A New Family of Ternary Intermetallic Compounds with Dualistic Atomic Ordering – The ZIP Phases

Matheus A. Tunes; Sean M. Drewry; Franziska Schmidt; James Anthony Valdez; Matthew M. Schneider; Caitlin Anne Kohnert; Tarik A. Saleh; Saryu Fensin; Stuart A. Maloy; Cláudio Geraldo Schön; Sylvain Dubois; Omri Tabo; Anna Eyal; Amit Keren; Asaf Pesach; Ganesh K. Nayak; Stavros‐Richard G. Christopoulos; Marco Molinari; Marcus Hans; Nick Goossens; Shuigen Huang; Jochen M. Schneider; Per O. Å. Persson; Jozef Vleugels; Konstantina Lambrinou

A New Family of Ternary Intermetallic Compounds with Dualistic Atomic Ordering – The ZIP Phases

Matheus A. Tunes, Sean M. Drewry, Franziska Schmidt, James Anthony Valdez, Matthew M. Schneider, Caitlin Anne Kohnert, Tarik A. Saleh, Saryu Fensin, Stuart A. Maloy, Cláudio Geraldo Schön, Sylvain Dubois, Omri Tabo, Anna Eyal, Amit Keren, Asaf Pesach, Ganesh K. Nayak, Stavros‐Richard G. Christopoulos, Marco Molinari, Marcus Hans, Nick GoossensShuigen Huang, Jochen M. Schneider, Per O. Å. Persson, Jozef Vleugels, Konstantina Lambrinou

Chair of Nonferrous Metallurgy (520)

Research output: Contribution to journal › Article › Research › peer-review

Abstract

A new family of nanostructured ternary intermetallic compounds − named the ZIP phases − is introduced in this work. The ZIP phases exhibit dualistic atomic ordering, i.e., they form two structural variants: one with the fcc diamond cubic structure (space group Fd (Formula presented.) m) and one with the hexagonal structure (space group P6 3/mmc). They are also characterized by metallic behavior, ionic bonding, and atomic zigzagging. Powder metallurgical routes involving pressure-assisted densification are adopted to demonstrate ZIP phase synthesis in the Nb-Si-Ni, Nb-Si-Co, Ta-Si-Ni, V-Si-Ni, and Nb-Si-Fe ternary systems. Crucially, reactive hot pressing is capable of producing high-purity ZIP phase materials after the judicious, elemental system-specific optimization of the processing route. Synthesis of phase-pure materials – demonstrated in the Nb-Si-Ni ternary system by the synthesis of quasi phase-pure Nb 3SiNi 2 and Ni 3SiNb 2 ZIP phase-based materials – is a steppingstone to the prospective exploitation of the ZIP phases. Characterization of Nb 3SiNi 2 and Ni 3SiNb 2 involves crystal structure determination, spatially resolved chemical analysis, and determination of select thermal, electrical, magnetic, mechanical, and physical properties. Density functional theory is used to assess the stability of Nb 3SiNi 2 & Ni 3SiNb 2 and derivative binary compounds at different temperatures, also exploring the exfoliation of these two ZIP phases along specific surfaces to produce 2D derivatives.

Original language	English
Article number	e08168
Number of pages	23
Journal	Advanced materials
Publication status	Published - 10 Sept 2025

Bibliographical note

Publisher Copyright:
© 2025 The Author(s). Advanced Materials published by Wiley-VCH GmbH.

Keywords

Intermetallic compounds (IMCs)
MAX phases
MXenes
nanolaminated hexagonal solids & 2D derivatives
nanostructured solids
ZIP phases

Cite this

Tunes, M. A., Drewry, S. M., Schmidt, F., Valdez, J. A., Schneider, M. M., Kohnert, C. A., Saleh, T. A., Fensin, S., Maloy, S. A., Schön, C. G., Dubois, S., Tabo, O., Eyal, A., Keren, A., Pesach, A., Nayak, G. K., Christopoulos, SR. G., Molinari, M., Hans, M., ... Lambrinou, K. (2025). A New Family of Ternary Intermetallic Compounds with Dualistic Atomic Ordering – The ZIP Phases. Advanced materials, Article e08168.

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title = "A New Family of Ternary Intermetallic Compounds with Dualistic Atomic Ordering – The ZIP Phases",

abstract = "A new family of nanostructured ternary intermetallic compounds − named the ZIP phases − is introduced in this work. The ZIP phases exhibit dualistic atomic ordering, i.e., they form two structural variants: one with the fcc diamond cubic structure (space group Fd (Formula presented.) m) and one with the hexagonal structure (space group P6 3/mmc). They are also characterized by metallic behavior, ionic bonding, and atomic zigzagging. Powder metallurgical routes involving pressure-assisted densification are adopted to demonstrate ZIP phase synthesis in the Nb-Si-Ni, Nb-Si-Co, Ta-Si-Ni, V-Si-Ni, and Nb-Si-Fe ternary systems. Crucially, reactive hot pressing is capable of producing high-purity ZIP phase materials after the judicious, elemental system-specific optimization of the processing route. Synthesis of phase-pure materials – demonstrated in the Nb-Si-Ni ternary system by the synthesis of quasi phase-pure Nb 3SiNi 2 and Ni 3SiNb 2 ZIP phase-based materials – is a steppingstone to the prospective exploitation of the ZIP phases. Characterization of Nb 3SiNi 2 and Ni 3SiNb 2 involves crystal structure determination, spatially resolved chemical analysis, and determination of select thermal, electrical, magnetic, mechanical, and physical properties. Density functional theory is used to assess the stability of Nb 3SiNi 2 & Ni 3SiNb 2 and derivative binary compounds at different temperatures, also exploring the exfoliation of these two ZIP phases along specific surfaces to produce 2D derivatives.",

keywords = "Intermetallic compounds (IMCs), MAX phases, MXenes, nanolaminated hexagonal solids & 2D derivatives, nanostructured solids, ZIP phases",

author = "Tunes, {Matheus A.} and Drewry, {Sean M.} and Franziska Schmidt and Valdez, {James Anthony} and Schneider, {Matthew M.} and Kohnert, {Caitlin Anne} and Saleh, {Tarik A.} and Saryu Fensin and Maloy, {Stuart A.} and Sch{\"o}n, {Cl{\'a}udio Geraldo} and Sylvain Dubois and Omri Tabo and Anna Eyal and Amit Keren and Asaf Pesach and Nayak, {Ganesh K.} and Christopoulos, {Stavros‐Richard G.} and Marco Molinari and Marcus Hans and Nick Goossens and Shuigen Huang and Schneider, {Jochen M.} and Persson, {Per O. {\AA}.} and Jozef Vleugels and Konstantina Lambrinou",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Advanced Materials published by Wiley-VCH GmbH.",

year = "2025",

month = sep,

day = "10",

language = "English",

journal = "Advanced materials",

issn = "0935-9648",

publisher = "Wiley-Blackwell, USA",

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Tunes, MA, Drewry, SM, Schmidt, F, Valdez, JA, Schneider, MM, Kohnert, CA, Saleh, TA, Fensin, S, Maloy, SA, Schön, CG, Dubois, S, Tabo, O, Eyal, A, Keren, A, Pesach, A, Nayak, GK, Christopoulos, SRG, Molinari, M, Hans, M, Goossens, N, Huang, S, Schneider, JM, Persson, POÅ, Vleugels, J & Lambrinou, K 2025, 'A New Family of Ternary Intermetallic Compounds with Dualistic Atomic Ordering – The ZIP Phases', Advanced materials.

TY - JOUR

T1 - A New Family of Ternary Intermetallic Compounds with Dualistic Atomic Ordering – The ZIP Phases

AU - Tunes, Matheus A.

AU - Drewry, Sean M.

AU - Schmidt, Franziska

AU - Valdez, James Anthony

AU - Schneider, Matthew M.

AU - Kohnert, Caitlin Anne

AU - Saleh, Tarik A.

AU - Fensin, Saryu

AU - Maloy, Stuart A.

AU - Schön, Cláudio Geraldo

AU - Dubois, Sylvain

AU - Tabo, Omri

AU - Eyal, Anna

AU - Keren, Amit

AU - Pesach, Asaf

AU - Nayak, Ganesh K.

AU - Christopoulos, Stavros‐Richard G.

AU - Molinari, Marco

AU - Hans, Marcus

AU - Goossens, Nick

AU - Huang, Shuigen

AU - Schneider, Jochen M.

AU - Persson, Per O. Å.

AU - Vleugels, Jozef

AU - Lambrinou, Konstantina

PY - 2025/9/10

Y1 - 2025/9/10

N2 - A new family of nanostructured ternary intermetallic compounds − named the ZIP phases − is introduced in this work. The ZIP phases exhibit dualistic atomic ordering, i.e., they form two structural variants: one with the fcc diamond cubic structure (space group Fd (Formula presented.) m) and one with the hexagonal structure (space group P6 3/mmc). They are also characterized by metallic behavior, ionic bonding, and atomic zigzagging. Powder metallurgical routes involving pressure-assisted densification are adopted to demonstrate ZIP phase synthesis in the Nb-Si-Ni, Nb-Si-Co, Ta-Si-Ni, V-Si-Ni, and Nb-Si-Fe ternary systems. Crucially, reactive hot pressing is capable of producing high-purity ZIP phase materials after the judicious, elemental system-specific optimization of the processing route. Synthesis of phase-pure materials – demonstrated in the Nb-Si-Ni ternary system by the synthesis of quasi phase-pure Nb 3SiNi 2 and Ni 3SiNb 2 ZIP phase-based materials – is a steppingstone to the prospective exploitation of the ZIP phases. Characterization of Nb 3SiNi 2 and Ni 3SiNb 2 involves crystal structure determination, spatially resolved chemical analysis, and determination of select thermal, electrical, magnetic, mechanical, and physical properties. Density functional theory is used to assess the stability of Nb 3SiNi 2 & Ni 3SiNb 2 and derivative binary compounds at different temperatures, also exploring the exfoliation of these two ZIP phases along specific surfaces to produce 2D derivatives.

AB - A new family of nanostructured ternary intermetallic compounds − named the ZIP phases − is introduced in this work. The ZIP phases exhibit dualistic atomic ordering, i.e., they form two structural variants: one with the fcc diamond cubic structure (space group Fd (Formula presented.) m) and one with the hexagonal structure (space group P6 3/mmc). They are also characterized by metallic behavior, ionic bonding, and atomic zigzagging. Powder metallurgical routes involving pressure-assisted densification are adopted to demonstrate ZIP phase synthesis in the Nb-Si-Ni, Nb-Si-Co, Ta-Si-Ni, V-Si-Ni, and Nb-Si-Fe ternary systems. Crucially, reactive hot pressing is capable of producing high-purity ZIP phase materials after the judicious, elemental system-specific optimization of the processing route. Synthesis of phase-pure materials – demonstrated in the Nb-Si-Ni ternary system by the synthesis of quasi phase-pure Nb 3SiNi 2 and Ni 3SiNb 2 ZIP phase-based materials – is a steppingstone to the prospective exploitation of the ZIP phases. Characterization of Nb 3SiNi 2 and Ni 3SiNb 2 involves crystal structure determination, spatially resolved chemical analysis, and determination of select thermal, electrical, magnetic, mechanical, and physical properties. Density functional theory is used to assess the stability of Nb 3SiNi 2 & Ni 3SiNb 2 and derivative binary compounds at different temperatures, also exploring the exfoliation of these two ZIP phases along specific surfaces to produce 2D derivatives.

KW - Intermetallic compounds (IMCs)

KW - MAX phases

KW - MXenes

KW - nanolaminated hexagonal solids & 2D derivatives

KW - nanostructured solids

KW - ZIP phases

UR - https://doi.org/10.1002/adma.202308168

UR - http://www.scopus.com/inward/record.url?scp=105015459511&partnerID=8YFLogxK

M3 - Article

SN - 0935-9648

JO - Advanced materials

JF - Advanced materials

M1 - e08168

ER -

A New Family of Ternary Intermetallic Compounds with Dualistic Atomic Ordering – The ZIP Phases

Abstract

Bibliographical note

Keywords

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Cite this