Pilling–Bedworth ratio

The Pilling–Bedworth ratio (P–B ratio), in corrosion of metals, is the ratio of the volume of the elementary cell of a metal oxide to the volume of the elementary cell of the corresponding metal (from which the oxide is created).

On the basis of the P–B ratio, it can be judged if the metal is likely to passivate in dry air by creation of a protective oxide layer.

Definition[]

The P–B ratio is defined as:^[1]

\mathrm {R_{PB}={\frac {V_{oxide}}{n\cdot V_{metal}}}={\frac {M_{oxide}\cdot \rho _{metal}}{n\cdot M_{metal}\cdot \rho _{oxide}}}}

where:

$R_{PB}$ – Pilling–Bedworth ratio
$M$ – atomic or molecular mass
$n$ – number of atoms of metal per molecule of the oxide
$\rho$ – density
$V$ – molar volume

History[]

N.B. Pilling and R.E. Bedworth^[2] suggested in 1923 that metals can be classed into two categories: those that form protective oxides, and those that cannot. They ascribed the protectiveness of the oxide to the volume the oxide takes in comparison to the volume of the metal used to produce this oxide in a corrosion process in dry air. The oxide layer would be unprotective if the ratio is less than unity because the film that forms on the metal surface is porous and/or cracked. Conversely, the metals with the ratio higher than 1 tend to be protective because they form an effective barrier that prevents the gas from further oxidizing the metal.^[3]

Application[]

Scheme of the oxide structure and the Pilling-Bedworth ratio.

On the basis of measurements, the following connection can be shown:

R_PB < 1: the oxide coating layer is too thin, likely broken and provides no protective effect (for example magnesium)
R_PB > 2: the oxide coating chips off and provides no protective effect (example iron)
1 < R_PB < 2: the oxide coating is passivating and provides a protecting effect against further surface oxidation (examples aluminium, titanium, chromium-containing steels).

However, the exceptions to the above P-B ratio rules are numerous. Many of the exceptions can be attributed to the mechanism of the oxide growth: the underlying assumption in the P-B ratio is that oxygen needs to diffuse through the oxide layer to the metal surface; in reality, it is often the metal ion that diffuses to the air-oxide interface.^{[citation needed]}

The P-B ratio is important when modelling the oxidation of nuclear fuel cladding tubes, which are typically made of Zirconium alloys, as it defines how much of the cladding that is consumed and weakened due to oxidation. The P-B ratio of Zirconium alloys can vary between 1.48-1.56,^[4] meaning that the oxide is more voluminous than the consumed metal.

Values[]

Metal	Metal oxide	Formula	R_PB
Potassium	Potassium oxide	K₂O	0.474^[5]
Sodium	Sodium oxide	Na₂O	0.541^[5]
Lithium	Lithium oxide	Li₂O	0.567^[5]
Strontium	Strontium oxide	Sr O	0.611^[5]
Calcium	Calcium oxide	Ca O	0.64 ^[3]
Barium	Barium oxide	Ba O	0.67^[5]
Magnesium	Magnesium oxide	Mg O	0.81
Aluminium	Aluminium oxide	Al₂O₃	1.28
Lead	Lead(II) oxide	Pb O	1.28 ^[3]
Platinum		Pt O	1.56 ^[3]
Zirconium	Zirconium(IV) oxide	Zr O₂	1.56
Zinc	Zinc oxide	Zn O	1.58
Hafnium	Hafnium(IV) oxide	Hf O₂	1.62 ^[3]
Nickel	Nickel(II) oxide	Ni O	1.65
Iron	Iron(II) oxide	Fe O	1.7
Titanium	Titanium(IV) oxide	Ti O₂	1.73
Iron	Iron(II,III) oxide	Fe₃O₄	1.90
Chromium	Chromium(III) oxide	Cr₂O₃	2.07
Iron	Iron(III) oxide	Fe₂O₃	2.14
Silicon	Silicon dioxide	Si O₂	2.15
Tantalum	Tantalum(V) oxide	Ta₂O₅	2.47 ^[3]
Niobium	Niobium pentoxide	Nb₂O₅	2.69^[5]
Vanadium	Vanadium(V) oxide	V₂O₅	3.25 ^[3]
Tungsten	Tungsten(VI) oxide	W O₃	3.3 ^[6]

References[]

^ Xu, C.; Gao, W. (2000). "Pilling-Bedworth ratio for oxidation of alloys". Mat. Res. Innovat. 3 (4): 231–235. doi:10.1007/s100190050008.
^ N.B. Pilling, R. E. Bedworth, "The Oxidation of Metals at High Temperatures". J. Inst. Met 29 (1923), p. 529-591.
^ Jump up to: ^a ^b ^c ^d ^e ^f ^g "ASM Handbook Vol.13 Corrosion", ASM International, 1987
^ Annand, Kirsty; Nord, Magnus; MacLaren, Ian; Gass, Mhairi (November 2017). "The corrosion of Zr(Fe, Cr)2 and Zr2Fe secondary phase particles in Zircaloy-4 under 350 °C pressurised water conditions". Corrosion Science. 128: 213–223. doi:10.1016/j.corsci.2017.09.014. ISSN 0010-938X.
^ Jump up to: ^a ^b ^c ^d ^e ^f "Pilling–Bedworth ratios (PBRs) for metals and their oxides".
^ Bagnall, C.; Capo, J.; Moorhead, W. J. (December 2018). "Oxidation Behavior of Tungsten Carbide-6% Cobalt Cemented Carbide". Metallography, Microstructure, and Analysis. 7 (6): 661–679. doi:10.1007/s13632-018-0493-7.

[Xu,_Gao,_2000-1] Xu, C.; Gao, W. (2000). "Pilling-Bedworth ratio for oxidation of alloys". Mat. Res. Innovat. 3 (4): 231–235. doi:10.1007/s100190050008.

[2] N.B. Pilling, R. E. Bedworth, "The Oxidation of Metals at High Temperatures". J. Inst. Met 29 (1923), p. 529-591.

[ASM-3] Jump up to: ^a ^b ^c ^d ^e ^f ^g "ASM Handbook Vol.13 Corrosion", ASM International, 1987

[Annand-4] Annand, Kirsty; Nord, Magnus; MacLaren, Ian; Gass, Mhairi (November 2017). "The corrosion of Zr(Fe, Cr)2 and Zr2Fe secondary phase particles in Zircaloy-4 under 350 °C pressurised water conditions". Corrosion Science. 128: 213–223. doi:10.1016/j.corsci.2017.09.014. ISSN 0010-938X.

[Sheppard-5] Jump up to: ^a ^b ^c ^d ^e ^f "Pilling–Bedworth ratios (PBRs) for metals and their oxides".

[Bagnall-6] Bagnall, C.; Capo, J.; Moorhead, W. J. (December 2018). "Oxidation Behavior of Tungsten Carbide-6% Cobalt Cemented Carbide". Metallography, Microstructure, and Analysis. 7 (6): 661–679. doi:10.1007/s13632-018-0493-7.

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