Unusual solute segregation phenomenon in coherent twin boundaries

He, Cong; Li, Zhiqiao; Chen, Houwen; Wilson, Nick; Nie, Jian–Feng

doi:10.1038/s41467-021-21104-8

Cited by 72 publications

(26 citation statements)

References 50 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In contrast, coherent TBs are dislocation-free and have perfectly aligned atomic stacks, resulting in low interfacial energies compared to grain boundaries; thus, strong solute segregation is not initially expected at coherent TBs. However, several recent reports on different alloy systems have shown solute segregation along TBs and proved it is associated to the migrating heterophase interface boundary, driven by minimizing the intrinsic stacking fault, elastic strain, and/or total energy in the system 20 – 22 . On the other hand, it is also worth notice that solutes accumulation at the TBs can also act as Cottrell clouds surrounding the twins and thereby restrict further slip of the dislocations which was well discussed as the strength enhancement mechanism for the twinned soft materials 23 – 25 .…”

Section: Resultsmentioning

confidence: 99%

Massive transformation in FeNi nanopowders with nanotwin-assisted nitridation

Wang

Hirayama

Liu

et al. 2022

Sci Rep

View full text Add to dashboard Cite

L10-ordered FeNi alloy (tetrataenite), a promising candidate for rare-earth-free and low-cost permanent magnet applications, is attracting increasing attention from academic and industrial communities. Highly ordered single-phase L10-FeNi is difficult to synthesis efficiently because of its low chemical order–disorder transition temperature (200–320 °C). A non-equilibrium synthetic route utilizing a nitrogen topotactic reaction has been considered a valid approach, although the phase transformation mechanism is currently unknown. Herein, we investigated the basis of this reaction, namely the formation mechanism of the tetragonal FeNiN precursor phase during the nitridation of FeNi nanopowders. Detailed microstructure analysis revealed that the FeNiN precursor phase could preferentially nucleate at the nanotwinned region during nitridation and subsequently grow following a massive transformation, with high-index irrational orientation relationships and ledgewise growth motion detected at the migrating phase interface. This is the first report of a massive phase transformation detected in an Fe–Ni–N system and provides new insights into the phase transformation during the nitriding process. This work is expected to promote the synthetic optimization of fully ordered FeNi alloys for various magnetic applications.

show abstract

Section: Resultsmentioning

confidence: 99%

Massive transformation in FeNi nanopowders with nanotwin-assisted nitridation

Wang

Hirayama

Liu

et al. 2022

Sci Rep

View full text Add to dashboard Cite

show abstract

“…In contrast, coherent TBs are dislocation-free and have perfectly aligned atomic stacks, resulting in low interfacial energies compared to grain boundaries; thus, strong solute segregation is not initially expected at coherent TBs. However, several recent reports on different alloy systems have shown solute segregation along TBs and proved it is associated to the migrating heterophase interface boundary, driven by minimizing the intrinsic stacking fault, elastic strain, and/or total energy in the system [20][21][22] . On the other hand, it is also worth notice that solutes accumulation at the TBs can also act as Cottrell clouds surrounding the twins and thereby restrict further slip of the dislocations which was well discussed as the strength enhancement mechanism for the twinned soft materials [23][24][25] .…”

Section: Resultsmentioning

confidence: 99%

Nanotwin-assisted nitridation in FeNi nanopowders for synthesis of rare-earth-free magnets

Wang

Hirayama

Lei

et al. 2021

Preprint

View full text Add to dashboard Cite

L10-ordered FeNi alloy (tetrataenite), a promising candidate for rare-earth-free and low-cost permanent magnet applications, is attracting increasing attention from academic and industrial communities. Highly ordered single-phase L10-FeNi is difficult to synthesis efficiently because of its low chemical order-disorder transition temperature (200–320 ℃). A non-equilibrium synthetic route utilizing a nitrogen topotactic reaction has been considered a valid approach, although the phase transformation mechanism is currently unknown. Herein, we investigated the basis of this reaction, namely the formation mechanism of the tetragonal FeNiN precursor phase during the nitridation of FeNi nanopowders. Detailed microstructure analysis revealed that the FeNiN precursor phase could preferentially nucleated at the nanotwinned region during nitridation and subsequently grew following a massive transformation, with high-index irrational orientation relationships and ledgewise growth motion detected at the migrating phase interface. This is the first report of a massive phase transformation detected in an Fe-Ni-N system and provides new insights into the phase transformation during the nitriding process. This work is expected to promote the synthetic optimization of fully ordered FeNi alloys for various magnetic applications.

show abstract

“…21,23−25 size larger than the matrix atom tends to take the extension site and the smaller one segregates favorably to the compression site, 21,34−37 and it can thus be understood as the larger/smaller solutes replacing the matrix atoms at the extension/ compressive sites, respectively, can minimize the strain in the lattice. However, recent results showed that larger size solutes segregated to the compression sites of {101̅ 1} TBs in Mg−Bi and Mg−Pb binary systems, 27 meaning that chemical bonding also played an indispensable role in determining the segregation behaviors. Additionally, what should be emphasized here is that the elastic strain minimization principle dominated by the atomic size effect requires that all the alternately distributed extension/compression sites in the coherent TBs should be occupied by larger/smaller solutes in an orderly and continuous manner, and all the TB 1g) and the corresponding EDS mapping images related to the elements Mg (Figure 1h), Nd (Figure 1i), and Mn (Figure 1j).…”

mentioning

confidence: 99%

“…Interfaces, including grain boundaries (GBs), phase boundaries, domain boundaries, twin boundaries (TBs), etc. , are ubiquitous crystal planar defects in materials and play a decisive role in their properties. − Generally, in materials containing more than one element, the segregation of impurities/solutes at such interfaces driven by the reduction of interfacial energy can significantly alter the performances, such as cohesion, mobility, thermostability, and strength. ,− A typical example is the catastrophic brittle intergranular failure of metals, which is caused by the diffusion of certain elements into the boundary core. ,, The segregation behaviors at interfaces were described by the early Langmuir–McLean segregation theorem, , and it was assumed that one-layer/sub-one-layer coverage of an interface, without any solute interactions or structural transformations, nor multilayer segregation or additional solute enrichment within the bulk, e.g., precipitations, which had been demonstrated in many special interfaces, including artificial bicrystal boundaries ,− and coherent TBs. − …”

mentioning

confidence: 99%

“…Twinning is a prevalent deformation mechanism in metals usually with a limited number of active slip systems. , TBs generated by twinning during plastic deformation are special dislocation-free high-angle tilt GBs, and with a lower interfacial energy than general GBs . In hexagonal close-packed (hcp) metals, such as Mg, Ti, Zn, and Zr, there are three main types of TBs commonly observed experimentally, i.e., {101̅1}, {101̅2}, and {101̅3}. − The segregation of solutes in these coherent TBs is not considered possible due to low interfacial energy characteristic, until such TB segregation phenomenon was first found in Mg alloys by Nie et al TB segregation is commonly considered to be effective in enhancing the strength of materials and the thermal stability of interfaces, etc . , …”

mentioning

confidence: 99%

See 1 more Smart Citation

Twin Boundary Superstructures Assembled by Periodic Segregation of Solute Atoms

et al. 2021

View full text Add to dashboard Cite

Twinning is a common deformation mechanism in metals, and twin boundary (TB) segregation of impurities/solutes plays an important role in the performances of alloys such as thermostability, mobility, and even strengthening. The occurrence of such segregation phenomena is generally believed as a one-layer coverage of solutes alternately distributed at extension/compression sites, in an orderly, continuous manner. However, in the Mnfree and Mn-containing Mg−Nd model systems, we reported unexpected three-and five-layered discontinuous segregation patterns of the coherent {101̅ 1} TBs, and not all the extension sites occupied by solutes larger in size than Mg, and even some larger sized solutes taking the compression sites. Nd/Mn solutes selectively segregate at substitutional sites and thus to generate two new types of ordered two-dimensional TB superstructures or complexions. These findings refresh the understanding of solute segregation in the perfect coherent TBs and provide a meaningful theoretical guidance for designing materials via targeted TB segregation.

show abstract

Unusual solute segregation phenomenon in coherent twin boundaries

Cited by 72 publications

References 50 publications

Massive transformation in FeNi nanopowders with nanotwin-assisted nitridation

Massive transformation in FeNi nanopowders with nanotwin-assisted nitridation

Nanotwin-assisted nitridation in FeNi nanopowders for synthesis of rare-earth-free magnets

Twin Boundary Superstructures Assembled by Periodic Segregation of Solute Atoms

Contact Info

Product

Resources

About