Browsing by Author "Hodgson, PD"
Now showing 1 - 4 of 4
Results Per Page
Sort Options
- ItemComplementarity of SANS,TEM and APT for the study of NbC and MnS precipitates in a direct strip cast steel(Australian Microscopy and Microanalysis Society, 2016-02-04) Dorin, T; Wood, K; Stanford, N; Taylor, A; Hodgson, PDOne of the main alloy design strategies to provide strengthening to low alloy steels is the deliberate addition of strong carbide forming elements such as Nb or Ti to form nano-precipitates with a carbide or carbo-nitride chemistry 1 . The addition of Mn is also common commercial practice to remove free sulphur from the steel. Thus, low alloy steels contain at least two chemically distinct precipitate populations, coarse manganese sulphides and fine carbo-nitrides. When steel alloys are processed by thin slab or direct strip casting (DSC), a significant decrease in the size of the sulphides is observed 2 and this is a direct consequence of the higher cooling rates experienced in these processes 3 . Since DSC is a relatively new processing technology 4 , the precise measurement of these nano-sulphides has not before been required, and very little information on this topic is available in the open literature. Small angle neutron scattering (SANS), atom probe tomography and electron microscopy have been used to investigate the MnS and Nb(C,N) precipitate populations in a low alloy steel processed by direct strip casting. Rapid cooling refined the sulphides, and both the SANS and atom probe tomography data indicate that sulphur is retained in solid solution after rapid cooling. A similar result is observed for the Nb-carbonitrides. The rapid cooling supresses precipitate formation, and only small Nb and N enriched clusters are able to form. These NbN clusters have a low volume fraction compared to the equilibrium condition in which classical Nb(C,N) precipitation is complete. Finally, we present a method to extract precipitate chemistry from the SANS data in order to validate the atom probe measurements on a statistically robust specimen volume.
- ItemThe effect of molybdenum on clustering and precipitation behaviour of strip-cast steels containing niobium(Elsevier B. V., 2019-12) Jiang, L; Marceau, RKW; Guan, B; Dorin, T; Wood, K; Hodgson, PD; Stanford, NTwo high-strength low-alloy (HSLA) steels containing Nb-carbonitrides were produced, one contained Mo and the other was Mo-free. The alloys were produced by simulated direct strip casting, and were fully bainitic in the as-cast condition. Isothermal ageing treatments were carried out to precipitate harden the alloy, and the strength was measured using a shear punch test. The dislocation density was measured with X-ray diffraction (XRD), and was found to be larger in the alloy containing Mo in all ageing conditions. Atom probe tomography (APT) showed the presence of solute clusters in the as-cast condition, and the addition of Mo increased both size and volume fraction of these clusters. The solute clusters provided significant strengthening increments of up to 112 MPa, and cluster strengthening was larger in the Mo-containing alloy. Precipitation of Nb-carbonitrides was observed after longer ageing times, which were refined by the addition of Mo. This was attributed to the higher dislocation density that increased the number of nucleation sites. Precipitate chemistry was similar for both alloys, and contrary to some literature reports, minimal Mo was observed to segregate to the precipitates. A thermodynamic rationale is presented which describes the reasons that Mo segregates to the Nb-carbide in some alloys but not in others, despite the alloy chemistries being relatively similar. © 2019 Acta Materialia Inc.
- ItemGrowth of bainitic ferrite and carbon partitioning during the early stages of bainite transformation in a 2 mass% silicon steel studied by in situ neutron diffraction, TEM and APT(International Union of Crystallography, 2016-01-08) Timokhina, IB; Liss, KD; Raabe, D; Rakha, K; Beladi, H; Xiong, XY; Hodgson, PDIn situ neutron diffraction, transmission electron microscopy (TEM) and atom probe tomography (APT) have been used to study the early stages of bainite transformation in a 2 mass% Si nano-bainitic steel. It was observed that carbon redistribution between the bainitic ferrite and retained austenite at the early stages of the bainite transformation at low isothermal holding occurred in the following sequence: (i) formation of bainitic ferrite nuclei within carbon-depleted regions immediately after the beginning of isothermal treatment; (ii) carbon partitioning immediately after the formation of bainitic ferrite nuclei but substantial carbon diffusion only after 33 min of bainite isothermal holding; (iii) formation of the carbon-enriched remaining austenite in the vicinity of bainitic laths at the beginning of the transformation; (iv) segregation of carbon to the dislocations near the austenite/ferrite interface; and (v) homogeneous redistribution of carbon within the remaining austenite with the progress of the transformation and with the formation of bainitic ferrite colonies. Bainitic ferrite nucleated at internal defects or bainite/austenite interfaces as well as at the prior austenite grain boundary. Bainitic ferrite has been observed in the form of an individual layer, a colony of layers and a layer with sideplates at the early stages of transformation. Copyright © International Union of Crystallography
- ItemSingle step preparation of meso-porous and reduced graphene oxide by gamma-ray irradiation in gaseous phase(Elsevier B.V., 2014-04-01) Dumée, LF; Feng, CF; He, L; Yi, ZF; She, FS; Peng, Z; Gao, WM; Banos, C; Davies, JB; Huynh, C; Hawkins, S; Duke, MC; Gray, S; Hodgson, PD; Kong, LXA facile and highly efficient route to produce simultaneously porous and reduced graphene oxide by gamma ray irradiation in hydrogen is here demonstrated. Narrowly distributed nano-scale pores (average size of ∼3 nm and surface density >44,900 pore μm−2) were generated across 10 μm thick graphene oxide bucky-papers at a total irradiation dose of 500 kGy. The graphene oxide sheet reduction was confirmed to occur homogeneously across the structures by Fourier transform infrared spectroscopy and Raman analysis. This one-step, catalyst-free, high penetration and through-put technique, offers great promises potential for the mass production of reduced graphene oxide from cheap graphene oxide. © 2014 Elsevier B.V.