Nitridation of Magnesium and its Application in Corrosion Resistance: A Review

doi:10.1007/s40195-025-01912-3

Abstract

Abstract:

Metallic magnesium and its alloys, as new types of metallic structural materials, show great application potential in fields such as aerospace, electronics, and biomedicine. However, magnesium is chemically active and highly susceptible to oxidation and corrosion in various environmental conditions, which can compromise its structural integrity and significantly reduce its service life. Therefore, it is of great significance to strengthen the development and application of corrosion protection technology for magnesium materials. At present, the nitridation of magnesium and its alloys is regarded as an effective surface treatment method to enhance corrosion resistance. To create durable nitrided layers on magnesium substrates with long-term stability, it is essential to thoroughly comprehend the influence of various techniques and processing conditions, as well as the resulting layer composition and microstructure. Additionally, a detailed understanding of how these fabricated layers behave in corrosive environments is crucial for optimizing their performance. This paper systematically reviews the research achievements and latest progress in the surface nitridation on magnesium alloys. The principles, advantages, drawbacks of different nitridation process, as well as their applications in enhancing the corrosion resistance of magnesium alloys are discussed. Furthermore, the paper summarizes the main technologies in the fabrication of magnesium nitride films, such as pulsed laser deposition, low-pressure chemical vapor deposition, reactive magnetron sputtering, thermal plasma synthesis, and molecular beam epitaxy, which offers a valuable reference for experimental research on magnesium nitride film. Finally, it also discusses the challenges and prospects of the research on the surface nitriding of magnesium and its alloys.

Key words: Magnesium, Nitridation technology, Surface modification, Corrosion resistance, Magnesium nitride

Junchen Fan, Ruidong Liu, Xiaofang Wang. Nitridation of Magnesium and its Application in Corrosion Resistance: A Review[J]. Acta Metallurgica Sinica (English Letters), 2025, 38(11): 1873-1890.

Figures/Tables 14

References 87

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Technology	Characteristics	Process parameters	Composition, Structure	Reference
Gas nitriding	Simple process, high temperatures, long processing times, low temperature nitriding can be achieved when combined with integral mechanical alloying	Working temperature: 650 °C -800 °C	Mg₃N₂/ cubic anti-bixbyite	[39]
Gas nitriding		Conditions: N₂ (1.0 L/min)	Mg₃N₂/ cubic anti-bixbyite	[39]
Ion beam ion implantation (IBII)	Controllable composition, limitations on size and shape of workpiece, high cost	Implantation dose: 4 × 10¹⁷ ions/cm²	Mg₃N₂/ cubic anti-bixbyite	[32]
		Energy of implantation: 65 keV
		Working temperature: 25 °C
Plasma immersion ion implantation (PIII)	It has the advantages of IBII and overcomes the disadvantage of its “line-of-sight” limitation to realize all direction ion implantation, but the injected layer is thin and the preparation efficiency is low	Negative high voltage: 35 kV	Mg₃N₂/ cubic anti-bixbyite	[56]
		Frequency: 200 Hz
		Pulse width: 35 μs
		Working pressure: 2 × 10⁻¹ Pa N₂
		Working temperature: 25 °C
Plasma nitriding	Short nitriding cycle, small substrate deformation, adjustable chemical composition and thickness, corrosion protection can be achieved in combination with coating technology	Materials: Ti (5 µm)/Al (10 µm)/AZ91D	TiN/ NaCl; Al₁₂Mg₁₇	[37]
		Working temperature: 400 °C − 460 °C
		Conditions: 300 Pa N₂/12 h
DBD nitriding	Simple process, easy operation, energy-saving and environmentally friendly	Voltage: 7 kV	Oxynitrided layer	[70]
	The physical mechanism of discharge is complex	Frequency: 10 kHz
		Working temperature: 25 °C
		Conditions: air/180 s

Technology	Characteristics	Process parameters	Composition, Structure	Reference
Gas nitriding	Simple process, high temperatures, long processing times, low temperature nitriding can be achieved when combined with integral mechanical alloying	Working temperature: 650 °C -800 °C	Mg₃N₂/ cubic anti-bixbyite	[39]
Gas nitriding		Conditions: N₂ (1.0 L/min)	Mg₃N₂/ cubic anti-bixbyite	[39]
Ion beam ion implantation (IBII)	Controllable composition, limitations on size and shape of workpiece, high cost	Implantation dose: 4 × 10¹⁷ ions/cm²	Mg₃N₂/ cubic anti-bixbyite	[32]
		Energy of implantation: 65 keV
		Working temperature: 25 °C
Plasma immersion ion implantation (PIII)	It has the advantages of IBII and overcomes the disadvantage of its “line-of-sight” limitation to realize all direction ion implantation, but the injected layer is thin and the preparation efficiency is low	Negative high voltage: 35 kV	Mg₃N₂/ cubic anti-bixbyite	[56]
		Frequency: 200 Hz
		Pulse width: 35 μs
		Working pressure: 2 × 10⁻¹ Pa N₂
		Working temperature: 25 °C
Plasma nitriding	Short nitriding cycle, small substrate deformation, adjustable chemical composition and thickness, corrosion protection can be achieved in combination with coating technology	Materials: Ti (5 µm)/Al (10 µm)/AZ91D	TiN/ NaCl; Al₁₂Mg₁₇	[37]
		Working temperature: 400 °C − 460 °C
		Conditions: 300 Pa N₂/12 h
DBD nitriding	Simple process, easy operation, energy-saving and environmentally friendly	Voltage: 7 kV	Oxynitrided layer	[70]
	The physical mechanism of discharge is complex	Frequency: 10 kHz
		Working temperature: 25 °C
		Conditions: air/180 s

Sample	Test conditions	E_corr (V/SCE)	I_corr (10⁻⁶ A/cm²)	Reference
AZ91	0.9 wt% NaCl	− 1.49	4.26	[51]
Zr/N ion-implanted AZ91	0.9 wt% NaCl	− 1.30	1.16	[51]
AZ31B	3 wt% NaCl	− 1.55	-	[36]
N ion-implanted AZ31B (Mg-42)	3 wt% NaCl	− 1.41	-	[36]
Mg	0.5 wt% NaCl	− 1.558	-	[32]
N ion-implanted Mg	0.5 wt% NaCl	− 1.446	-
AM50	0.5 wt% NaCl	− 1.516	-
N ion-implanted AM50	0.5 wt% NaCl	− 1.461	-
AZ31	0.5 wt% NaCl	− 1.486	-
N ion-implanted AZ31	0.5 wt% NaCl	− 1.402	-
Bare AZ31	3.5 wt% NaCl	− 1.486	24.2	[53]
SiN_x/Ar/AZ31	3.5 wt% NaCl	− 1.285	10.9
DLC:H/SiN_x/Ar/AZ31	3.5 wt% NaCl	− 1.479	4.7
SiN_x/Ar&N/AZ31	3.5 wt% NaCl	− 1.478	6.9
DLC:H/SiN_x/ Ar&N/AZ31	3.5 wt% NaCl	− 1.58	6.6
AM60	1 M NaCl	− 1.39	88.9	[34]
AM60/Single-layer MoS₂-phenolic resin	1 M NaCl	− 1.15	0.605
AM60/N/AlN/MoS₂-phenolic resin	1 M NaCl	− 1.23	0.00231
AM60/N/AlN/CrAlN/MoS₂-phenolic resin	1 M NaCl	− 1.01	0.512
AZ91	after immersion in SBF for 48 h	− 1.477	4.81	[56]
Nitrided AZ91	after immersion in SBF for 48 h	− 1.266	0.21	[56]
Coated AZ91	after immersion in SBF for 48 h	− 1.194	0.09
	after immersion in SBF for 120 h	− 1.131	0.05
AZ91	0.5 mol/L NaCl	− 1.53	-	[37]
Nitriding variant (Ti5_N)	0.5 mol/L NaCl	− 1.45	-
AZ91D	3.5 wt% NaCl	− 1.51	-	[67]
Al/Ti multilayer coated AZ91D	3.5 wt% NaCl	− 1.41	-
Al/Ti multilayer coated + 375 °C nitrided AZ91D	3.5 wt% NaCl	− 1.20	-
Al/Ti multilayer coated + 400 °C nitrided AZ91D	3.5 wt% NaCl	− 1.35	-
AZ31	3.5 wt% NaCl	− 1.53	2.10	[86]
As-deposited Al	3.5 wt% NaCl	− 1.33	0.28
Heat-treated Al	3.5 wt% NaCl	− 1.41	0.61
Bare recycled Mg	3.5 wt% NaCl	− 1.53	672	[87]
Pasma electrolytic oxidation-coated recycled Mg	3.5 wt% NaCl	− 1.45	0.502

Sample	Test conditions	E_corr (V/SCE)	I_corr (10⁻⁶ A/cm²)	Reference
AZ91	0.9 wt% NaCl	− 1.49	4.26	[51]
Zr/N ion-implanted AZ91	0.9 wt% NaCl	− 1.30	1.16	[51]
AZ31B	3 wt% NaCl	− 1.55	-	[36]
N ion-implanted AZ31B (Mg-42)	3 wt% NaCl	− 1.41	-	[36]
Mg	0.5 wt% NaCl	− 1.558	-	[32]
N ion-implanted Mg	0.5 wt% NaCl	− 1.446	-
AM50	0.5 wt% NaCl	− 1.516	-
N ion-implanted AM50	0.5 wt% NaCl	− 1.461	-
AZ31	0.5 wt% NaCl	− 1.486	-
N ion-implanted AZ31	0.5 wt% NaCl	− 1.402	-
Bare AZ31	3.5 wt% NaCl	− 1.486	24.2	[53]
SiN_x/Ar/AZ31	3.5 wt% NaCl	− 1.285	10.9
DLC:H/SiN_x/Ar/AZ31	3.5 wt% NaCl	− 1.479	4.7
SiN_x/Ar&N/AZ31	3.5 wt% NaCl	− 1.478	6.9
DLC:H/SiN_x/ Ar&N/AZ31	3.5 wt% NaCl	− 1.58	6.6
AM60	1 M NaCl	− 1.39	88.9	[34]
AM60/Single-layer MoS₂-phenolic resin	1 M NaCl	− 1.15	0.605
AM60/N/AlN/MoS₂-phenolic resin	1 M NaCl	− 1.23	0.00231
AM60/N/AlN/CrAlN/MoS₂-phenolic resin	1 M NaCl	− 1.01	0.512
AZ91	after immersion in SBF for 48 h	− 1.477	4.81	[56]
Nitrided AZ91	after immersion in SBF for 48 h	− 1.266	0.21	[56]
Coated AZ91	after immersion in SBF for 48 h	− 1.194	0.09
	after immersion in SBF for 120 h	− 1.131	0.05
AZ91	0.5 mol/L NaCl	− 1.53	-	[37]
Nitriding variant (Ti5_N)	0.5 mol/L NaCl	− 1.45	-
AZ91D	3.5 wt% NaCl	− 1.51	-	[67]
Al/Ti multilayer coated AZ91D	3.5 wt% NaCl	− 1.41	-
Al/Ti multilayer coated + 375 °C nitrided AZ91D	3.5 wt% NaCl	− 1.20	-
Al/Ti multilayer coated + 400 °C nitrided AZ91D	3.5 wt% NaCl	− 1.35	-
AZ31	3.5 wt% NaCl	− 1.53	2.10	[86]
As-deposited Al	3.5 wt% NaCl	− 1.33	0.28
Heat-treated Al	3.5 wt% NaCl	− 1.41	0.61
Bare recycled Mg	3.5 wt% NaCl	− 1.53	672	[87]
Pasma electrolytic oxidation-coated recycled Mg	3.5 wt% NaCl	− 1.45	0.502