Effects of Tungsten and Boron Contents on Crystallization Temperature and Microhardness of Tungsten Based Metallic Glasses

doi:10.1007/s40195-015-0254-4

Abstract

Abstract:

Effects of tungsten and boron contents on the thermal properties and microhardness of W-Fe-B metallic glass system were studied. Thin foils, with thicknesses of 20 and 100 μm, of the alloys were produced by piston and anvil method in an arc furnace. The structures of the foils were investigated by X-ray diffraction. Thermal stabilities of the alloys were examined by using differential scanning calorimetry. 20-μm- thick foils of all the alloys were determined to be fully amorphous, but crystalline phases were detected in the 100-μm-thick foils. It was found that crystallization temperatures of the alloys are between 1060 and 1177 K. Tungsten and boron content increases improve the crystallization temperature and microhardness of the alloys significantly, but deteriorate the glass forming ability of the alloys. It was also observed that for constant Fe content, increasing tungsten content to the level higher than that of boron content does not result in any further improvement in crystallization temperature, but improves glass forming ability significantly. The alloy containing highest total amount of tungsten and boron, W₃₅Fe₃₅B₃₀, has the highest crystallization temperature, 1177 K, and microhardness, 1634 HV.

Key words: Metallic, glass, Refractory, metal, Crystallization, temperature, Hardness

Pelin Öztürk, Aytekin Hitit. Effects of Tungsten and Boron Contents on Crystallization Temperature and Microhardness of Tungsten Based Metallic Glasses[J]. Acta Metallurgica Sinica (English Letters), 2015, 28(6): 733-738.

Figures/Tables 9

References 15

[1]	A. Inoue, A. Takeuchi,Acta Mater. 59, 2243(2011)
[2]	T. Yoshitake, Y. Kubo, H. Igarashi,Mater. Sci. Eng. 97, 269(1988)
[3]	L. Rohr, P. Reimann, T. Richmond, H.J. Güntherodt, Mater. Sci. Eng. A 133, 715 (1991)
[4]	C.C. Koch, D.M. Kroeger, J.O. Scarbrough, B.C. Giessen, Phys. Rev. B 22, 5213 (1980)
[5]	T. Masumoto, A. Inoue, S. Sakai, H. Kimura, A. Hoshi, Trans. JIM 21, 115 (1980)
[6]	M.K. Mahan, B.L. Jha, J. Mater. Sci. Lett. 15, 1594(1980)
[7]	M. Mehra, R. Schultz, W.L. Johnson, J. Non-Cryst. Solids 61-62, 859(1984)
[8]	R. Yoshimoto, Y. Nogi, R. Tamura, S. Takeuchi,Mater. Sci. Eng., A 449-451, 260(2007)
[9]	A. Inoue, S. Sakai, H. Kimura, K. Masumoto, A. Hoshi,Scr. Mater. 14, 235(1980)
[10]	M. Ohtsuki, K. Nagata, R. Tamura, S. Takeuchi, Mater. Trans., JIM 46, 48 (2005)
[11]	Z.Y. Suo, Y.L. Song, B. Yu, K.Q. Qiu, Mater. Sci. Eng. A 528, 2912 (2011)
[12]	S.V. Madge, A. Caron, R. Gralla, G. Wilde, S.K. Mishra, Intermetallics 47, 6 (2014)
[13]	A.P. Thakoor, J.L. Lamb, S.K. Khanna, M. Mehra, W.L. Johnson, J. Appl. Phys. 58, 3409(1985)
[14]	V.V. Brazhkin, A.G. Lyapin, R.J. Hemley, Philos. Mag. A 82, 231 (2002)
[15]	C.J. Qi, Y.H. Jiang, Y.Z. Liu, R. Zhou,Ceram. Int. 40, 5843(2014)

Series	Alloy	T _g (K)	T _x1 (K)	T _x2 (K)	T _m (K)	T _L (K)	Hardness (HV)
1	W₂₅Fe₄₅B₃₀	1017	1060	1148	1416	-	1340
	W_27.5Fe₄₀B_32.5	1063	1110	1190	1409	-	1545
2	W_27.5Fe₄₅B_27.5	1043	1090	1201	1603	-	1356
	W₃₀ Fe₄₀B₃₀	1106	1140	1251	1602	-	1608
3	W₃₀Fe₄₅B₂₅	1036	1086	1204	1607	-	1485
	W_32.5Fe₄₀B_27.5	1095	1143	1268	1602	-	1544
	W₃₅Fe₃₅B₃₀	1130	1177	1331	1679	-	1634

Series	Alloy	T _g (K)	T _x1 (K)	T _x2 (K)	T _m (K)	T _L (K)	Hardness (HV)
1	W₂₅Fe₄₅B₃₀	1017	1060	1148	1416	-	1340
	W_27.5Fe₄₀B_32.5	1063	1110	1190	1409	-	1545
2	W_27.5Fe₄₅B_27.5	1043	1090	1201	1603	-	1356
	W₃₀ Fe₄₀B₃₀	1106	1140	1251	1602	-	1608
3	W₃₀Fe₄₅B₂₅	1036	1086	1204	1607	-	1485
	W_32.5Fe₄₀B_27.5	1095	1143	1268	1602	-	1544
	W₃₅Fe₃₅B₃₀	1130	1177	1331	1679	-	1634

Alloy	T _x1 (K)	T _x2 (K)	Ref.
(Ta,W)₈₀Si₁₀B₁₀	1310-1456	-	[2]
(Hf,Ta)₈₀Si₁₀B₁₀	940-1220	-	[2]
(Ta,Nb,V)₈₀Si₁₀B₁₀	930-1210	-	[2]
Ta₅₅Ir₄₅	1340	-	[3]
Ta₅₅Ni₄₅	990	-	[3]
(Nb,Mo)₈₀Si₁₀B₁₀	1020-1120	-	[2]
(Nb,Ta)₅₅(Rh,Ir)₄₅	951-1338	--	[4]
Nb₇₀W₁₀Si₂₀	1027	-	[5]
Nb₇₀Mo₁₀Si₂₀	1008	-	[5]
(Mo,Cr,Fe)₈₀(P,B,C,Si)₂₀	1104-1186	-	[6]
Mo₄₈TM₃₂P₁₂B₈	1078-1151	-	[6]
(Mo_0.6Ru_0.4)_78-86B_22-14	1020-1090	-	[7]
Re_49.7B_18.4Zr_7.5Si_17.4Nb_7.0	1331	1347	[8]
Re_46.4B_33.4Hf₄Si_16.2	1128	1139	[8]
W₇₀Si₂₀B₁₀	1033	-	[9]
W₄₅Re₂₃Ru₁₅B₁₇	1273	-	[10]
W₅₆Ir₂₃B₂₁	1271	1305	[10]
W₄₆Ru₃₇B₁₇	1174	1208	[10]
W₄₆Ru₃₇B₁₂Si₅	1172	1202	[10]
W₄₆Ru₃₇B₁₅Si₂	1167	1201	[10]
W₃₈Ir₁₇Ru₃₁B₁₄	1119	1232	[10]
W₅₄Rh₂₆B₂₀	1064	1152	[10]
W₃₇Ru₃₁Rh₁₈B₁₄	1049	-	[10]
W₃₀Fe₃₈B₂₅C₇	1067	1128	[11]
W₃₃Ni₃₂B ₃₅ ^a	1146	-	[12]

Alloy	T _x1 (K)	T _x2 (K)	Ref.
(Ta,W)₈₀Si₁₀B₁₀	1310-1456	-	[2]
(Hf,Ta)₈₀Si₁₀B₁₀	940-1220	-	[2]
(Ta,Nb,V)₈₀Si₁₀B₁₀	930-1210	-	[2]
Ta₅₅Ir₄₅	1340	-	[3]
Ta₅₅Ni₄₅	990	-	[3]
(Nb,Mo)₈₀Si₁₀B₁₀	1020-1120	-	[2]
(Nb,Ta)₅₅(Rh,Ir)₄₅	951-1338	--	[4]
Nb₇₀W₁₀Si₂₀	1027	-	[5]
Nb₇₀Mo₁₀Si₂₀	1008	-	[5]
(Mo,Cr,Fe)₈₀(P,B,C,Si)₂₀	1104-1186	-	[6]
Mo₄₈TM₃₂P₁₂B₈	1078-1151	-	[6]
(Mo_0.6Ru_0.4)_78-86B_22-14	1020-1090	-	[7]
Re_49.7B_18.4Zr_7.5Si_17.4Nb_7.0	1331	1347	[8]
Re_46.4B_33.4Hf₄Si_16.2	1128	1139	[8]
W₇₀Si₂₀B₁₀	1033	-	[9]
W₄₅Re₂₃Ru₁₅B₁₇	1273	-	[10]
W₅₆Ir₂₃B₂₁	1271	1305	[10]
W₄₆Ru₃₇B₁₇	1174	1208	[10]
W₄₆Ru₃₇B₁₂Si₅	1172	1202	[10]
W₄₆Ru₃₇B₁₅Si₂	1167	1201	[10]
W₃₈Ir₁₇Ru₃₁B₁₄	1119	1232	[10]
W₅₄Rh₂₆B₂₀	1064	1152	[10]
W₃₇Ru₃₁Rh₁₈B₁₄	1049	-	[10]
W₃₀Fe₃₈B₂₅C₇	1067	1128	[11]
W₃₃Ni₃₂B ₃₅ ^a	1146	-	[12]

Alloy	Hardness (HV)	Ref.
W₃₃Ni₃₂B ₃₅ ^a	2447	[12]
(W_0.6Re_0.4)_0.76B ₂₄ ^a	2400	[13]
Mo-Fe-B	1784-1988	[6]
Mo-Co-B	1682-1733	[6]
Mo-Co-Fe-B	1784-1815	[6]
Re_49.7B_18.4Zr_7.5Si_17.4Nb_7.0	1784	[8]
Re_46.4B_33.4Hf₄Si_16.2	1377	[8]
Mo₇₀Si₂₀B₁₀	1020	[9]
W₇₀Si₂₀B₁₀	1326	[9]
W₄₅Re₂₃Ru₁₅B₁₇	1764	[10]
W₄₆Ru₃₇B₁₇	1713	[10]
W₄₅Ru₃₆B₁₇Hf₂	1682	[10]
W₄₆Ru₃₇B₁₅Si₂	1468	[10]
W₄₆Ru₃₇B₁₂Si₅	1346	[10]
W₃₀Fe₃₈B₂₅C₇	1219	[11]