FSstel List of Optimized Systems and References

 

Al-B

P.J. Spencer, 2006 (VLAB Project)

 

Al-Bi

M. Paliwal and In-Ho Jung, "Thermodynamic modeling of Al-Bi, Al-Sb, Mg-Al-Bi and Mg-Al-Sb systems", Calphad, 2010, vol. 34, pp. 51-63.

 

Al-C

M. Paek, I. Jung, unpublished results (2018)

See also: J Grobner, H L Lukas, F Aldinger, CALPHAD 20 (1996) 247-254.

 

Al-C-Fe

M. Paek, I. Jung, unpublished results (2018)

See also: K-G.Chin, H-J.Lee, J-H.Kwak, J-Y.Kang, B-J.Lee, J. Alloys and Compounds 505 (2010) 217-223; A.T. Phan, M. Paek, Y.-B. Kang, Acta Materialia, 79 (2014) 1-15.

 

Al-C-Fe-Mn

M.-S. Kim, Y. Kang, “Development of thermodynamic database for high Mn-high Al steels: Phase equilibria in the Fe-Mn-Al-C system by experiment and thermodynamic modelling”, Calphad 51 (2015) 89-103.

 

Al-C-Mn

M. Paek, I. Jung, unpublished results (2018)

See also: K-G.Chin, H-J.Lee, J-H.Kwak, J-Y.Kang, B-J.Lee, J. Alloys and Compounds 505 (2010) 217-223.

 

Al-Ca

Y-B. Kang, CRCT, 2008

 

Al-Ca-Fe-Si

 J. C. Angelezio, C. Servant, I. Ansara, CALPHAD, Vol. 18, No. 3 (1994), 273-309.

 

Al-Ca-Mg

Y-B. Kang, CRCT, 2008

 

Al-Ce

Y-B. Kang, CRCT, 2008

 

Al-Co

Z. Zhu, I. Jung, unpublished results (2018)

 

Al-Co-Ni

Z. Zhu, I. Jung, unpublished results (2019)

 

Al-Cr

S. Cui, I Jung, J Kim, S. Xin, “A coupled experimental and thermodynamic study of the Al-Cr and Al-Cr-Mg systems”, J. Alloys and Compounds, vol. 698, 2017, pp. 1038-1057.

 

Al-Cr-Cu

S. Cui and In-Ho Jung, “Thermodynamic modeling of the quaternary Al-Cu-Mg-Si system”, Calphad, Vol. 57, pp. 1-27, 2017.

 

Al-Cr-Mg

S. Cui, I Jung, J Kim, S. Xin, “A coupled experimental and thermodynamic study of the Al-Cr and Al-Cr-Mg systems”, J. Alloys and Compounds, vol. 698, 2017, pp. 1038-1057.

 

Al-Cr-Mn

S. Cui and In-Ho Jung, “Thermodynamic modeling of the Al-Cr-Mn ternary system”, Metall. Mater. Trans A, 2017, Vol. 48, 1383-1401, 2017.

 

Al-Cr-Ni

Z. Zhu, I. Jung, unpublished results (2018)

 

Al-Cr-Si

S. Cui and In-Ho Jung, unpublished work (2015).

 

Al-Cr-Ti

Z. Zhu, I. Jung, unpublished results (2018)

 

Al-Cu

N. Saunders, unpublished research, COST-507 (1991).

 

Al-Cu-Fe

H.Ohtani, H.Suda, K.Ishida, ISIJ International 37 (1997) 207-216.;

 

Al-Cu-Mg

S. Cui and In-Ho Jung, “Thermodynamic modeling of the quaternary Al-Cu-Mg-Si system”, Calphad, Vol. 57, pp. 1-27, 2017.

 

Al-Cu-Mg-Si

S. Cui and In-Ho Jung, “Thermodynamic modeling of the quaternary Al-Cu-Mg-Si system”, Calphad, Vol. 57, pp. 1-27, 2017.

 

Al-Cu-Mn

S. Cui and In-Ho Jung, unpublished work (2015).

 

Al-Cu-Si

S. Cui and In-Ho Jung, “Thermodynamic modeling of the quaternary Al-Cu-Mg-Si system”, Calphad, Vol. 57, pp. 1-27, 2017.

 

Al-Dy

Y-B. Kang, CRCT, 2008

 

Al-Er

Y-B. Kang, CRCT, 2008

 

Al-Eu

Y-B. Kang, CRCT, 2008

 

Al-Fe

M. Paek, I. Jung, unpublished results (2018)

M. Kim, Y. Kang, “Thermodynamic Modeling of the Fe-Mn-C and the Fe-Mn-Al Systems Using the Modified Quasichemical Model for Liquid PhaseJ. Phase Equilibria and Diffusion 36(5), 2015, pp 453–470.

 

Al-Fe-Mg

J. Kim, In-Ho Jung, unpublished work (2016)

 

Al-Fe-Mg-Si

A. Prikhodowskij, RWTH Aachen, 2001.

J. Kim, In-Ho Jung, unpublished work (2016)

 

Al-Fe-Mn

M.-S. Kim, Y.-B. Kim, “Thermodynamic Modeling of the Fe-Mn-C and the Fe-Mn-Al Systems Using the Modified Quasichemical Model for Liquid Phase”, J. Phase Equilibria and Diff., 36 (2015), 453-470.

 

Al-Fe-Mn-N

Z. You, I.-Ho. Jung, unpublished work (2018).

 

Al-Fe-Mn-O

M. Paek, K. Do, Y. Kang, I. Jung, and J. Pak, “Aluminum Deoxidation Equilibria in Liquid Iron: Part III. Experiments and Thermodynamic Modeling of the Fe-Mn-Al-O system”, Metallurgical and Materials Transaction B, 2016, vol. 47, pp. 2837-2847.

 

Al-Fe-Mn-Si

M. Paek, I. Jung, unpublished results (2018)

 

Al-Fe-Mn-Si-N

M. Paek, I. Jung, unpublished results (2018)

Z. You, and I. Jung, unpublished results (2018)

 

Al-Fe-Mn-Si-P

Z. You, and I. Jung unpublished results (2019)

 

Al-Fe-O

M Paek, K Do, Y Kang, I Jung, and J Pak, “Aluminum Deoxidation Equilibria in Liquid Iron: Part III. Experiments and Thermodynamic Modeling of the Fe-Mn-Al-O system”, Metallurgical and Materials Transaction B, 2016, vol. 47, pp. 2837-2847.

 

Al-Fe-P

Z. You, M. Paek, I. Jung, unpublished results (2019)

 

Al-Fe-Zn

J. Kim, I.-H. Jung, P. Spencer, unpublished work (2016)

 

Al-Gd

Y-B. Kang, CRCT, 2008

 

Al-H

J.-P. Harvey, Master Thesis, Ecole Polytechnique de Montreal (2006).

 

Al-Hf

T. Wang et al. Journal of Phase Equilibria Vol. 23 No. 5 2002, pp. 416-423.

 

Al-Ho

Y-B. Kang, CRCT, 2008

 

Al-La

L. Jin, Y.-B. Kang, P. Chartrand and C.D. Fuerst, “Thermodynamic evaluation and optimization of Al-La, Al-Ce, Al-Pr, Al-Nd and Al-Sm systems using the Modified Quasichemical Model for liquids”, CALPHAD: Computer Coupling of Phase Diagrams and Thermochemistry, 35(1), p.30-41, 2011.

 

Al-Lu

Y-B. Kang, CRCT, 2008

 

Al-Mg

P. Chartrand, CRCT, 2006; Vol.Data: F.Gemme, CRCT, 2003 (VLAB project); C.Aliravci, 2007 (GM Project)

 

Al-Mg-Zn

From FTlite database

 

Al-Mn

S. Cui, I. Jung, “Thermodynamic modeling of the Al-Cr-Mn ternary system”, Metall. Mater. Trans A, 2017, Vol. 48, 1383-1401.

 

Al-Mo

N. Saunders, COST 507 (1998) ISBN 92-828-3902-8 p 59-64

 

Al-N

Z. You, M. Paek, I. Jung, unpublished results (2018)

 

Al-Nb

C. He et al. Journal of Alloys and Compounds 637 (2015) 361–375

 

Al-Nb-Ni

GTT technology, 2023

Also see Y. Du et al. Intermetallics 11 (2003) 995–1013

 

Al-Nd

Y-B. Kang, CRCT, 2008

 

Al-Ni

Z. Zhu, I. Jung, unpublished results (2018)

 

Al-P

Z. You, M. Paek, I. Jung, unpublished results (2018)

 

Al-Pb

Y.-B. Kang, CRCT, 2009

 

Al-Pr

Y-B. Kang, CRCT, 2008

 

Al-Sb

M. Paliwal and In-Ho Jung, "Thermodynamic modeling of Al-Bi, Al-Sb, Mg-Al-Bi and Mg-Al-Sb systems"Calphad, 2010, vol. 34, pp. 51-63.

 

Al-Sc

Y-B. Kang, CRCT, 2008

 

Al-Si

J.-P. Harvey, M.A.Sc. thesis, Ecole Polytechnique, 2006

 

Al-Sm

Y-B. Kang, CRCT, 2008

 

Al-Sn

S.G.Fries, H.L.Lukas, COST 507 (1998) ISBN 92-828-3902-8, p.81-82

 

Al-Tb

Y-B. Kang, CRCT, 2008

 

Al-Ti

Z. Zhu, I. Jung, unpublished results (2018)

 

Al-Tm

Y-B. Kang, CRCT, 2008

 

Al-V

N. Saunders, COST 507 (1998) ISBN 92-828-3902-8 p 95-98

 

Al-W

N. Saunders, COST 507 (1998) ISBN 92-828-3902-8 p 103-108

 

Al-Y

FTlite

 

Al-Yb

Y-B. Kang, CRCT, 2008

 

Al-Zn

Liquid : P. Chartrand, CRCT, 2006 (VLAB Project); Vol.Data. F.Gemme, CRCT, 2003 (VLAB Project); solids S. –L. Chen and Y.A. Chang, Calphad, 17 (1993), pp. 113-124.

 

Al-Zr

COST 507, pp.112-116.

 

B-C

P.-J. Spencer, 2007 (VLAB project)

 

B-Co

M.-A. Van Ende, I.-H. Jung, unpublished work (2018)

 

B-Cr

M.-A. Van Ende, I.-H. Jung, unpublished work (2018)

 

B-Cu

M.-A. Van Ende, I.-H. Jung, unpublished work (2018)

 

B-Dy

M.-A. Van Ende, I.-H. Jung, unpublished work (2018)

 

B-Fe

M.-A. Van Ende, I.-H. Jung, unpublished work (2018);

M.-A. Van Ende and I.-H. Jung, “Critical thermodynamic evaluation and optimization of the Fe-B, Fe-Nd, B-Nd and Nd-Fe-B systems”, J. Alloy. Compd. 2013, Vol. 548, pp. 133–1542.

 

B-Fe-Nd

M.-A. Van Ende and I.-H. Jung, “Critical thermodynamic evaluation and optimization of the Fe-B, Fe-Nd, B-Nd and Nd-Fe-B systems”, J. Alloy. Compd. 2013, Vol. 548, pp. 133–1542.

 

B-Fe-Dy

M.-A. Van Ende, T.-S. Kim, Y. Kim, I.-H. Jung, “Thermodynamic optimization of the Dy-Nd-Fe-B system and application to the recovery and recycling of rare earth metal from NdFeB magnet”, Green Chemistry, 2015, vol. 17, 2246-2262.

 

B-Fe-Nd-Dy

M.-A. Van Ende, T.-S. Kim, Y. Kim, I.-H. Jung, “Thermodynamic optimization of the Dy-Nd-Fe-B system and application to the recovery and recycling of rare earth metal from NdFeB magnet”, Green Chemistry, 2015, vol. 17, 2246-2262.

 

B-Mn

M.-A. Van Ende, I.-H. Jung, unpublished work (2018)

 

B-Mo

L.M. Pan, unpublished research in SGTE Solution Database, 1991.

 

B-N

FTlite database

 

B-Ni

M.-A. Van Ende, I.-H. Jung, unpublished work (2018)

 

B-Pb

M.-A. Van Ende, I.-H. Jung, unpublished work (2018)

 

B-Pr

M.-A. Van Ende, I.-H. Jung, unpublished work (2018)

 

B-Si

FTlite database

 

B-Sn

M.-A. Van Ende, I.-H. Jung, unpublished work (2018)

 

B-Tb

M.-A. Van Ende, I.-H. Jung, unpublished work (2018)

 

B-Ti

M.-A. Van Ende, I.-H. Jung, unpublished work (2018)

 

B-V

L.M. Pan, unpublished research in SGTE Solution Database, 1991.

 

B-W

H. Duschanek, P. Rogl, J. Phase Equilib. 16 (1995), pp. 150-161.

 

B-Zn

M.-A. Van Ende, I.-H. Jung, unpublished work (2018)

 

B-Zr

X.-F. Sheng, CRCT, 2008 (GM Project)

 

Bi-Cu

C.P. Wang et al. / Journal of Alloys and Compounds 482 (2009) 67–72

 

Bi-Fe

T. Jantzen, GTT optimisation, 2003.

 

Bi-Sn

FTlite database

 

Bi-Zn

C Girard, Thesis (Marseille 1985); Bi-Ga-Zn

 

C-Ca

I.-H. Jung, 2020 (similar to FTlite)

 

C-Co

A. Fernandez Guillermet, Z Metallkde,  78 (1987) 700-709

 

C-Co-Cr

A. Kussofsky and B.Jansson, CALPHAD 21 (1997) 321-333

 

C-Co-Cr-W

B. Janssen, Inst. of Metals Report, Stockholm, (1987)

 

C-Co-Fe

A.Fernandez Guillermet, Z. Metallkde. 79 (1988) 317-329

 

C-Co-Fe-Ni

A. Fernandez Guillermet, Z.Metallkde. 79 (1988) 524-536

 

C-Co-Ni

A.Fernandez Guillermet, Z.Metallkde. 79 (1988) 524-536

 

C-Co-V

S. Huang et al. / Journal of Alloys and Compounds 385 (2004) 114–118

 

C-Co-W

A.Fernandez Guillermet, Metall.Trans. 20A (1989) p 935-956

 

C-Cr

B.J.Lee, CALPHAD 16 (1992) 121-149

 

C-Cr-Fe

J-O.Andersson, Met.Trans A, 19A (1988) 627-636;  B.-J. Lee, Calphad 16 (1992) 121-149

Small modification for M23C6, M7C3 (In-Ho Jung, 2018)

 

C-Cr-Fe-Mn

B.-J. Lee, Metall.Trans.A 24A (1993) 1017-1025

 

C-Cr-Fe-Mo

Caian Qiu, ISIJ International 32 (1992) 1117-1127

 

C-Cr-Fe-Ni

Byeong-Joo Lee, unpublished revision (1993)

 

C-Cr-Fe-V

P.Gustafson, Inst.Met.Res.(Sweden) (1990) -Estimation

 

C-Cr-Fe-W

P.Gustafson, Metall.Trans. 19 (1988) 2547-2554;  Byeong-Joo Lee, unpublished revision (1991)

 

C-Cr-Mn

B.-J. Lee, Metall.Trans.A 24A (1993) 1017-1025

 

C-Cr-Mo

Caian Qiu, ISIJ International 32 (1992) 1117-1127

 

C-Cr-Mo-V

J. Bratberg, Z. Metallkd. 96 (2005) 335-344

 

C-Cr-N

Z. You, M. Paek, I. Jung, unpublished results (2018)

 

C-Cr-Ni

M. Paek, I. Jung, unpublished results (2018)

 

C-Cr-Si

Y. Du, J.C. Schuster, L. Perring,  J. Am. Ceram. Soc. 83 (2000) 2067-73

 

C-Cr-Ti

J.C. Schuster, Y. Du,  Calphad 23 (1999) 393-408

 

C-Cr-V

P.Gustafson, Inst.Met.Res.(Sweden) (1990) -Estimation

 

C-Cu

K. Shubhank, Y.-B. Kang / CALPHAD: Computer Coupling of Phase Diagrams and Thermochemistry 45 (2014) 127–137

 

 

C-Cu-Fe

K. Shubhank, Y.-B. Kang / CALPHAD: Computer Coupling of Phase Diagrams and Thermochemistry 45 (2014) 127–137

 

C-Fe

M. Kim, Y. Kang, “Thermodynamic Modeling of the Fe-Mn-C and the Fe-Mn-Al Systems Using the Modified Quasichemical Model for Liquid PhaseJ. Phase Equilibria and Diffusion 36(5), 2015, pp 453–470.

 

C-Fe-Mn

M. Kim, Y. Kang, “Thermodynamic Modeling of the Fe-Mn-C and the Fe-Mn-Al Systems Using the Modified Quasichemical Model for Liquid PhaseJ. Phase Equilibria and Diffusion 36(5), 2015, pp 453–470.

 

C-Fe-Mn-V

W.Huang, TRITA-MAC 441, (1990)

 

C-Fe-Mo

J.O.Andersson, Calphad 12 (1988) p 9-23

 

C-Fe-Mo-W

P.Gustafson, Z.Metallkde. 79 (1988) 421-425

 

C-Fe-N

Z. You, M. Paek, I-H. Jung (2019), unpublished.

 

C-Fe-N-Nb-Ti

B.J. Lee, Met.Mater.Trans.A 32A (2001) 2423-2439

 

C-Fe-Nb

W. Huang, Z.Metallkde. 81 (1990) 397-404

 

C-Fe-Ni

A.Gabriel, P.Gustafson, I.Ansara, CALPHAD 11 (1987) 203-218

 

C-Fe-P

Z. You and I-H. Jung (2019), unpublished.

 

C-Fe-Si

M. Paek and I-H. Jung (2018), unpublished.

 

C-Fe-Ti

S.Jonsson, Metall.Mater.Trans.B 29B (1998) 371-384

L.F.S.Dumitrescu, M.Hillert, ISIJ International 39 (1999) 84-90

 

C-Fe-V

W.Huang, TRITA-MAC 432, (1990)

 

C-Fe-W

P.Gustafson, Metall.Trans. 18A (1987) p 175-188;  P. Franke, private communication to SGTE, 2008

 

C-Hf

H. Bitterman, P. Rogl, J. Phase Equilibria, 18 (1997) 344-356.

 

C-Hf-Nb

P.J.Spencer, 2011, no ternary parameters required.

 

C-Hf-W

P.J.Spencer, 2011.

 

C-Mn

M. Paek, J. Pak, Y.-B. Kang, Phase equilibria and thermodynamics of Mn-C, Mn-Si, Si-C binary systems and Mn-Si-C ternary system by critical evaluation, combined with experiment and thermodynamic modeling. CALPHAD 46, 92-102 (2014)

 

C-Mn-Si

M. Paek, J. Pak, Y.-B. Kang, Phase equilibria and thermodynamics of Mn-C, Mn-Si, Si-C binary systems and Mn-Si-C ternary system by critical evaluation, combined with experiment and thermodynamic modeling. CALPHAD 46, 92-102 (2014)

 

C-Mn-V

W.Huang, TRITA-MAC 441, (1990);  W. Huang, Metall. Trans. 22A (1991) 1911-1920

 

C-Mo

J.O.Andersson, Calphad 12 (1988) p 1-8

 

C-Mo-Ti

H.-J. Chung, J.-H. Shim,   D.N. Lee, J. Alloys Comp. 282 (1999) 142-148

 

C-Mo-V

P.Gustafson, Inst.Met.Res.(Sweden) (1990, estim.);  J. Bratberg, K. Frisk,  Calphad 26 (2002) 459-476

 

C-Mo-W

P.Gustafson, Z.Metallkde. 79 (1988) 397-402

 

C-N-Nb

W.Huang, Z.Metallkde. 88 (1997) 63-68

 

C-N-Ti

B.J.Lee, Met.Mater.Trans.A 32A (2001) 2423-2439;  S. Jonsson, Z. Metallkd. 87 (1996) 713-720

 

C-Nb

W.Huang, M.Selleby, Z.Metallkde. 88 (1997) 55-62

 

C-Nb-Ta

P.J.Spencer, 2011

 

C-Nb-Ti

B.J.Lee, Met.Mater.Trans.A 32A (2001) 2423-2439

 

C-Nb-V

P.J.Spencer, 2011

 

C-Nb-Zr

P.J.Spencer, 2011

 

C-Ni

M. Paek, I. Jung, unpublished work (2018)

A.Gabriel, C.Chatillon, I.Ansara, Calphad Vol 11 (1987) 203-218

 

C-Ni-Si

Y. Du, J.C. Schuster,  Metall. Mater. Trans. 30A (1999) 2409-2418

 

C-Ni-Ti

Y. Du, J.C. Schuster: Z Metallkd. 89 (1998) 399-410

 

C-Ni-W

P.Gustafson, A.Gabriel, I.Ansara, Z.Metallkde. 78 (1986) 151-156

 

C-Si

M. Paek, I. Jung, unpublished work (2018);

J.Grobner, H L Lukas, F Aldinger, CALPHAD 20 (1996) 247-254

 

C-Ta (new parameters for liquid, fcc, bcc, hcp are necessary)

P.J.Spencer, 2011

 

C-Ta-W

P.J.Spencer, 2011

 

C-Ti

S.Jonsson, Z.Metallkde. 87 (1996) 703-712

 

C-Ti-W

S. Jonsson, Z. Metallkde. 87 (1996) 788-795

 

C-V

W. Huang, Z Metallkd 82 (1991) p 174-181

 

C-V-W

P.J.Spencer, 2011;  J. Bratberg, Z. Metallkd. 96 (2005) 335-344

 

C-W

P. Gustafson, Mater.Sci.& Tech. 2 (1986) p 653-658

 

C-W-Zr

P.J.Spencer, 2011

 

C-Zr

A. Fernandez Guillermet; J. Alloys Compounds, 217 (1995) 69-89.

 

Ca-Co

Liquid miscibility gap – estimation; FTlite database.

 

Ca-Cr

Liquid miscibility gap – estimation; FTlite database.

 

Ca-Fe

S. Cui, M. Paliwal, In-Ho Jung, “Thermodynamic Optimization of Ca-Fe-Si System and its Applications to Metallurgical Grade Si-Refining Process”, Metall. Mater. Trans. E, 2014 vol. 1, pp. 67-79.

 

Ca-Fe-O

In-Ho Jung, unpublished work (2018)

 

Ca-Fe-S

In-Ho Jung, unpublished work (2018)

 

Ca-Fe-Si

S. Cui, M. Paliwal, In-Ho Jung, “Thermodynamic Optimization of Ca-Fe-Si System and its Applications to Metallurgical Grade Si-Refining Process”, Metall. Mater. Trans. E, 2014 vol. 1, pp. 67-79.

 

Ca-H

(only liquid) J.-P. Harvey, Master Thesis, Ecole Polytechnique de Montreal (2006).

 

Ca-Mg

J. Wang, Ph.D. Thesis, Ecole Polytechnique, 2014

 

Ca-Mo

Estimated work, FTlite database.

 

Ca-Ni

In-Ho Jung, unpublished work (2022), reoptimization based the work by D. Uremovich, F. Islam, M. Medraj, Science and Technology of Advanced Materials 7 (2006) 119–126.

 

Ca-P

Adamantia Lazou and In-Ho Jung, unpublished work (2022)

 

Ca-Si

M. Heyerman and P. Chartrand, “Thermodynamic Evaluation and Optimization of the Ca-Si System”, J. Phase Equilibria and Diffusion, 27 [3], 220-230, 2006

 

Ca-Sn

Jian Wang, Ph.D. Thesis, Ecole Polytechnique, Montreal, 2014

 

Ca-Ta

Estimated work, FTlite database.

 

Ca-Ta

Liquid miscibility gap, Estimated work, FTlite database.

 

Ca-Ti

Liquid miscibility gap, Estimated work, FTlite database.

 

Ca-V

Liquid miscibility gap, Estimated work, FTlite database.

 

Ca-W

Liquid miscibility gap, Estimated work, FTlite database.

 

Ca-Zn

P. Spencer, A.D. Pelton., Y.-B. Kang, P. Chartrand, and C. Fuerst, Calphad 32 (2007), pp. 423-431

 

Ce-Co

A. Gupta and I.-H. Jung, unpublished work, 2018.

 

Ce-Cr

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Ce-Fe

Bikram Konar, Junghwan Kim and In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = La, Ce, Pr, Nd and Sm”, Journal of Phase Equilibria and Diffusion, 2016, vol. 37(4), 438-458.

 

Ce-Mg

FTlite database.

 

Ce-Mn

J Kim, I.-H. Jung, “Critical systematic evaluation and thermodynamic optimization of the Mn-RE system: RE = La, Ce, Pr, Nd and Sm”, J. Alloy. Compd., 2012, vol. 525, pp. 191-201.

 

Ce-Ni

A. Pachauri and I.-H. Jung, unpublished work, 2018.

 

Ce-Si

J. Kim, In-Ho Jung, “Critical evaluation and thermodynamic optimization of the Si-RE systems: Part I. Si-RE system (RE = La, Ce, Pr, Nd and Sm)”, J. Chem. Thermodynamics, 2015, vol. 81, pp. 253-272.

 

Co-Cr

Z. Zhu, In-Ho Jung, unpublished work (2018).

 

Co-Cr-Fe

In-Ho Jung, unpublished work (2000)

 

Co-Cr-Ni

T.Jantzen, GTT, 2003.

Z. Zhu, I.-H. Jung, unpublished work (2019)

 

Co-Cr-V

In-Ho Jung, unpublished work (2000)

 

Co-Cr-W

B.Janssen, Inst. of Metals Report, Stockholm, (1987)

 

Co-Cu

T.Nishizawa, K.Ishida, Bull. Alloy Phase Diags. 5 (1984) 161-165

 

Co-Cu-Fe

H.Ohtani, H.Suda, K.Ishida, ISIJ International 37 (1997) 207-216.

 

Co-Dy

A. Gupta and I.-H. Jung, unpublished work, 2018.

 

Co-Er

A. Gupta and I.-H. Jung, unpublished work, 2018.

 

Co-Fe

A.Fernandez Guillermet, High Temp. High Press. 19 (1988) 477-499

 

Co-Fe-Ni

A.Fernandez Guillermet, CALPHAD 13 (1989) 1-22

 

Co-Fe-N

A.Fernandez Guillermet, S.Jonsson, Z.Metallkde. 83 (1993) 165-175

 

Co-Fe-V

In-Ho Jung, unpublished work (2000)

 

Co-Fe-W

A.Fernandez Guillermet, Z.Metallkde. 79 (1988) 633-642

 

Co-Fe-Zn

In-Ho Jung, unpublished work, 2020.

 

Co-Gd

A. Gupta and I.-H. Jung, unpublished work, 2018.

 

Co-Ho

A. Gupta and I.-H. Jung, unpublished work, 2018.

 

Co-Mg

FTlite database

 

Co-Mn

W.Huang, Calphad 13 (1989) p 231-242

 

Co-Mo

A.Davydov, U.R.Kattner, J.Phase Equilibria 20 (1999) p 5-16

 

Co-N

A.F.Guillermet, S.Jonsson, Z.Metallkde. 83(1992)1 p 21-31

 

Co-Nb

K.C.H.Kumar, I.Ansara, P.Wollants, L.Delaey, J.Alloys and Compounds 267 (1998) p 105-112

 

Co-Nd

A. Gupta and I.-H. Jung, unpublished work, 2018.

 

Co-Ni

A. Fernandez Guillermet, Z Metallkde, 78 (1987) 639-647

 

Co-Ni-Ti

Z. Zhu, In-Ho Jung, unpublished work (2019).

 

Co-Ni-V

In-Ho Jung, unpublished work (2000)

 

Co-Ni-W

A. Fernandez Guillermet, TRITA-MAC 373, (1988)

 

Co-Pr

A. Gupta and I.-H. Jung, unpublished work, 2018.

 

Co-S

From FTmisc

 

Co-Sc

I.-H. Jung, unpublished work, 2022

 

Co-Si

In-Ho Jung, unpublished (2017).

 

Co-Sm

A. Gupta and I.-H. Jung, unpublished work, 2018.

 

Co-Ti

Z. Zhu, In-Ho Jung, unpublished work (2018).

 

Co-V

S. Huang et al. / Journal of Alloys and Compounds 385 (2004) 114–118

 

Co-W

A.F.Guillermet, Metall.Trans. 20A (1989) p 935-956

 

Co-Y

A. Gupta and I.-H. Jung, unpublished work, 2018.

 

Co-Zn

Junghwan Kim and In-Ho Jung, unpublished work, 2012.

 

Co-Zr

A.Durga, H. Kumar: CALPHAD 34(2010)200-205

 

Cr-Cu

S. Cui and In-Ho Jung, “Thermodynamic modeling of the Cu-Fe-Cr and Cu-Fe-Mn systems”, Calphad, vol. 56, pp. 241-259, 2017.

 

Cr-Cu-Fe

S. Cui and In-Ho Jung, “Thermodynamic modeling of the Cu-Fe-Cr and Cu-Fe-Mn systems”, Calphad, vol. 56, pp. 241-259, 2017.

 

Cr-Dy

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cr-Er

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cr-Eu

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cr-Fe

S. Cui and In-Ho Jung, “Thermodynamic modeling of the Cu-Fe-Cr and Cu-Fe-Mn systems”, Calphad, vol. 56, pp. 241-259, 2017.

 

Cr-Gd

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cr-Ho

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cr-La

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cr-Lu

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cr-Fe-Mn

B.J.Lee, Met.Trans. A, 24A (1993) 1919-1932; C. Qiu, Metall. Trans. 24A (1993) 2393-2409

 

Cr-Fe-Mn-N

Z. You, M. Paek, In-Ho Jung, unpublished results, 2018.

 

Cr-Fe-Mo

C. Qiu, CALPHAD, 16 (1992), N. 3, pp. 281-189.

 

Cr-Fe-N

Z. You, M. Paek, In-Ho Jung, unpublished results, 2018.

 

Cr-Fe-N-Ni

Z. You, M. Paek, In-Ho Jung, unpublished results, 2018.

 

Cr-Fe-Ni

M. Paek, In-Ho jung, unpublished results, 2018.

B.J.Lee, private communication (2000)

 

Cr-Fe-O

M. Paek, In-Ho Jung, unpublished work (2018)

 

Cr-Fe-P

Z. You, In-Ho jung, unpublished results, 2019.

 

Cr-Fe-O

M. Paek, In-Ho Jung, unpublished work (2018)

 

Cr-Fe-S

FTmisc database

 

Cr-Fe-V

B.J.Lee, TRITA-MAC 474, (1991)

 

Cr-Fe-W

P.Gustafson, TRITA-MAC 342 (1987)

 

Cr-H

J.-P. Harvey, Master Thesis, Ecole Polytechnique de Montreal (2006).

 

Cr-Mg

S. Cui, In-Ho Jung, Junghwan Kim, and S.. Xin, “A coupled experimental and thermodynamic study of the Al-Cr and Al-Cr-Mg systems”, J. Alloys and Compounds, vol. 698, 2017, pp. 1038-1057.

 

Cr-Mn

S .Cui and In-Ho Jung, “Thermodynamic modeling of the Al-Cr-Mn ternary system”, Metall. Mater. Trans A, 2017, Vol. 48, 1383-1401, 2017.

 

Cr-Mn-N

Z. You, M. Paek, In-Ho Jung, unpublished results, 2018.

K. Frisk, Calphad 17 (1993) 335-349; C. Qiu, Metall.Trans. 24A (1993) 2393-2409

 

Cr-Mn-Ni

P. Franke, private communication to SGTE, 2008

 

Cr-Mn-Ti

L.Y. Chen, C.H. Li, K. Wang, H.Q. Dong, X.G. Lu, W.Z. Ding, Calphad 2009, vol. 33, 658–663.

 

Cr-Mo

K..Frisk, P..Gustafson, Calphad 12 (1988) p 247-254

 

Cr-Mo-N

K..Frisk, TRITA-MAC 393 (1989);  P. Franke, private communication to SGTE, 2013

 

Cr-Mo-Nb

Y. Du et al., CALPHAD, 29 (2005) 140–148

I.-H. Jung, unpublished work (2021): Liquid and solid solutions were modified.

 

Cr-Mo-Nb-Ni

I.-H. Jung, unpublished work (2021)

 

Cr-Mo-Ni

K..Frisk, TRITA-MAC 492 (1990)

 

Cr-N

Z. You, M. Paek, In-Ho Jung, unpublished results, 2018.

K.Frisk, TRITA-MAC 393 (1989)

 

Cr-N-Ni

Z. You, M. Paek, In-Ho Jung, unpublished results, 2018.

K.Frisk, TRITA-MAC 422 (1990)

 

Cr-N-Ti

P.Gustafson, Inst.Met.Res.(Sweden) (1990) - Estimation

 

Cr-N-V

P.Gustafson, Inst.Met.Res.(Sweden) (1990) - Estimation

 

Cr-N-W

P.Gustafson, Inst.Met.Res.(Sweden) (1990) – Estimation

 

Cr-Nb

J.G.Costa Neto, S.G.Fries, H.L.Lukas, Calphad 17 (1993) p 219-228

 

Cr-Nb-Ni

Y. Du et al., CALPHAD, 29 (2005) 140–148

I.-H. Jung, unpublished work (2021): Liquid and solid solutions were modified.

 

Cr-Nd

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cr-Ni

Z. Zhu, In-Ho Jung, unpublished work (2018) – liquid is changed to MQM

A.Dinsdale, T.G.Chart, MTDS NPL, Unpublished work (1986)

 

Cr-Ni-W

P.Gustafson, CALPHAD 11 (1987) 277-292

 

Cr-P

Z. You, M. Paek, In-Ho Jung, unpublished results, 2018.

 

Cr-Pb

P. Chartrand, 2003

 

Cr-Pr

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cr-S

FTmisc database

 

Cr-Sc

FTlite database

 

Cr-Sm

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cr-Tb

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cr-Y

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cr-Yb

SW. Jung and I.-H. Jung, unpublished work, 2022.

 

Cu-Fe-Mn

S. Cui, In-Ho Jung, “Thermodynamic modeling of the Cu-Fe-Cr and Cu-Fe-Mn systems”, Calphad, vol. 56, pp. 241-259, 2017.

 

Cu-Fe-Ni

H.Ohtani, H.Suda, K.Ishida, ISIJ International 37 (1997) 207-216.

 

Cu-Fe-S

FTmisc database

 

Cu-Fe-Si

In-Ho Jung, unpublished work (2020)

 

Cu-Fe-Sn

H. Ohtani, H. Suda, K. Ishida, ISIJ International 37 (1997) 207-216.

Ok

 

Cu-Fe-V

H. Ohtani, H. Suda, K. Ishida, ISIJ International 37 (1997) 207-216.

 

Cu-H

J.-P. Harvey, Master Thesis, Ecole Polytechnique de Montreal (2006).

 

Cu-Mg-Si

S. Cui, In-Ho Jung, unpublished work (2015)

 

Cu-Mn

S. Cui, In-Ho Jung, “Thermodynamic modeling of the Cu-Fe-Cr and Cu-Fe-Mn systems”, Calphad, vol. 56, pp. 241-259, 2017.

H. Ohtani, H. Suda, K. Ishida, ISIJ International 37 (1997) 207-216.

 

Cu-Nd

A. Hussain, M.A. Van Ende, J. H. Kim and I.-H. Jung, “Critical thermodynamic evaluation and optimization of the Co-Nd, Cu-Nd and Nd-Ni systems”, Calphad, 2013, vol. 41, pp. 26-41.

 

Cu-Ni

A. Jansson, TRITA-MAC 340 (1987); Cu-Fe-Ni'

 

Cu-P

SGTE database

 

Cu-Pb

SGTE database

 

Cu-S

FTmisc database

 

Cu-Sb

SGTE database

 

Cu-Si

D. Kcang, In-Ho Jung, unpublished work (2010)

 

Cu-Sn

J.H.Shim, C.S.Oh, B.J.Lee, D.N.Lee, Z.Metallkde 87 (1996) 205-212.

 

Cu-Ti

SGTE database

 

Cu-V

BJL database, private communication 1999; Cu-V.

 

Cu-W

In-Ho Jung, unpublished work, 2020

 

Cu-Zn

M. Kowalski, P.J. Spencer, J Phase Equil 14(1993)4 p 432-438.

 

Cu-Zr

COST 507, pp.192-194.

 

Dy-Fe

Bikram Konar, Junghwan Kim and In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = Gd, Tb, Dy, Ho, Er, Tm, Lu, and Y”, Journal of Phase Equilibria and Diffusion, 2017, vol. 38, Issue 4, pp 509–542.

 

Dy-Mg

FTlite database.

 

Dy-Mn

J. Kim, M. Paliwal, Z. Zhou, H. Kim, and I.-H. Jung, “Critical systematic evaluation and thermodynamic optimization of the Mn-RE system (RE = Tb, Dy, Ho, Er, Tm and Lu) with key experiments for the Mn-Dy system”, J. Phase Equilibria and Diffusion, 2014, vol. 35 (6), pp. 670-694.

 

Dy-Ni

A. Pachauri and I.-H. Jung, unpublished work, 2018.

 

Dy-Si

J. Kim, In-Ho Jung, “Critical evaluation and thermodynamic optimization of the Si-RE systems: Part II. Si-RE system (RE = Gd, Tb, Dy, Ho, Er, Tm, Lu and Y)”, J. Chem. Thermodynamics, 2015, vol. 81, pp. 273-297.

 

Er-Fe

Bikram Konar, Junghwan Kim and In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = Gd, Tb, Dy, Ho, Er, Tm, Lu, and Y”, Journal of Phase Equilibria and Diffusion, 2017, vol. 38, Issue 4, pp 509–542.

 

Er-Mn

J. Kim, M. Paliwal, Z. Zhou, H. Kim, and I.-H. Jung, “Critical systematic evaluation and thermodynamic optimization of the Mn-RE system (RE = Tb, Dy, Ho, Er, Tm and Lu) with key experiments for the Mn-Dy system”, J. Phase Equilibria and Diffusion, 2014, vol. 35 (6), pp. 670-694.

 

Er-Ni

A. Pachauri and I.-H. Jung, unpublished work, 2018.

 

Er-Si

J. Kim, In-Ho Jung, “Critical evaluation and thermodynamic optimization of the Si-RE systems: Part II. Si-RE system (RE = Gd, Tb, Dy, Ho, Er, Tm, Lu and Y)”, J. Chem. Thermodynamics, 2015, vol. 81, pp. 273-297.

 

Fe-Gd

Bikram Konar, Junghwan Kim and In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = Gd, Tb, Dy, Ho, Er, Tm, Lu, and Y”, Journal of Phase Equilibria and Diffusion, 2017, vol. 38, Issue 4, pp 509–542.

 

Fe-H

J.-P. Harvey, Master Thesis, Ecole Polytechnique de Montreal (2006).

 

Fe-Hf

In-Ho Jung, unpublished work, 2020

 

Fe-Ho

Bikram Konar, Junghwan Kim and In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = Gd, Tb, Dy, Ho, Er, Tm, Lu, and Y”, Journal of Phase Equilibria and Diffusion, 2017, vol. 38, Issue 4, pp 509–542.

 

Fe-La

B. Konar, J. Kim, In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = La, Ce, Pr, Nd and Sm”, Journal of Phase Equilibria and Diffusion, 2016, vol. 37(4), 438-458.

 

Fe-La-Si

I.-H. Jung, unpublished work (2021)

 

Fe-Lu

Bikram Konar, Junghwan Kim and In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = Gd, Tb, Dy, Ho, Er, Tm, Lu, and Y”, Journal of Phase Equilibria and Diffusion, 2017, vol. 38, Issue 4, pp 509–542.

 

Fe-Mg

P. Chartrand, CRCT, 2006 (GM project)

 

Fe-Mg-O

In-Ho Jung, unpublished work (2018)

 

Fe-Mg-S

In-Ho Jung, unpublished work (2018)

 

Fe-Mg-Si

S. Cui, In-Ho Jung, unpublished work (2015)

 

Fe-Mn

S. Cui, In-Ho Jung, unpublished work (2015)

W. Huang, CALPHAD Vol 13 (1989) pp 243-252, TRITA-MAC 388 (rev 1989).

 

Fe-Mn-N

Z. You, M. Paek, In-Ho Jung, “Critical Evaluation and Optimization of the Fe-N, Mn-N and Fe-Mn-N Systems”, J. Phase Equilibria and Diffusion, 2018, vo. 39, pp. 650-677.

 

Fe-Mn-Nb

I.-H. Jung, unpublished work (2020)

 

Fe-Mn-Ni

P. Franke, private communication to SGTE, 2008;

In-Ho Jung, unpublished work (slightly modification), 2020.

 

Fe-Mn-O

M. Paek, K. Do, Y.-B. Kang, I. Jung, and J. Pak, “Aluminum Deoxidation Equilibria in Liquid Iron: Part III. Experiments and Thermodynamic Modeling of the Fe-Mn-Al-O system”, Metallurgical and Materials Transaction B, 2016, vol. 47, pp. 2837-2847.

 

Fe-Mn-P

Z. You, I.-H. Jung, unpublished work (2019)

 

Fe-Mn-S

FTmisc database.

 

Fe-Mn-Si

M. Paek, In-Ho Jung, unpublished work (2018)

 

Fe-Mn-V

W.Huang, TRITA-MAC 441, (1990)

 

Fe-Mo

J. O. Andersson, Calphad 12 (1988) p 9-23

 

Fe-Mo-N

P.Gustafson, Inst.Met.Res.(Sweden) (1990) - Estimation

 

Fe-Mo-S

In-Ho Jung, private communication, 2004

 

Fe-Mo-Ni

K.Frisk, TRITA-MAC 428 (1990)

 

Fe-Mo-W

P.Gustafson, Z.Metallkde. 79 (1988) p 388-396

 

Fe-N

Z. You, M. Paek, In-Ho Jung, “Critical Evaluation and Optimization of the Fe-N, Mn-N and Fe-Mn-N Systems”, J. Phase Equilibria and Diffusion, 2018, vo. 39, pp. 650-677.

 

Fe-N-Nb

B.J.Lee, Met.Mater.Trans.A 32A (2001) 2423-2439

 

Fe-N-Ni

Z. You, M. Paek, In-Ho Jung, unpublished work (2018)

 

Fe-N-Si

Z. You, M. Paek, In-Ho Jung, unpublished work (2018)

 

Fe-N-Ti

B.J.Lee, Met.Mater.Trans.A 32A (2001) 2423-2439

 

Fe-N-V

H.Ohtani, KTH Report, (1990)

 

Fe-N-W

P.Gustafson, Inst.Met.Res.(Sweden) (1990) - Estimation

 

Fe-Nb

B.J.Lee, Met.Mater.Trans.A 32A (2001) 2423-2439

 

Fe-Nb-Ti

B.J.Lee, Met.Mater.Trans.A 32A (2001) 2423-2439

 

Fe-Nd

Bikram Konar, Junghwan Kim and In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = La, Ce, Pr, Nd and Sm”, Journal of Phase Equilibria and Diffusion, 2016, vol. 37(4), 438-458.

 

Fe-Ni

M. Paek, In-Ho Jung, unpublished work (2018)

A.Dinsdale, T.G.Chart, MTDS NPL, unpublished work (1986)

 

Fe-Ni-P

Z. You and In-Ho Jung, unpublished work, 2009

 

Fe-Ni-S

In-Ho Jung, private communication, 2004

 

Fe-Ni-Si 

J. Miettinen, Calphad 23 (1999) 249-262

In-Ho Jung, unpublished work, 2020.

 

Fe-Ni-Ta

B. Yang, C. Guo, C. Li, Z. Du, Experimental Investigation and Thermodynamic Modelling

of the Fe-Ni-Ta System, J. Phase Equilib. Diffus. (2020) 41:500–521.

 

Fe-Ni-Ti

J. De Keyzer, et al. CALPHAD 33 (2009) 109-123

Z. Zhu and I.-H. Jung unpublished (2018)

 

Fe-Ni-W

A. Fernandez Guillermet,L.Ostlund, Met.Trans.17A (1986) 1809-1823

 

Fe-Ni-Zr

In-Ho Jung (2020), unpublished work

Based on S.Y. Yang et al.: Experimental investigation of phase equilibria in the Ni–Fe–Zr ternary system, J. Mater. Res., Vol. 31, 2016, 2407-2424.

 

Fe-P

Z. You, M. Paek, In-Ho Jung, unpublished work (2018)

 

Fe-P-S

In-Ho Jung, private communication, 2004

 

Fe-Pb

A. T. Dinsdale and D. Gohil, NPL, unpublished work (1987).

Update: SGTE Update database.'

 

Fe-Pr

Bikram Konar, Junghwan Kim and In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = La, Ce, Pr, Nd and Sm”, Journal of Phase Equilibria and Diffusion, 2016, vol. 37(4), 438-458.

 

Fe-S

FTmisc database

 

Fe-S-Zn

YE Lee and In-Ho Jung, unpublished work 2012

 

Fe-Sb

Klaus Hack, GTT, 2003.

 

Fe-Sc

Bikram Konar, In-Ho Jung, unpublished work (2021)

 

Fe-Si

S. Cui, In-Ho Jung, “Critical reassessment of the Fe-Si system”, Calphad, vol. 56, 2017, pp. 108-125.

 

Fe-Si-O

M. Paek, In-Ho Jung, unpublished work (2018)

 

Fe-Si-P

Z. You, In-Ho Jung, unpublished work (2019)

 

Fe-Si-S

In-Ho Jung, private communication, 2004

 

Fe-Sm

Bikram Konar, Junghwan Kim and In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = La, Ce, Pr, Nd and Sm”, Journal of Phase Equilibria and Diffusion, 2016, vol. 37(4), 438-458.

 

Fe-Sn

K C H Kumar, P Wollants, L Delaey, CALPHAD 20(1996)2 p 139-149.

 

Fe-Sn-S

In-Ho Jung, private communication, 2004

 

Fe-Ta

V.B. Rajkumar, K.C. Hari Kumar, Gibbs energy modelling of Fe–Ta system by Calphad

method assisted by experiments and ab initio calculations, CALPHAD, 48(2015)157–165

(slightly different by In-Ho Jung (2021))

 

Fe-Tb

Bikram Konar, Junghwan Kim and In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = Gd, Tb, Dy, Ho, Er, Tm, Lu, and Y”, Journal of Phase Equilibria and Diffusion, 2017, vol. 38, Issue 4, pp 509–542.

 

Fe-Ti

L.F.S.Dumitrescu, M.Hillert, N.Saunders, J.Phase Equilibria 19(1998) 441-448

 

Fe-Ti-O

M. Paek, In-Ho Jung, unpublished work (2018)

 

Fe-Ti-S

In-Ho Jung, unpublished work (2018)

 

Fe-Tm

Bikram Konar, Junghwan Kim and In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = Gd, Tb, Dy, Ho, Er, Tm, Lu, and Y”, Journal of Phase Equilibria and Diffusion, 2017, vol. 38, Issue 4, pp 509–542.

 

Fe-V

W.Huang, Z.Metallkde. 82 (1991) p 391-401

 

Fe-V-O

M. Paek, In-Ho Jung, unpublished work (2018)

 

Fe-V-S

In-Ho Jung, unpublished work (2018)

 

Fe-W

P.Gustafson, Metall.Trans. 18A (1987) p 175-188

 

Fe-W-S

In-Ho Jung, private communication, 2004

 

Fe-Y

Bikram Konar, Junghwan Kim and In-Ho Jung, “Critical systematic evaluation and thermodynamic optimization of the Fe-RE system: RE = Gd, Tb, Dy, Ho, Er, Tm, Lu, and Y”, Journal of Phase Equilibria and Diffusion, 2017, vol. 38, Issue 4, pp 509–542.

 

Fe-Zn

J. Kim, In-Ho Jung, unpublished work, 2017.

Fe-Zn-Zr

In-Ho Jung, unpublished work 2022

 

Fe-Zr

C.Servant, C.Gueneau, I.Ansara, J.Alloys and Compounds 247 (1995) 19-26

 

Fe-Zr-O

In-Ho Jung, unpublished work, 2018.

 

Fe-Zr-S

In-Ho Jung, private communication, 2004

 

Dy-Mn

J. Kim and I.-H. Jung, “Thermodynamic modeling of the Mn-Y and Mn-Gd systems for the application of RE in Mg alloy development”, Can. Metall. Quarterly, Vol. 52 (2013) 311–320.

 

Gd-Ni

A. Pachauri and I.-H. Jung, unpublished work, 2018.

 

Gd-Si

J. Kim, In-Ho Jung, “Critical evaluation and thermodynamic optimization of the Si-RE systems: Part II. Si-RE system (RE = Gd, Tb, Dy, Ho, Er, Tm, Lu and Y)”, J. Chem. Thermodynamics, 2015, vol. 81, pp. 273-297.

 

H-Mg

J.-P. Harvey, Master Thesis, Ecole Polytechnique de Montreal (2006).

 

H-Ni

J.-P. Harvey, Master Thesis, Ecole Polytechnique de Montreal (2006).

 

H-Si

J.-P. Harvey, Master Thesis, Ecole Polytechnique de Montreal (2006).

 

H-Ti

T.-H. Kim, In-Ho Jung, unpublished work, 2018

 

H-V

J.-M Cheon, In-Ho Jung, unpublished work, 2018

 

H-Zn

(only liquid) J.-P. Harvey, Master Thesis, Ecole Polytechnique de Montreal (2006).

 

H-Zr

T.-H. Kim, In-Ho Jung, unpublished work, 2018

 

Hf-Mo

G. Shao, Intermetallics, 10, 2002, 429-434.

 

Hf-Nb

G. Ghosh, A. van de Walle, M. Asta, G.B. Olson, Calphad, 26 (2002) 491-511.

 

Hf-Ni

T. Wang, Z.Jin, Ji-C. Zhao, Z. Metallkunde 92 (2001) 441-446.

 

Hf-Si

FTlite database

 

Hf-Ta

A. Fernandez Guillermet, Z. Metallkunde 86 (1996) 382-387.

 

Hf-Ti

H. Bitterman, P.Rogl, J. Phase Equilibria 18 (1997) 24-47.

 

Hf-V

P.J.Spencer, June 2011, based on parameters for the Zr-V system.

 

Hf-W

G. Shao, Intermetallics, 10 (2002) 429-434.

 

Hf-Zr

L.Lin, L.Delaey, O.van der Biest, P.Wollants,  Scripta Mat. 34 (1996) 1411-1416.

 

Ho-Mn

J. Kim, M. Paliwal, Z. Zhou, H. Kim, and I.-H. Jung, “Critical systematic evaluation and thermodynamic optimization of the Mn-RE system (RE = Tb, Dy, Ho, Er, Tm and Lu) with key experiments for the Mn-Dy system”, J. Phase Equilibria and Diffusion, 2014, vol. 35 (6), pp. 670-694.

 

Ho-Ni

A. Pachauri and I.-H. Jung, unpublished work, 2018.

 

Ho-Si

J. Kim, In-Ho Jung, “Critical evaluation and thermodynamic optimization of the Si-RE systems: Part II. Si-RE system (RE = Gd, Tb, Dy, Ho, Er, Tm, Lu and Y)”, J. Chem. Thermodynamics, 2015, vol. 81, pp. 273-297.

 

La-Mn

J Kim, I.-H. Jung, “Critical systematic evaluation and thermodynamic optimization of the Mn-RE system: RE = La, Ce, Pr, Nd and Sm”, J. Alloy. Compd., 2012, vol. 525, pp. 191-201.

 

La-Ni

A. Pachauri and I.-H. Jung, unpublished work, 2018.

 

La-Si

J. Kim, In-Ho Jung, “Critical evaluation and thermodynamic optimization of the Si-RE systems: Part I. Si-RE system (RE = La, Ce, Pr, Nd and Sm)”, J. Chem. Thermodynamics, 2015, vol. 81, pp. 253-272.

 

Lu-Mn

J. Kim, M. Paliwal, Z. Zhou, H. Kim, and I.-H. Jung, “Critical systematic evaluation and thermodynamic optimization of the Mn-RE system (RE = Tb, Dy, Ho, Er, Tm and Lu) with key experiments for the Mn-Dy system”, J. Phase Equilibria and Diffusion, 2014, vol. 35 (6), pp. 670-694.

 

Lu-Si

J. Kim, In-Ho Jung, “Critical evaluation and thermodynamic optimization of the Si-RE systems: Part II. Si-RE system (RE = Gd, Tb, Dy, Ho, Er, Tm, Lu and Y)”, J. Chem. Thermodynamics, 2015, vol. 81, pp. 273-297.

 

Mg-Mo

Liquid miscibility gap, estimated, FTlite database

 

Mg-Mn

Y.-B. Kang, A.D. Pelton. P. Chartrand, P. Spencer and C. Fuerst, J. Phase Equil. Diff. 28 (2007), pp. 342-354

 

Mg-Nd

FTlite database

 

Mg-Ni

M.-A. Van Ende, and I.-H. Jung, unpublished (2015): liquid was changed to MQM and solid phases were reoptimized.

 

Mg-P

Estimated based on Ca-P system

 

Mg-Pr

FTlite database

 

Mg-Si

J.-P. Harvey, M.A.Sc. thesis, Ecole Polytechnique, 2006 (VLAB Project); Vol. Data F. Gemme, CRCT, 2003 (VLAB project)

 

Mg-Sn

FTlite database

 

Mg-Ta

Liquid miscibility gap, estimated, FTlite database

 

Mg-Tb

FTlite database

 

Mg-W

Liquid miscibility gap, estimated, FTlite database

 

Mg-Zn

Liquid: P.J. Spencer, 2006 (GM Project); Solids from COST-507

 

Mg-Zr

FTlite database

 

Mn-Mo

B.J.Lee, KRISS, unpublished work, 1993-1995

 

Mn-N

Z. You, M. Paek, In-Ho Jung, “Critical Evaluation and Optimization of the Fe-N, Mn-N and Fe-Mn-N Systems”, J. Phase Equilibria and Diffusion, 2018, vo. 39, pp. 650-677.

 

Mn-Nb

I.-H. Jung, unpublished work (2020)

 

Mn-Nd

J Kim, I.-H. Jung, “Critical systematic evaluation and thermodynamic optimization of the Mn-RE system: RE = La, Ce, Pr, Nd and Sm”, J. Alloy. Compd., 2012, vol. 525, pp. 191-201.

 

Mn-Ni

NPL, unpublished work (1989)

 

Mn-Ni-V

P. Franke, private communication to SGTE, 2008

 

Mn-P

Z. You, M. Paek, In-Ho Jung, unpublished work 2018

 

Mn-Pb

SGTE database

 

Mn-Pr

J Kim, I.-H. Jung, “Critical systematic evaluation and thermodynamic optimization of the Mn-RE system: RE = La, Ce, Pr, Nd and Sm”, J. Alloy. Compd., 2012, vol. 525, pp. 191-201.

 

Mn-S

FTmisc database

 

Mn-Sc

J Kim, I.-H. Jung, unpublished work (2012)

 

Mn-Si

M. Paek, J Pak, Y.-B. Kang, Phase equilibria and thermodynamics of Mn-C, Mn-Si, Si-C binary systems and Mn-Si-C ternary system by critical evaluation, combined with experiment and thermodynamic modeling. CALPHAD 46, 92-102 (2014)

 

Mn-Sm

J Kim, I.-H. Jung, “Critical systematic evaluation and thermodynamic optimization of the Mn-RE system: RE = La, Ce, Pr, Nd and Sm”, J. Alloy. Compd., 2012, vol. 525, pp. 191-201.

 

Mn-Sn

J. Miettinen: CALPHAD, 2001, 25(1), 43-58

 

Mn-Ta

Yan et al. J Alloy and Comp, 2021, 158715

 

Mn-Tb

J. Kim, M. Paliwal, Z. Zhou, H. Kim, and I.-H. Jung, “Critical systematic evaluation and thermodynamic optimization of the Mn-RE system (RE = Tb, Dy, Ho, Er, Tm and Lu) with key experiments for the Mn-Dy system”, J. Phase Equilibria and Diffusion, 2014, vol. 35 (6), pp. 670-694.

 

Mn-Ti

N.Saunders, COST 507 (1998) ISBN 92-828-3902-8 p 241-244

 

Mn-Tm

J. Kim, M. Paliwal, Z. Zhou, H. Kim, and I.-H. Jung, “Critical systematic evaluation and thermodynamic optimization of the Mn-RE system (RE = Tb, Dy, Ho, Er, Tm and Lu) with key experiments for the Mn-Dy system”, J. Phase Equilibria and Diffusion, 2014, vol. 35 (6), pp. 670-694.

 

Mn-V

W.Huang, Metall.Trans. 22A (1991) p 1911-1920

 

Mn-W

I-H. Jung, unpublished work, (2020)

 

Mn-Y

J. Kim and I.-H. Jung, “Thermodynamic modeling of the Mn-Y and Mn-Gd systems for the application of RE in Mg alloy development”, Can. Metall. Quarterly, Vol. 52 (2013) 311–320.

 

Mn-Zn

Y.-B. Kang, CRCT, 2005 (GM project)

 

Mn-Zr

H.J. Seifert, J. Groebner, F. Aldinger, F.H. Hayes, G. Effenberg, C. Baetzner, H. Flandorfer, P. Rogl, A. Saccone, R. Ferro, Proc.3rd. International Magnesium Conference, Ed. G. W. Lorimer, Inst.of Materials, London, 1997, pp. 257-270.;

 

Mo-N

In-Ho Jung, modification of liquid (2018)

K.Frisk, TRITA-MAC 393 (1989)

 

Mo-N-Nb

 

Mo-N-Ni

K.Frisk, TRITA-MAC 433 (1990)

 

Mo-Nb

P.Y.Chevalier, Thermodata SGTE report

 

Mo-Nb-Ni

Mo-nb-ni –> “Ni3M solid solution” (O) newly done FS82. – only addition of Ni3M solid solution.

Complete solid solutions: Ni3Ta-Ni3Nb, Ni3Mo-Ni3Ta : D0a structure.  : done 

 

Mo-Nb-Ni-Ta

Complete solid solutions: Ni3Ta-Ni3Nb, Ni3Mo-Ni3Ta : D0a structure.  : Ni-Mo rich region??

 

Mo-Ni

K.Frisk, Calphad 14 (1990) p 311-320

Changed to Cui et al.MMTA. 1999, p.2735

 

Mo-Ni-Ta

Y. Cui, X. Lu, and Z. Jin, Experimental Study and Thermodynamic Assessment of the Ni-Mo-Ta Ternary System, Metall. Mater. Trans. A, 30A (1999) p. 2735

 

Mo-P

SGTE database

 

Mo-Pb

Liquid miscibility gap, estimated, FTlite database

 

Mo-Sc

In-Ho Jung, unpublished work 2022, reoptimization based on Wang et al. Journal of Phase Equilibria and Diffusion Vol. 36 No. 1 2015

 

Mo-Si

C.Vahlas, P.Y.Chevalier, E.Blanquet, Calphad 13 (1989) p 273-292

 

Mo-Ta

Y. Cui, Private communication to SGTE, 1999.

 

Mo-Ti

H.-J. Chung, J.-H. Shim, D.N. Lee, J. Alloys Comp. 282 (1999) 142-148

 

Mo-V

J. Bratberg, K. Frisk, Calphad, vol. 26 (2020) 459-476

 

Mo-W

P.Gustafson, Z.Metallkde. 79 (1988) p 388-396

 

Mo-Zn

Liquid miscibility gap, estimated, FTlite database

 

N-Nb

W.Huang, Metall.Mater.Trans.A, 27A (1996) 3591-3600

 

N-Nb-Ti

B.J.Lee, Met.Mater.Trans.A 32A (2001) 2423-2439

 

N-Ni

K.Frisk, Z.Metallkde. 82 (1991) p 59-66; 

 

N-Si

Z.You, M. Paek, In-Ho Jung, unpublished work, 2018

 

N-Si-Ti

X. Ma, C. Li, W. Zhang, J.Alloys.Comp. 394 (2005) 138-147

 

N-Ta

SGTE database (only Liquid)

 

N-Ti

K Zeng, COST 507 (1998) ISBN 92-828-3902-8 p 253-255;

-> (update the phase diagram figure)

 

N-V

H.Ohtani, M.Hillert, Calphad 15 (1991) p 11-24

 

N-W

A.F.Guillermet, S.Jonsson, Z.Metallkde. 84 (1993) p 106-117

Liquid slight different

 

Nb-Ta

W Xiong, Y Du, Y Li, B Y Huang, H H Xu, H L Chen, Z Pan, Calphad,  28 (2004) 133-140.

 

Nb-Ni

A. Bolcavage, U.R. Kattner, J. Phase Equilibria 17 (1996) 92–100.

I.-H. Jung, unpublished work (2021): Liquid was modified to MQM, and Ni6Nb7 was slightly modified.

 

Nb-Ti

N.Saunders, COST 507, Final Report, Volume 2 (1998) 256-260

 

Nb-V

K.C.H.Kumar, P Wollants, L Delaey, CALPHAD 18(1994)1 p 71-79.

 

Nb-W

W.Huang, Private Communication (1995)

 

Nb-Zr

A.F. Guillermet, Z. Metallkde. 82 (1991), pp. 478-487.

 

Nd-Ni

A. Pachauri and I.-H. Jung, unpublished work, 2018.

 

Nd-Si

J. Kim, In-Ho Jung, “Critical evaluation and thermodynamic optimization of the Si-RE systems: Part I. Si-RE system (RE = La, Ce, Pr, Nd and Sm)”, J. Chem. Thermodynamics, 2015, vol. 81, pp. 253-272.

 

Ni-P

Z. You, M. Paek, In-Ho Jung, unpublished work (2018)

 

Ni-Pb

P. Chartrand, CRCT, 2003 (VLAB project)

 

Ni-Pr

A. Pachauri and I.-H. Jung, unpublished work, 2018.

 

Ni-S

FTmisc database

 

Ni-Sc

Z.Cao Thermochimica Acta 586(2014)

 

Ni-Si

D Kang, In-Ho Jung, unpublished work (2010)

 

Ni-Sm

A. Pachauri and I.-H. Jung, unpublished work, 2018.

 

Ni-Sn

S.J. Baek, I.-H. Jung, unpublished work (2020)

 

Ni-Ta

C. Zhou, C. Guo, C. Li, Z. Du, Thermochimica Acta 666 (2018) 135–147.

(changed in FSStel82)

 

Ni-Tb

A. Pachauri and I.-H. Jung, unpublished work, 2018.

 

Ni-Ti

Z. Zhou, In-Ho Jung, unpublished work (2018)

 

Ni-V

J.Korb, K.Hack, COST 507 (1998) ISBN 92-828-3902-8 p 261-263

 

Ni-W

P.Gustafson, A.Gabriel,I.Ansara, Z.Metallkde. 78 (1987) p 151-156

 

Ni-Y

COST 501

 

Ni-Zn

In-Ho Jung, unpublished work 2022 : only liquid phase modeled.

 

Ni-Zr

G. Ghosh, J.Mater.Res. 9 (1994), pp. 598-616.

 

P-Sb

SGTE database

 

P-Si

I.-H. Jung, Y. Zhang, “Thermodynamic calculations for the dephosphorization of silicon using molten slag”, JOM, 2012, 64 (8), pp. 973-981.

 

P-Sn

A. Pachauri and I.-H. Jung, unpublished work, 2018.

 

P-Zn

A. Pachauri and I.-H. Jung, unpublished work, 2018.

 

Pb-Sb

SGTE database

 

Pb-Si

SGTE database

 

Pb-Sn

SGTE database

 

Pb-Zn

T Jantzen, P J Spencer, Calphad 22(1998)3 p 417-434.

 

Pb-Zr

SGTE database

 

Pr-Si

J. Kim, In-Ho Jung, “Critical evaluation and thermodynamic optimization of the Si-RE systems: Part II. Si-RE system (RE = Gd, Tb, Dy, Ho, Er, Tm, Lu and Y)”, J. Chem. Thermodynamics, 2015, vol. 81, pp. 273-297.

 

S-Fe-Zn

YE Lee and In-Ho Jung, unpublished work 2012

 

S-Sn

In-Ho Jung, unpublished work 2022

 

S-Zn

YE Lee and In-Ho Jung, unpublished work 2012

 

Sb-Si

FTlite database

 

Sb-Zn

L A Zabdyr, Calphad 21(1997)3 p 349-358.

 

Sc-Si

J. Kim, In-Ho Jung, unpublished (2012).

 

Sc-V

In-Ho Jung, unpublished work 2022.

 

Si-Sn

M.H.G.Jacobs, P.J.Spencer, Calphad  20 (1996) 89-91

 

Si-Sn-Ti

C. Tiwary, M. Paliwal, S. Kashyap, P. Pandey, S. Sarkar, I. Kundu, S. Bhaskar, In-Ho Jung, K. Chattopadhyay, D. Banerjee, Materials Science & Engineering A, Vol. 770, 2020, 138472.

 

Si-Ta

C. Vahlas, P-Y. Chevalier, E. Blanquet, CALPHAD 13 (1989) 273-292.

 

Si-Ti

H. Rong, In-Ho Jung, unpublished work, 2011

 

Si-V

M.H.Rand, COST 507 (1998) ISBN 2-87263-156-9, p 182

 

Si-W

C.Vahlas, P.Y.Chevalier, E.Blanquet, Calphad 13 (1989) p 273-292

 

Si-Zn

M. H. G. Jacobs, P J Spencer, Calphad 20 (1996) 3 p 307-320

 

Si-Zr

COST 507, pp. 280-283.

 

Sn-Ti

Kevin Han, In-Ho Jung, unpublished work, 2011.

 

Sn-V

Kevin Han, In-Ho Jung, unpublished work, 2011.

 

Sn-Zn

S. Fries, H. L. Lukas, COST 507 (1998) ISBN 92-828-3902-8 p 288-289.

 

Sn-Zr

COST 507, pp. 290-292.

 

Ta-Ti

N. Saunders in COST 507 (1998) ISBN 92-828-3902-8 p 203-296.

 

Ta-V

C.A. Danon, C. Servant. Journal of Alloys and Compounds, 366 (2004) 191-200;

 

Ta-W

A.F. Guillermet, W. Huang, unpublished research, KTH, 1995.

 

Ta-Zr

A. Fernandez Guillermet, J. Alloys Compounds,  226 (1995) 174-184.

LIQUID and BCC phases modified by P.J. Spencer, June 2011.

 

Ti-V

N.Saunders, COST 507 (1998) ISBN 92-828-3902-8 p 297-298

 

Ti-W

N.Saunders, COST 507 (1998) ISBN 92-828-3902-8 p 299-302

 

Ti-Zn

In-Ho Jung, unpublished work 2022, reoptimization based on K. Doi, S. Ono, H. Ohtani, M. Hasebe: J. Phase Equilib. Diff., 2006, 27(1), 63-74

 

Ti-Zr

K.C. Hari Kumar, P.Wollants, L.Delaey, J. Alloys Compounds, 206 (1994) 121-7.

 

V-W

J. Bratberg, Z. Metallkde. 96 (2005) 335-344.

 

V-Zn

FTlite database

 

V-Zr

J.Korb, K.Hack, in COST507, Thermochemical Database for Light Metal Alloys,   

Volume 2, eds. I.Ansara, A.T. Dinsdale, M.H.Rand, July 1998, EUR 18499.

 

W-Zn

FTlite database

 

W-Zr

Thermodata, private communication to SGTE, July 2005.

 

Y-Zn

Zhu et al., Journal of Alloys and Compounds, Volume 641, 25 August 2015, Pages 261-271

 

Zn-Zr

In-Ho Jung, unpublished work 2022 (Zr-rich region is needed to be improved; no inverse liquid miscibility gap)