COMPOSITION DESIGN AND OPTIMIZATION OF Fe-B-Si-Nb BULK AMORPHOUS ALLOYS

doi:10.11900/0412.1961.2016.00033

Acta Metall Sin

2016, Vol. 52

Issue (11): 1459-1466 DOI: 10.11900/0412.1961.2016.00033

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COMPOSITION DESIGN AND OPTIMIZATION OF Fe-B-Si-Nb BULK AMORPHOUS ALLOYS

Yaoxiang GENG¹(

),Yingmin WANG²,Jianbing QIANG²,Chuang DONG²,Haibin WANG¹,Ojied TEGUS³

1 School of Materials Science and Engineering, Jiangsu University of Science and Technology, Zhenjiang 212003, China
2 Key Lab of Materials Modification by Laser, Ion and Electron Beams, Ministry of Education, Dalian University of Technology, Dalian 116024, China
3 Inner Mongolia Key Laboratory for Physics and Chemistry of Functional Materials, Inner Mongolia Normal University, Hohhot 010022, China

Cite this article:

Yaoxiang GENG,Yingmin WANG,Jianbing QIANG,Chuang DONG,Haibin WANG,Ojied TEGUS. COMPOSITION DESIGN AND OPTIMIZATION OF Fe-B-Si-Nb BULK AMORPHOUS ALLOYS. Acta Metall Sin, 2016, 52(11): 1459-1466.

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Abstract

Fe-based amorphous alloys are well known for their good magnetic properties including ultrahigh saturation magnetization, low coercive force, high magnetic permeability and low core loss. But these alloys were only prepared into ribbon form in early times due to their insufficient glass-forming abilities (GFAs). The present work focuses on the design of Fe-B-Si-Nb bulk metallic glasses with good soft magnetic properties and high glass-forming ability. Glass formation in Fe-B system is first considered with cluster-plus-glue-atom model. A basic composition formula [B-B₂Fe₈]Fe is proposed as the framework for multi-component alloy design. Considering the structural stability of the model glass, Si and Nb are introduced to the [B-B₂Fe₈] cluster to replace the center B and shell Fe atoms, from which a series of Fe-B-Si-Nb alloys with composition formulas [Si-B₂Fe_8-_xNb_x]Fe (x=0.1~1.2) are derived. Copper mold casting experiments revealed that bulk glass alloys with a critical diameter (d_c) exceeding 1.0 mm are readily obtained with the Nb content range of x=0.2~1.2, the largest d_c (about 2.5 mm) appears in the vicinity of x=0.4~0.5. Considering the local packing efficiency of Fe-B-Si-Nb glass model structure, another series alloy compositions, namely, [(Si_1-_yB_y)-B₂Fe_8-_xNb_x]Fe is reached by increasing Nb and decreasing Si simultaneously in [Si-B₂Fe_7.6Nb_0.4]Fe basal glass alloys. The experimental results show that bulk glass alloys with d_c=2.5 mm are available over a wide range of compositions from (x=0.5, y=0.05) to (x=0.9, y=0.25). Excellent magnetic softness with high saturation magnetizations (B_s=1.14~1.46 T) and low coercive forces (H_c=1.6~6.7 A/m) is found in the [Si-B₂Fe_8-_xNb_x]Fe (x=0.2~0.6) series glass alloys. A high fracture strength of 4220 MPa with a plasticity of 0.5% is observed in the [(Si_0.95B_0.05)-B₂Fe_7.5Nb_0.5]Fe bulk glass alloy.

Key words: cluster-plus-glue-atom model, Fe-B-Si-Nb bulk glass alloy, mechanical property, soft magnetic property

Received: 20 January 2016

Fund: Supported by National Natural Science Foundation of China (No.51131002), Fundamental Research Funds for the Central Universities (Nos.DUT16ZD209 and DUT13ZD102), Scientific and Technological Development Foundation of China Academy of Engineering Physics (No.2013A03010115), National Magnetic Confinement Fusion Science Program (No.2013GB107003) and the Fund of the State Key Laboratory of Solidification Processing in NWPU (No.SKLSP201607)

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	Yaoxiang GENG
	Yingmin WANG
	Jianbing QIANG
	Chuang DONG
	Haibin WANG
	Ojied TEGUS

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https://www.ams.org.cn/EN/10.11900/0412.1961.2016.00033 OR https://www.ams.org.cn/EN/Y2016/V52/I11/1459

Fig.1 XRD spectra of [Si-B₂Fe_8-_xNb_x]Fe (a) and [(Si_1-_yB_y)-B₂Fe_8-_xNb_x]Fe (b) rod samples with different critical diameters (d_c)

Table 1 Cluster formulas, chemical compositions (atomic fraction), glass forming ability and thermal data of [Si-B₂Fe_8-_xNb_x]Fe and [(Si_1-_yB_y₎-B₂Fe_8-_xNb_x]Fe amorphous alloys

Fig.2 Bright field TEM images and the corresponding SAED patterns (insets) of [Si-B₂Fe_7.6Nb_0.4]Fe (a) and [(Si_0.8B_0.2)-B₂Fe_7.2Nb_0.8]Fe (b) rod samples with d_c= 2.5 mm

Fig.3 Variations of d_c against Si and Nb contents in Fe-B-Si-Nb alloys (The rod glass alloys with d_c>2.5 mm would be formed in dashed area)

Fig.4 DSC (a, b) and DTA (c, d) curves of [Si-B₂Fe_8-_xNb_x]Fe (a, c) and [(Si_1-_yB_y)-B₂Fe_8-_xNb_x]Fe (b, d) glass ribbons

Fig.5 Variations of T_g, T_x (a) and T_rg (b) against Nb content x in [Si-B₂Fe_8-_xNb_x]Fe and [(Si_1-_yB_y)-B₂Fe_8-_xNb_x]Fe samples

Fig.6 Room temperature compressive engineering stress-strain curve of the [(Si_0.95B_0.05)-B₂Fe_7.5Nb_0.5]Fe bulk glass alloy

Fig.7 Magnetization versus the applied magnetic field (a) and the B-H loops (b) of the [Si-B₂Fe_8-_xNb_x] Fe (x=0.2~0.6) glass ribbons

Fig.8 Variations of saturation magnetizations (B_s) and Curie temperature (T_c) against Nb content x in [Si-B₂Fe_8-_xNb_x]Fe (x=0.2~0.6) glass alloys

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