg)

2.2 In-situ SXRD

In-situ SXRD tension and compression tests were performed in the transmission mode at the EDDI beamline (BESSY II, HZB, Berlin).[30] The EDDI diffractometer was operated in the energy-dispersive (ED) mode; therefore, the reflections of several crystallographic planes could be simultaneously tracked during the in-situ experiments. The diffraction peaks were fitted using a Pseudo-Voigt function; an in-house developed Mathematica code was employed. A liquid-nitrogen cooled Ge solid-state detector from Canberra (model GL0110) was used. The counting time was 2 minutes per spectrum. The aperture sizes of the primary and the secondary slits were 1 mm × 1 mm and 100 µm × 5 mm (equatorial × axial), respectively. This allowed averaging across the entire sample diameter. For the in-situ mechanical tests, a load rig (Walter + Bai AG) with maximum load of 20 kN, mounted on an Eulerian cradle, was employed (Figure 1(b)). The building direction of the sample corresponded to the load direction during uniaxial tests (axis X, Figure 1(a)). Acquisitions were performed in axial and radial directions for every load step (εax and εrad in Figure 1(a)), but for the sake of simplicity, only the axial data will be reported (see below). The load control mode was used with a loading rate of 10 N/s between each counting step. The displacement was defined by the relative displacement of the clamps. It should be noticed that the in-situ tensile tests were performed until failure, but only the elastic part is reported in the present study.

The lattice strain \( \varepsilon^{hkl} \) was calculated from \( d^{hkl} \) values at every load step as

$$ \varepsilon^{hkl} = \frac{{d^{hkl} - d_{\text{in}}^{hkl} }}{{d_{\text{in}}^{hkl} }} $$
(1)

where \( d_{\text{in}}^{hkl} \) was the lattice spacing for crystallographic plane families {hkl} at preload (around 10 N).

2.3 Microscopy and Texture Analysis

The microstructure was characterized in the clamp region at around 65 mm from the bottom of the sample. The measurements were performed in the plane perpendicular to the build direction. For microstructural analysis, AB_t and 530C_t samples were ground and then polished with an aqueous suspension of 0.04-μm SiO2 particles with the addition of 10 pct H2O2. Scanning electron microscopy (SEM) was conducted in backscattered electron mode (BSE) on a LEO 1530VP microscope with Gemini tower (Zeiss). The operation voltage was 15 kV and the working distance 7 mm.

Texture analysis was performed in the ED diffraction mode, employing the ED laboratory diffractometer LEDDI (HZB, Berlin). LEDDI features are described in detail in Reference 31. The experiments were conducted in reflection geometry. The texture measurements were performed in the plane perpendicular to the build direction, at the same location where microscopy was made: around 65 mm from the bottom of the sample and in the center of the sample. Only one location per sample was considered, since no variation of the microstructure was observed. A conventional tungsten long fine-focus X-ray tube was operated at U = 60 kV and I = 45 mA in combination with an ED detector system. The latter allows the simultaneous collection of multiple diffraction lines hkl up to photon energies of 60 keV in a single spectrum recorded under an arbitrary but fixed Bragg angle 2θ. For texture analysis, ED spectra were acquired at azimuthal angles φ (rotation in the YZ plane) and the inclination angles ψ (tilting in XZ plane) in the intervals from φ ϵ [0 deg; 355 deg] and ψ ϵ [0 deg; 85 deg] in steps of 5 deg. Overall, six hkl reflections of α/α′-Ti could be detected (002, 100, 101, 102, 103, and 110) and were evaluated in order to determine the orientation distribution function (ODF). From the ODF, pole figures for all crystallographic families {hkl} could be calculated. The ODF as well as the recalculated pole figures were processed using the software package LaboTex 3.0.[32]

2.4 X-ray Computed Tomography

X-ray computed tomography (CT) was performed in the gage region (middle height of the sample) prior to the mechanical test of both tensile samples (AB_t and 530C_t). A v|tome|x L 300 CT scanner from General Electric (GE) was used. 2000 projections were acquired for each CT scan. A tube voltage of 125 kV and a current of 60 µA were used. The acquisition time for each projection was 2 seconds. The GE standard commercial reconstruction algorithm was used and the beam hardening correction was selected based on reconstructed images. A voxel size of (4 µm)3 was achieved. Data processing was performed using the AvizoFire 9.4 software package.[33] The pores were identified by global threshold segmentation. To remove noise, raw data were filtered by a non-local means filter, implemented in the AvizoFire 9.4. software. For the calculation of the volume fraction of pores, only pores larger than eight voxels were considered to reduce the probability of false segmentation.

3 Results

The microstructure of the AB sample presents α + α′ laths (Figure 2(a)); this is typical for Ti-6Al-4V LPBF in the as-manufactured condition. The 530C sample shows a small amount of β-precipitates nucleated at the grain boundaries of α lamellae, as also shown in References 9 and 34. Haubrich et al.[9] reported that the mass fraction of β-Ti phase reaches around 3 pct. This heat treatment was adopted as it is supposed to be stress relieving without inducing large microstructural modifications.

Fig. 2
figure 2

BSE-SEM image taken in the build plane for (a) AB_t and (b) 530C_t. Red circles show examples of β-Ti particles

The microstructure, presented in Figure 2, is assumed to be representative of the gage volume used in the in-situ experiments. In fact, Barriobero-Vila et al.[35] showed that only a few last building layers (i.e., within the last millimeter of the built) have different microstructures (more precisely, β-phase content) from the rest of the sample in LPBF Ti-6Al-4V. Additionally, the gage volume used in the synchrotron radiation diffraction experiments practically covers the entire sample diameter (3 mm), thereby averaging the local microstructural variations.

From the three-dimensional reconstructions of the volumes and rendering of defects, projections along the X-axis and Y-axis could be extracted. They show the spatial distribution of defects (Figure 3). Lack of fusion defects,[29] typical for LPBF, and round gas pores could be observed in both samples. As mentioned above, the manufacturing conditions were considered as porosity optimized (reported in our previous studies).[10,29] Therefore, the investigated samples were expected to be close to fully dense. Indeed, the analysis of the volume fraction of pores (for the part of tensile samples) showed 0.01 vol pct for both AB_t and 530C_t samples (Figure 3). The alignment and the location of pores in the build plane (YZ), as well as the complex shape of lack of fusion defects, can be crucial for the mechanical behavior even if the overall porosity is small.[36] However, in our case, we can safely assume that they do not play a significant role in the mechanical behavior.

Fig. 3
figure 3

Three-dimensional rendering of pores (in red) projected onto the YZ plane (a) AB_t and (b) 530C_t and onto the XZ plane for (c) AB_t and (d) 530C_t. Pores open to the surface are shown with arrows

The diffraction patterns obtained during the in-situ experiments in axial and radial directions for AB_t and 530C_t samples are presented in Figure 4. Their difference gives a footprint of the preferential crystallographic orientation. For the analysis of the elastic response, only reflections present in both directions were considered (indexed in Figures 4(a) and (c)). As expected from the microstructure (Figure 2), a small difference between AB_t and 530C_t samples is visible (see the presence of the 112-reflection in the axial direction in Figure 4(a)), which is due to the small difference in β-phase content (Figure 4(d)). It should be noticed that the β-200 reflection was observed for the 530C_t samples only in one direction and with low intensity; therefore, it will not be discussed in the remainder of the article.

Fig. 4
figure 4

Diffraction patterns obtained during in-situ experiment for sample AB_t (a) in the axial direction and (b) in the radial direction and for sample 530C_t (c) in the axial direction and (d) in the radial direction. Note: Only the reflections present in both directions (indexed in plots (a) and (c)) were considered for further analysis

The pole figures for nine crystallographic planes of α-Ti, calculated from ODF of the AB_t sample, are presented in Figure 5. The as-built and the heat-treated materials show similar texture (Figure 4) so that the texture for the heat-treated material is not reported for the sake of brevity. The pole figures indicate a double fiber texture (with fiber axes 102 and 110), and therefore a transversely isotropic behavior.

Fig. 5
figure 5

Calculated pole figures for α-Ti for the AB_t specimen

For RS determination in engineering components, in most of the cases, the assumption of quasi-isotropy is made and, therefore, only two DECs are used. Therefore, the elastic responses along the axial and radial directions are the most relevant for experimentalists. It is widely reported that the yield stress of AB LPBF Ti-6Al-4V reaches around 900 to 1100 MPa.[37] Therefore, in order to obtain the DEC for each crystallographic family, only the elastic part (up to 600 MPa) of the applied stress vs microscopic strain was analyzed (Figure 6). In the radial direction of the AB_t sample, a mismatch between the start point (unstrained) and the first loading point can be observed (Figure 6(a)): For almost all reflections, a tensile strain is recorded. This behavior is not observed for the heat-treated 530C sample (Figure 6(b)). Therefore, it could be caused by a small amount of RS,[5] which relaxed after the first load step. The shift could be explained also by some initial misalignment of the AB_t sample, successively disappearing as the load is applied. For higher loads, the deformation has a linear behavior as a function of applied stress. Sample AB_c does not present such a behavior. For the 530C_t sample along the axial direction, the two secondary prismatic planes ({210} and {110}) show the lowest slope of the applied stress-microstrain curve. Also, the elastic anisotropy is more pronounced for the 530C_t as compared to the AB_t specimen. In contrast, 530C_c shows almost no scatter among different crystallographic planes along the axial direction but some anisotropy in the radial direction.

Fig. 6
figure 6

Lattice strain evolution for different crystallographic planes during in-situ test for (a) AB_t and (b) 530C_t (tension) and compression test for (c) AB_c and (d) 530C_c (compression). Note the sign of the applied stress and the lattice strain

Due to texture, not every diffraction peak from the pole figures of Figure 5 was observed during the in-situ experiments. For example, no grains of the {002} and {100} families were found to be oriented along the build direction (Figure 5, φ = 0; ψ = 0); i.e., they were not detectable in the in-situ experiment. Moreover, only low intensities for 103 and 101 reflections were detected. Therefore, it was not possible to directly analyze the mechanical response to external stress of basal and first-order prismatic planes.

The connection between diffraction-based microstrain and engineering macrostress is often made by DEC.[11] However, such a concept exists in more general form in micromechanics,[38] where DEC can be viewed as a component of the product of the strain concentration tensor \( \varTheta_{ijmn} \) and the tensor of macroscopic elastic compliances \( S_{mnkl} \) so that \( A_{ijkl} = \varTheta_{ijmn} S_{mnkl} \). The link between microstrain and macrostress becomes, in such formalism,

$$ \left\langle {\varepsilon_{ij} } \right\rangle_{\text{micro}} = < A_{ijkl} > \sigma_{kl} $$
(2)

We introduce the tensor \( A_{ijkl} \) as a SµECT. It connects the elastic behavior of an individual grain with the effective (macroscopic) elastic properties of the specimen (material surrounding the grain). Importantly, SµECT also depends on the morphology of the grains—their shapes and orientations. Such an aspect is usually not considered by models developed to calculate DEC. In Eq. [2], the tensor A is averaged because it is classically defined pointwise, but here, it is applied to the entire gage volume (under the assumption that the diffracting grains represent the gage volume).

In our case, we recorded the axial and transverse response (microstrain) to a uniaxial applied stress, and Eq. [2] rewrites

$$ \begin{array}{*{20}c} {\left\langle {\varepsilon_{ax}^{hkl} } \right\rangle_{\text{micro}} = \left\langle {\varepsilon_{xx} } \right\rangle_{\text{micro}} = < A_{xxxx} > \sigma_{xx} = < A_{\text{ax}}^{hkl} > \sigma_{\text{app}} } \\ {\left\langle {\varepsilon_{\text{rad}}^{hkl} } \right\rangle_{\text{micro}} = \left\langle {\varepsilon_{zz} } \right\rangle_{\text{micro}} = < A_{xxzz} > \sigma_{xx} = < A_{\text{rad}}^{hkl} > \sigma_{\text{app}} } \\ \end{array} $$
(3)

where both the strains and the Aijkl tensor components are hkl dependent. By fitting the experimental data \( d_{\text{ax}}^{hkl} \) or \( d_{\text{rad}}^{hkl} \)vs\( \sigma_{\text{app}} \) with a linear function, the SµECT component \( A_{\text{ax}}^{hkl} \) in the loading direction or \( A_{\text{rad}}^{hkl} \) transverse to it can be calculated by, e.g.,

$$ d_{\text{ax}}^{hkl} = {d_{\text{in}}^{hkl} }{A_{\text{ax}}^{hkl} }\sigma_{\text{app}} + d_{\text{in}}^{hkl} $$
(4)

It must be kept in mind, however, that \( A_{\text{rad}}^{hkl} \) represents different grains than \( A_{\text{ax}}^{hkl} \) (the reflection hkl is generally not caused by the same grains in two perpendicular directions unless very particular reflections are considered). Moreover, due to texture, the response in the radial direction of the same grain can be different from the axial (different constraints from surrounding grains). We will, therefore, focus on the axial response only.

4 Discussion

In the literature, it is common to indicate the inverse of SµECT components (e.g., \( A_{\text{ax}}^{-1} \)) as DEC and calculate them by means of commercial or in-house software, based on Voigt, Reuss, and Kröner schemes.[39] In these models, two assumptions are commonly made: (1) the material is macroscopically isotropic (but individual grains can be anisotropic) and (2) grains are perfectly randomly oriented. Kröner’s model further assumes that grains are spherical. In many structural materials, these conditions may not be fully satisfied and, in fact, some improvements of classic schemes have been proposed to take into account texture and microstructural features.[23,26,40] However, the simplest versions of such models are still widely used by experimentalists for RS calculation, since full information about the material (such as grain morphology and size, texture, and anisotropy) is not always available. By comparing the output of such models with the experimental values of \( A_{\text{ax}}^{-1} \), we can estimate the error associated to the usage of the common approximations for the calculation of RS. Therefore, we calculated the theoretical \( A_{\text{ax}}^{-1} \) values for α-Ti (hcp) using the software XEC[41] (Figure 7). When calculating \( A_{\text{ax}}^{-1} \), it is common to introduce the orientation parameter H2. It defines the direction cosine of the angle between the prismatic {100} and the basal {002} planes, according to the formula

Fig. 7
figure 7

The inverse of SµECT component along the axial direction \( A_{\text{ax}}^{-1} \) as a function of orientation factor H2, as measured (points) and calculated (lines). The magenta lines show the linear fit of the experimental date and ± 5 pct scatter around the mean value. Literature values for conventional Ti-6Al-4V are also reported, taken from Refs. [14] and [17]

$$ H^{2} = \frac{{l^{2} }}{{\frac{4}{3}\left( {\frac{c}{a}} \right)^{2} \left( {h^{2} + k^{2} + hk} \right) + l^{2} }} $$
(5)

As discussed in References 39 and 42, Voigt’s approximation presents no directional dependence of the DEC (on hkl): the inverse of SµECT axial component would get the value \( A_{\text{ax}}^{-1} \) = 117 GPa for all reflections (Figure 7). This causes a difference to experimental values up to 20 GPa (i.e., 15 pct of the experimental values, Figure 7). Voigt’s model yields indeed an estimation of the macroscopic elastic modulus. In fact, Simonelli et al. experimentally obtained a Young’s modulus of 115 ± 6 GPa for Ti-6Al-4V LPBF samples built vertically.[43] Voigt’s scheme in this form is not suited for the calculation of \( A_{\text{ax}}^{-1} \) in diffraction-based RS analysis. It would be equivalent to the use of macroscopic elastic constants (as in Reference 44) for the link between microstrains and macrostresses. This should be avoided, especially in the case of strong anisotropy as commonly linked to materials produced by additive manufacturing processes such as LPBF.

Kröner’s scheme captures the experimental values of \( A_{\text{ax}}^{-1} \) for low Miller indices (or H2 parameters), corresponding to prismatic planes, while the Reuss model yields underestimated DECs. Consistently, for high orientation parameters (corresponding to pyramidal planes), the Reuss model captures the experimental values, while Kröner’s model follows the lower bound of the experimental values (Figure 7). Relevantly, all theoretical schemes capture the experimental values of DEC for LPBF Ti-6Al-4V more precisely than the values reported for conventional Ti-6Al-4V (References 14 and 17). The \( A_{\text{ax}}^{-1} \) difference between conventionally produced and AM Ti-6Al-4V reaches up to 20 GPa (Figure 7). Similar findings have been reported in Reference 16. This effect can be attributed to the different texture and microstructure between the two materials. As mentioned previously, the SµECT automatically includes information about the microstructure (grain morphology and texture). Those two factors are very different for LPBF (martensitic α/α′, Figure 2) and typical forged/wrought Ti-6Al-4V (α + β, Reference 17). In order to capture all effects of texture and microstructure of LPBF materials, more sophisticated theoretical approaches should be used,[23,24,45] moving beyond the classic schemes presented previously. This will be the subject of a companion article.

All experimentally determined \( A_{\text{ax}}^{-1} \) values lie in an interval ± 5 pct from a linear fit of all datapoints (magenta line, Figure 7). The DEC values calculated by the Kröner and Reuss models are also in the range of the experimental scatter. Thus, if a high precision is not required for RS calculations, these models can be used for the calculation of \( A_{\text{ax}}^{-1} \) in LPBF Ti-6Al-4V as a first approximation. We observe that the precision can be even improved by considering low or high H2 (Reuss model agrees with the data for low H2, Kröner’s for high H2). However, \( A_{\text{ax}}^{-1} \) of each single specimen has an experimental scatter of less than ± 5 pct. Therefore, for a precise calculation of RS, the \( A_{\text{ax}}^{-1} \) of the specific condition (tension/compression or heat treatment) should be taken.

In fact, the inverse of SµECT component \( A_{\text{ax}}^{-1} \) for compression specimens appears almost systematically larger than that for tensile (Figures 8(a) and (b)). The two sets of samples (with and without heat treatment) show a similar behavior, and the largest difference occurs for prismatic planes (at H2 = 0, Figures 8(a) and (b)). To estimate the tension/compression asymmetry at the macroscopic level, the average (or equivalent) elastic strain \( \left\langle \varepsilon \right\rangle \) (as proposed by Reference 46) was calculated as

$$ \left\langle \varepsilon \right\rangle = \frac{{\mathop \sum \nolimits_{hkl} \varepsilon_{hkl} f_{hkl} }}{{\mathop \sum \nolimits_{hkl} f_{hkl} }} $$
(6)

where \( f_{hkl} \) is the fraction of grains with orientation \( \langle{hkl}\rangle \). This fraction depends on the direction inside the specimen, i.e., on the angle ψ of the specimen inclination to the scattering vector. \( f_{hkl} \left( \psi \right) \) can be extracted from the texture measurements (pole figures, Figure 5) using the texture intensity (\( I_{hkl}^{{}} \left( \psi \right) \)) of every reflection and weighting it by its multiplicity \( m_{hkl} \) (note that nine peaks were used for this calculation):

Fig. 8
figure 8

The inverse of SµECT component \( A_{\text{ax}}^{-1} \) as a function of the orientation factor H2 for (a) AB and (b) for 530C. (c) Volume fraction of diffracting hkl grains as a function of the azimuth angle ψ, and (d) the applied stress as a function of mean lattice strain curves for tension and compression

$$ f_{hkl} \left( \psi \right) = \frac{{I_{hkl}^{{}} \left( \psi \right)m_{hkl} }}{{\mathop \sum \nolimits_{hkl = 1}^{9} I_{hkl}^{{}} \left( \psi \right) \cdot m_{hkl} }} $$
(7)

Since the material presents a double fiber texture (Figure 5), the pole figures can be integrated along φ and the ODF depends only on the angle ψ. This calculation yields the dependence of \( f_{hkl} \left( \psi \right) \) on the tilt angle with respect to the sample long direction or, in other words, the azimuthal distribution of the fractions of a crystallite family from the axial to the radial directions (Figure 8(c)). \( f_{hkl} \left( 0 \right) \) is the necessary quantity for the calculation of the axial average lattice strain (Figure 8(d)).

Using Eq. [6], we obtain that the average \( A_{\text{ax}}^{-1} \) is higher for compression by around 5 GPa for both AB and 530C samples (Figure 8(d)). One of the reasons for this difference can be defects and their orientation. As observed in Figure 3, and reported in the literature,[47,48,49] LPBF materials often present a lack of fusion defects (crack-like) aligned perpendicular to the building direction (Figures 3(c) and (d)). During a compression test along the building direction, such defects are expected to (mechanically) close, while under tension, they should open and even propagate. A similar behavior is observed in microcracked ceramics.[50] However, in that case, the crack density is much larger and the difference between the slopes of the stress-strain curves in tension and compression is more obvious than in the present study. According to CT images, the volume fraction of pores (within the CT resolution limit) reached only around 0.01 pct (Figure 3). While porosity and crack density are not directly linked (cracks have negligible volume), we can estimate the crack density to be low also in our LPBF Ti-6Al-4V samples.

5 Conclusions

The connection between macroscopic stress and diffraction (micro-) strain was made by the SµECT, well known in micromechanics. We experimentally determined two components of the SµECT by in-situ SXRD in LPBF Ti-6Al-4V. We compared experimental data with the output of the classic models (Voigt, Reuss, and Kröner) used to calculate the so-called DECs. We concluded the following:

  1. 1.

    The usage of Voigt’s model is equivalent to that of the macroscopic elastic constants, so that it should be avoided for diffraction-based residual stress determination in materials with high anisotropy.

  2. 2.

    A large difference of DECs (or axial SµECT\( A_{\text{ax}}^{-1} \)) between AM and wrought Ti-6Al-4V exists. This is attributed to texture and microstructural differences.

  3. 3.

    Acceptable agreement between experimental \( A_{\text{ax}}^{-1} \) and the Kröner or Reuss model (assuming isotropic microstructure) was found. However, a more appropriate model capturing microstructural features (e.g., grain size and shape) and texture should be developed.

  4. 4.

    In the case of complex or new materials, the experimental determination of SµECT is necessary.

  5. 5.

    A tension-compression asymmetry of both the microstrain and average macrostrain curves vs applied stress was observed and possibly attributed to the presence of the lack of fusion/crack-like defects, detected in computed tomography reconstructions.

Finally, for the sake of reproducibility and traceability of the results, we recommend explicit reporting of the DECs (or the SµECT components) used for residual stress calculations. Failing to do so would render it impossible to compare or benchmark different measurements (e.g., bulk or surface stress or studies of process parameter variation) and draw general conclusions about the residual stress state in LPBF parts.