Additive manufacturing of steels: a review of achievements and challenges

Given their unique microstructures, AM austenitic stainless steels show interesting behaviour in tensile testing different from the conventionally produced parts. For instance, LPBF has shown to produce 316L stainless steel that is stronger than its wrought/cast counterpart (ultimate tensile strength (UTS) of 640–700 MPa for LPBF compared to 450–555 MPa for conventional; yield strength (YS) of 450–590 MPa for LPBF compared to 160–365 MPa for conventional) while still remaining ductile (elongation of 36-59% for LPBF compared to 30-43% for conventional) [50, 51]. An example of such superior tensile properties for LPBF 316L stainless steel compared to its conventional counterpart is presented in Fig. 3a. This is mainly attributed to the presence of numerous nano-inclusions that hinder dislocation movements, and a large density of low angle grain boundaries. The exceptional combination of strength and ductility in 316L austenitic stainless steel is a great achievement for AM considering the limitation of conventional manufacturing in overcoming the strength–ductility dilemma [50, 51].

There are reports on LPBF 316L austenitic stainless steel showing a good fatigue performance, comparable to its conventionally processed counterpart [52]. LPBF 304 austenitic stainless steel also exhibits a comparable fatigue resistance in high-cycle regimes and an even slightly higher fatigue resistance in low-cycle-fatigue regimes [53], as presented in strain-life fatigue curves in Fig. 3b. AM 316L stainless steel has been shown to have a better wear resistance than its conventional counterpart at room temperature under dry sliding conditions and to even maintain this trend at high temperatures up to 400 °C [54], as depicted in the coefficient of friction versus sliding distance curves in Fig. 3c, d. This is attributed to the role of the cellular sub-grains within the microstructure of the AM 316L austenitic stainless steel in resisting against subsurface deformation through hindering dislocation movement. A similar conclusion has been made for better tribological behaviour of LPBF 316L austenitic stainless steel under wet wear test in a simulated body solution [28].

It is generally accepted that the corrosion properties of stainless steels are dependent on their microstructure and chemical composition. Phases such as δ-ferrite, metallic/non-metallic inclusions and precipitates in the steel can all affect its corrosion resistance. The effects of microstructural features of AM stainless steel, which are in turn dependent upon the AM processing conditions, on their corrosion characteristics will be discussed in the following.

Sulphide inclusions, particularly manganese sulphide (MnS), are detrimental to pitting corrosion resistance of all grades of stainless steels [55‐57]. Elimination of such harmful MnS inclusions is not practical in conventional subtractive manufacturing, since S is generally added to stainless steel as an alloying element with the aim of improving machinability [58]. Changing the chemical composition of MnS inclusions, e.g. by replacing Mn in the sulphide by Cr, has been shown to be a useful method in enhancing the pitting corrosion resistance though not in severe corrosive environments like ferric chloride solutions [59]. Reducing the size of MnS inclusions through rapid solidification [60] or laser surface re-melting [61] has also been found to improve the pitting corrosion resistance. In this respect, AM has been shown to be capable of producing austenitic stainless steels with excellent pitting corrosion resistance [62, 63], as presented in Fig. 4a. This is mainly attributed to the rapid solidification inherent to AM that limits the formation of MnS inclusions [64, 65].

Given the excellent pitting corrosion resistance and high hardness and wear resistance, as discussed previously, AM austenitic stainless steel is expected to exhibit an enhanced erosion-corrosion resistance compared to its conventional counterpart. However, Laleh et al. [63] report an unexpected lower erosion-corrosion resistance for LPBF 316L austenitic stainless steel (Fig. 4b), which is due to the weaker repassivation ability in LPBF 316L austenitic stainless steel compared to its conventionally processed counterpart. This is in good agreement with other studies [62, 66, 67]. The mechanism behind this behaviour is still unclear; however, the presence of internal porosities and the inhomogeneous microstructure of AM steel are supposed to be the major factors. In this regard, a recent study by Kong et al. [68] shows a similar repassivation potential for LPBF 316L austenitic stainless steel to its conventional counterpart by eliminating the porosity content (< 0.03 vol%).

Intergranular corrosion (IGC) of stainless steel is a localised form of corrosion that proceeds along the grain boundaries and usually happens during exposure to high temperatures (between 500 and 800 °C) or welding [69, 70]. Formation of secondary precipitates like Cr-rich carbides, σ and χ phases along the grain boundaries leaves the adjacent areas more susceptible to corrosion during subsequent exposure to corrosive environments. IGC of AM stainless steel is still under dispute. Some studies report an accelerated interfacial corrosion in LPBF 316L [71, 72] while some others show an opposite behaviour [36]. The enhanced IGC resistance of the LPBF 316L austenitic stainless steel (Fig. 4c–g) is attributed to the presence of a large volume of low angle grain boundaries and twin boundaries [36], which are believed to be not susceptible to IGC. The existing disagreement in the IGC behaviour of AM stainless steels could be related to the sensitisation conditions (heat treatment temperature, cooling conditions) and/or IGC test method.

It has been shown that LPBF 316L austenitic stainless steel has a superior hydrogen damage resistance compared to its conventional counterpart [73], indicating that LPBF 316L austenitic stainless steel could be an option for using in hydrogen fuel cells. This behaviour is mainly attributed to the lower degree of austenite to martensite transformation and, thus, lower volume fraction of martensite in LPBF 316L austenitic stainless steel upon exposure to 4 h hydrogen charging, as the martensite phase has a poorer corrosion resistance than austenite in these steels. A similar conclusion has been made by Baek et al. [74] who report a higher resistance to hydrogen embrittlement under high-pressure H atmosphere for AM 304L austenitic stainless steel compared to its conventional counterpart, which is mainly discussed based on the stability of the austenite phase that does not transform to martensite phase under load stress. These results indicate an ability of the AM austenitic stainless steel to resist again phase transformation during H charging; however, the mechanism behind this phenomenon is still not clear in the literature and needs to be clarified in future work.

Despite the above-mentioned promising properties offered by AM, there are still many important challenges inherent to AM of austenitic stainless steels that hinder their widespread industrial application. The most important challenges that AM currently encounters in austenitic stainless steels manufacturing will be reviewed in the following. They include residual stresses, anisotropy, formation of pores and post-processing via heat treatments.

The sharp thermal gradients associated with AM generate large residual stresses that cause part distortion [75, 76]. This will subsequently affect mechanical properties, decrease the stress corrosion cracking resistance [77‐79] or even deteriorate final geometry [80] of the parts. Preheating the build substrate or feedstock material is the most common way to decrease temperature gradients and, thus, reduce residual stresses [81]. Controlling the scanning strategy is another approach to reduce residual stresses [82‐84]. Other than these ‘in situ’ methods for controlling residual stresses, heat treatment post-processing has also been reported to be beneficial in terms of releasing residual stresses [85].

Anisotropy in AM is a critical issue and can be categorised into two types: first, anisotropy that arises from building a part in different directions and second, anisotropy that arises from property measurements along different axes. It has been well understood that the building direction (the acute angle between the long axis of the fabricating part and the horizontal plane) can cause anisotropy in the microstructure and mechanical properties of AM austenitic stainless steel parts [86‐88]. The columnar grain structure and strong crystallographic texture along the building direction have been known as major contributing factors to anisotropy in the mechanical properties of AM austenitic stainless steel parts [89]. For instance, it has been shown that the UTS in horizontally built specimens (loading direction parallel to the layers in the microstructure) is almost 20% higher compared to that of the vertically built specimens [88]. This behaviour is related to the preferential formation of defects between the successive layers during AM fabrication, which thereafter results in a decreased strength when the loading direction is perpendicular to the layers. Anisotropy has not been reported as a critical issue in corrosion properties of AM austenitic stainless steel as long as high-density specimens are produced. The focus in the literature is on the response of the different planes (i.e. transverse and building planes) against various kinds of corrosion, and most of the studies report similar corrosion characteristics in terms of pitting [27, 67, 90] and intergranular [36] corrosion resistances at all planes. It has also been shown that the building direction does not have a significant influence on the tribological performance of the LPBF 316L austenitic stainless steel under dry sliding wear test [91].

Different types of pores have been reported in AM austenitic stainless steels [41, 67‐73]. LOF pores are shown to be more detrimental to wear properties [66, 92, 93], fatigue resistance [94, 95] and corrosion resistance [96‐98] than spherical gas pores, since they act as the crack initiation site during tensile testing and pit formation site upon immersion in a corrosive environment. Examples of pit development at the sites of LOF pores in AM austenitic stainless steels when subjected to corrosive environments are presented in Fig. 5, indicated by potentiodynamic polarisation tests and three-dimensional computed tomography analysis. They show that the pitting corrosion resistance will decrease in the presence of LOF pores because of their susceptibility to act as the pit formation sites. Spherical gas pores have also been classified as open and covered pores based on their geometry at the top external surface. Open spherical gas pores are found to be less susceptible to stable pit formation compared to the semi-covered ones, which is attributed to the differences in the ions diffusion rates upon exposure to corrosive environments [99].

Interaction between the heat source and feedstock material during AM leads to a large number of rapid heating and cooling cycles, which might result in a microstructure far from the equilibrium conditions. In this regard, post-processing treatments including stress relief heat treatment and hot isostatic pressing (HIP) have been commonly used to eliminate these issues. Current standards for the heat treatment of austenitic stainless steels have all been developed for the cast and wrought materials and not optimised for AM parts. Examining the effect of such heat treatments on the properties of the AM parts and optimising heat treatment routes for AM products is therefore essential.

As an example, in terms of corrosion properties, solution annealing heat treatment at a temperature range between 1010 and 1120 °C has generally been used for conventional austenitic stainless steel to increase corrosion resistance through dissolving carbides into the solid solution of the γ matrix [100, 101]. A summary of dependence of pitting potential for LPBF 316L austenitic stainless steel on the post-processing heat treatment is presented in Table 1. This table summarises a wide range of post-processing heat treatments (temperature, holding time and cooling conditions) used in the literature. In most of cases, heat treatment above 1000 °C leads to a decrease in the pitting corrosion resistance, suggesting that the commonly used solution annealing heat treatment for conventional austenitic stainless steels may not be applicable for AM 316L austenitic stainless steel.

It has been shown that heat treatments at temperatures above 1000 °C drastically decrease the pitting corrosion resistance [64, 68, 102], indicating that such heat treatments are not practical for AM austenitic stainless steel in applications where high resistance to pitting corrosion is required. There is still no agreement on the mechanism behind the drastic decline in pitting corrosion resistance after subjecting to temperatures above 1000 °C, although some authors believe that formation of detrimental MnS inclusions is responsible for this phenomenon [64] while others propose that release of compressive residual stresses leads to such behaviour [102]. Apparently, a heat treatment at high temperatures leads to the partial/complete transformation of some existing inclusions to inclusions with different chemical compositions, and even the formation of some new inclusions that were not present in the as-built condition [48, 64]. The mechanism behind the inclusion transformation under such high-temperature heat treatments remains unclear.

For simplicity, the American Society for Metals (ASM) standard wrought tensile properties for the alloys discussed in this section are presented in Table 2 for comparison to the properties exhibited by AM produced parts of these steels.

Duplex stainless steels (DSSs) have microstructures of essentially equal fractions of δ-ferrite and austenite. This unlocks a wide range of attractive properties such as high strength, good ductility and excellent corrosion resistance for applications in oil & gas, petrochemical, construction, marine, and desalination [177]. The current challenge with DSSs is their complex microstructural evolution where various further deleterious phases may be precipitated during multistep conventional processing, impacting the properties of these steels. AM can overcome the current challenges inherent to complex multistep traditional processing of DSSs. Most of the work published until now on AM of DSSs is on the microstructure evolution during AM and post-heat treatment of 2205 and 2507 grades. 2205 is the most common grade of duplex stainless steels, containing 22% Cr, 3.2% Mo and 5% Ni (wt%), offering high strength, good weldability and excellent pitting and crevice corrosion resistance. 2507 is a super-duplex stainless steel, containing 25% Cr, 4% Mo and 7% Ni (wt%), that possesses an excellent combination of strength and corrosion resistance. This makes it an ideal candidate for aggressive environments such as warm seawater and acids for examples in offshore oil & gas infrastructures [178]. Two types of the AM methods, i.e. LPBF and DED have mainly been employed for DSSs. The microstructures obtained through these techniques have been reported to be different. LPBF parts show mostly a ferritic microstructure with high strength but poor ductility, necessitating further heat treatments, while DED-produced ones exhibit a considerable fraction of austenite offering higher ductility at the expense of strength. This is mainly due to the significant difference in the cooling rates between these two processing methods.

Different grades of low-carbon ferritic and martensitic steels can be processed by AM for applications where wear and corrosion resistance are needed. These include parts such as medical tools, bearings and blades as well as pumps, valves and shafts. It has been shown that AM products can achieve tensile strength, corrosion and magnetic properties equivalent or superior to those of wrought and conventionally processed samples. Poor ductility and toughness as well as anisotropy are, however, the remaining challenges with AM of these steels. One of these steels that has been studied in the context of AM is grade 420, a general-purpose medium C martensitic stainless steel with excellent hardenability and acceptable corrosion resistance. For example, an improvement in both tensile properties and corrosion resistance of 420 stainless steels in both AM and post-heat-treated conditions has been observed with the addition of Nb and Mo [187]. A summary of comparison of Nb/Mo AM 420 steel with the AM 420 steel without Nb/Mo and wrought 420 steel is given in Table 3. The enhancement of the mechanical properties is attributed to the formation of a martensitic microstructure containing nanoscale carbide such as NbC. Such phases are not observed in the AM 420 stainless steel without Nb/Mo.

High strength is achievable also for 420 stainless steel via LPBF (UTS of 1670 MPa, YS of 600 MPa and elongation of 3.5%) [188]. The UTS achieved is much higher than the value reported for the wrought material (800 MPa). The elongation is, however, lower than wrought 420 stainless steel. A post-AM tempering heat treatment at 400 °C for 15 min can yield an extremely high UTS of 1800 MPa and YS of 1400 MPa. Tempering also enhances the elongation to ~ 25% that is about 5 times of elongation in the LPBF condition. The enhanced mechanical properties is attributed to the transformation of retained austenite to martensite during tensile testing. Similarly, there are also observations of higher YS and UTS in LPBF 4140 steel compared to the wrought steel in both building and normal to building directions without compromising ductility and impact toughness [189].

Post-AM heat treatment can significantly affect the mechanical performance of some other grades of martensitic/ferritic steels. For instance, as shown by Sridharan et al. [190] for both HT9 (a 12%Cr–1%Mo martensitic stainless steel widely used in turbines and boilers in fossil-fired power plants and nuclear energy systems) [191] and P91 ferritic-martensitic steel (9%Cr–1%Mo steel mostly used in nuclear fission reactors) [192], a post-heat treatment reduces the YS and UTS but improves the ductility, at room and warm working temperatures (330 and 550 °C). As another example, Liu et al. [193] reports that the impact toughness of an AM 300 M ultra-high strength steel (a modified version of 4340 steel with Si added to enhance hot working) is extremely low (9 J/cm²), while a post-deposition heat treatment can recover the toughness to ~ 25 J/cm². The extremely low toughness in the as-built condition is attributed to the coarse size of ‘effective microstructure unit’ where coarse epitaxial primary austenite columnar grains result in coarse martensite packets in the as-deposited condition. In another study by Sridharan et al. [194], AM HT9 steel shows superior tensile properties (YS = 1043 MPa, UTS = 1168 MPa and elongation at fracture = 14.2%) compared to its wrought counterpart (YS = 800 MPa, UTS = 950 MPa and elongation at fracture = 10–16%). A post-process heat treatment of the AM samples results in properties in the range of normalised and tempered HT9. This is mainly because a higher austenitising temperature and a lower tempering temperature results in a fine dispersion of the carbide structure and a fine-grained lath martensite, maximising tensile properties.

Thermal cycles during AM may result in unexpected microstructures. For instance, in an LPBF 24CrNiMoY steel, with an increase in the number of thermal cycles, the microstructure changes from a martensitic one to a bainitic one [195]. For the bainitic microstructure, the laser energy density significantly affects the microstructure and mechanical properties. Decreasing the laser energy density from 210 to 140 J/mm³ reduces the bainite lath width from 1.7 to 0.6 μm. A general Hall–Petch like trend of increasing the YS with decreasing bainite lath size is, in turn, observed. Promising tensile properties with about 5–10% improvement compared to the as-cast material can be achieved in 24CrNiMo steel fabricated via DED, too [196]. Interestingly, the substrate temperature during DED can significantly change the microstructure constituents, texture and grain size. With the increase of substrate temperature from RT to 400 °C, the microstructure changes from fully martensitic to a mixture of martensite and lower bainite. Correspondingly, grain size (texture intensity) decreases from 30 μm (16.0) to 13 μm (4.7).

Promising microstructure and tensile properties can be achieved in reduced activation ferritic/martensitic (RAFM) steel (used mainly as structural material for fusion reactors [197]) produced by LPBF using two scanning strategies of (1) bidirectional scanning without and (2) with 45° deviation from X/Y-axis and 90° rotation [198]. Both strategies result in advanced tensile properties of YS = 893–911 MPa, UTS = 1008–1047 MPa and elongation = 15.0–18.7%, which is a much higher combination compared to that in LPBF China low activation martensitic steel [199] and conventionally processed RAFM steels [200]. The enhanced strength is attributed to the grain refinement, and the acceptable ductility is ascribed to morphology of grains that change the fracture mode to transgranular ductile. A very interesting change in the grain morphology of the steel (from columnar-like to rhombus-shaped) is observed with the change of scanning strategy (Fig. 16), though these changes do not profoundly affect the strength.

The inhomogeneity and the in situ heat treatment inherited from the AM can be used as a means to enhance mechanical properties of martensitic/ferritic steels. For example, as reported by Jiang et al. [201], LPBF can be used to create a heterogeneous multi-/bimodal microstructure in a RAFM S209 steel resulting in superior properties of YS of 1053 MPa and elongation of ~ 17%. This is mainly attributed to the refined grains and fine martensite laths as a result of increasing the energy density during LPBF, which decreases the temperature gradient facilitating the formation of fine equiaxed grains.

AM can result in advanced properties in 24CrNiMoY steel, too [202]. The strength of AM 24CrNiMoY parts are mainly controlled by the size of the bainitic laths where the finer the bainitic ferrite lath bundle, the higher the YS [202]. The excellent hardness and tensile properties of this alloy in the LPBF condition is attributed to the dominance of supersaturated solid solution, dislocation and subgrain cell structures in the microstructure.

It is worth noting that there have also been reports showing poor mechanical properties of ferritic/martensitic steel AM products compared to the wrought samples. For example, ultra-high-strength martensitic stainless steel AerMet100 processed with DED shows lower tensile strength and ductility than its wrought counterpart [203]. There is also an anisotropy in tensile properties especially in elongation where longitude (L) direction showed 12.3% elongation while transverse (T) direction only showed 4.6%. This is justified considering the applied tensile stress being perpendicular to the prior austenite grain boundary (locations prone to crack propagation) in T-direction. At the L-direction, however, the applied tensile stress was parallel to the grain boundary causing high crack propagation resistance through grain interior bainitic microstructures. An anisotropy has also been observed in the UTS and elongation of China Low Activation Martensitic steel processed by LPBF [199]. The tempering of the martensitic structure resulted from LPBF enhances ductility at the expense of strength. The LPBF steel shows a low impact toughness of 10 J which is less than 5% of that of the same steel in the wrought condition.

Silicon steels have also been processed by AM showing promising magnetic properties. While conventional processing is limited to electrical steels of less than ~ 3.5 wt% Si due to workability limitations, Garibaldi et al. [204] report that a Fe-6.9 wt% Si can be successfully produced by LPBF. This is outstanding as the electrical resistivity, and hence power losses, scale strongly with the Si content. Post-AM annealed parts can achieve excellent quasi-static magnetic properties (maximum relative permeability of 24,000 and coercivity of 16 A/m) which is as good as commercial high Si electrical steels such as JNEX Super Core developed by JFE Steel [204]. This has obvious benefits for processing novel core geometries, especially in applications where complex geometrical core design is advantageous, while the employment of a laminated core is not viable due to structural integrity concerns or is not strictly necessary (e.g. in some synchronous rotor cores). This behaviour is attributed to stress relief (up to 900 °C) and grain growth (900–1150 °C) that reduce the density of lattice defects. Lattice defects are known to hinder magnetic domain wall motion through a pining effect [204].

HSLA steels have been successfully processed via AM for different applications such as tooling industries and defence. Their properties have been reported to be affected by the laser energy density and the distance from the substrate. For example, as shown by Jelis et al. [205], for AM HSLA steels used in defence applications, a desirable fine martensitic structure as a result of the rapid cooling of the melt pool can be achieved. The porosity increases and the morphology of the pores becomes more irregular as the energy density is decreased, which in turn increases the propensity to cracking. The brittle martensitic microstructure of the component may also contribute to cracking as the components show a slightly higher brittleness at lower energy densities. Another example of successful AM of HSLA has been reported by Rodrigues et al. [206] who have processed HSLA steel with WAAM. This method of AM is, however, outside the scope of this review.

Tool steels are a family of high C and alloy steels comprising carbide-forming elements such as Cr, V, Mo and W that are used to make tools such as drills, hobs, punches, dies, etc. These steels are of excellent hardness, wear resistance and resistance to high-temperature softening. They are usually heat treated to achieve a hard matrix with a dispersion of both coarse and fine carbides, providing improved wear resistance and hot hardness [207]. In general, AM processing of these steels is challenging. Firstly, these steels are of high strength and low toughness that makes them susceptible to cracking during cooling down. Furthermore, it has been reported that C in these steels can segregate to the melt surface, reducing wettability [208]. This together with the severe thermal gradient during AM result in thermal stresses, that leads to cracking [209]. Despite such challenges, there are reports on successful AM of these steels in the literature.

During AM, due to the high cooling rate, these steels solidify as martensite supersaturated in C and retained austenite. Every solidified layer is, however, affected by melting and heating of the neighbouring layers. In the case of an overlap, solidified layers can be remelted multiple times by the melting of adjacent tracks. If a layer is distant from the melt pool, it might be heated to temperatures above austenite transformation temperature, but not melting point. This will cause reaustenitisation of martensite. Distant further from the melt pool, the heat will be only enough for tempering of martensite, carbon partitioning and carbide precipitation. This implies that the retained austenite, martensite and carbide characteristics all depend on the heating/cooling cycle that each part of the build experiences during AM.

TRIP/TWIP steels are attractive due to their high work hardening rates, making them ideal candidates for applications such as automotive and defence where a high post-yield plasticity and energy absorption capacity is desired. These steels are basically austenitic and go through twinning and/or a martensitic phase transformation during deformation. There are only few papers focusing on the TRIP and TWIP effects in AM-processed austenitic base steels. Most of these works show enhanced tensile properties mainly due to the opportunities existing in AM to locally change the chemistry and in turn stacking fault energy that controls the deformation mechanism.

Heterogenous (location dependent) TRIP and TWIP effects can be observed in DED high Mn steel due to the heterogeneity in the chemical composition that affects the stacking fault energy and the dominant deformation mechanism (Fig. 19) [231]. This is in contrast to what is observed in the same alloy produced via conventional processing or LPBF. Notably, such heterogeneity does not affect the macroscopic deformation behaviour. It has also been found that increasing the Al content during DED decreases the work hardening rate. This is mainly due to an increase in the stacking fault energy with Al content that shifts the deformation mechanism from twinning to the cross-slip. Through site-specific change in the chemical composition during AM, one can induce site-specific deformation mechanisms. For example, X30MnAl23‐1 is of a chemical composition that yields a stacking fault energy value low enough to activate the TWIP effect only while avoiding the TRIP effect. This results in high specific energy absorption and predictable compressive deformation behaviour as no brittle martensite is formed during straining. Such capabilities to design microstructures and in turn micro-deformation mechanisms are promising for high Mn steel, considering the difficulties associated with their conventional processing.

Other studies show that high Mn steels processed with LPBF possess strength levels higher than the conventionally processed steels at the expense of elongation [232]. The presence of ε- and α’-martensite as well as the high density of dislocations provide high strength while porosities and impurities typical of AM deteriorate the formability. The same work hardening rate is achieved for these steels irrespective of their fabrication route, with both TWIP and TRIP effects. An anisotropy in the tensile properties of these AM steels is, however, observed which is mainly due to the anisotropic texture and elongated grain morphology. The TRIP effect can impart a surprisingly high elongation to a LPBF 304L steel despite the observation of porosities [233]. Such excellent ductility is due to a secondary hardening effect by the martensite formed during tensile deformation, as martensite can accommodate more load compared to austenite, resulting in an increased plasticity.

The TWIP effect can be activated in LPBF 316L austenitic stainless steel [234]. This has been attributed to the role of N that decreases the stacking fault energy of 316L steel into the TWIP region. Twinning-induced plasticity can override the detrimental effect of porosity and other defects on ductility of AM samples. The synergy between the TWIP effect and the high strength resulting from hierarchical fine subgrains can offer new windows for AM austenitic stainless steels. Generally, the TRIP effect is a main factor in advanced properties of AM tool steels and PH/maraging steels with significant volume of retained austenite. This has been discussed in sections on tool steels and PH/maraging steels.