The 3D atom probe(3DAP) is a particularly helpful instrument with atomic spatial resolution and high componential sensitivity in the characterization of the early stages of precipitation reactions.

The 3D atom probe(3DAP) is a unique tool capable of obtaining chemical information at the atomic level,offering a powerful method to investigate microstructural and compositional changes occurring at nano-scale.

By applying the techniques of optical microscope, field ion microscope(FIM) and three-dimensional atom probe(3DAP),the carbides precipitated from ferrite matrix on the early stage of niobium and vanadium micro-alloyed steels were characterized.

The three-dimensional atom probe(3DAP) is a quantitative micro-analytical instrument,which provides three-dimension maps of the distribution of different element atoms in metallic specimens by chemically analyzing the atoms one-by-one.

The effect of Cu addition on the GP zones of 6082Al-Mg-Si alloy during the early stage of ageing at 170℃ was investigated by transmission electron microscope(TEM) and three-dimensional atom probe (3DAP).

3D atom probe combined with OM and TEM was applied to characterize the carbides precipitation and microstructure evolution in Nb-V microalloyed steel plates quenched after solution treatment at 1200℃for 0.

Elemental distribution of Nb and Zr atoms in Nd_2Fe_(14)B/α-Fe nanocomposite magnets were investigated by three-dimensional atom probe(3DAP).

From atom segregation,nucleation to precipitation of Niobium carbonitride in ferrite matrix was investigate by field ion microscope (FIM) and three dimensional atom probe (3DAP) and the relevant influencing factors were analyzed;Combined with experimental results,the nucleation and precipitation of Niobium carbonitride was attempted.

The analysis of three dimensional atom probe(3DAP) revealed that Cu atoms were almost insoluble in α-Fe phase,enriching in Fe77.

We have studied the partitioning of B in Fe-14B and the partitioning of Zr, B, Si, Cu and Au in FeZrB nanocrystalline soft magnetic alloys by using atom probe field ion microscopy (APFIM) and high resolution microscopy (HREM) in atomic or nanometric scale and the effect of Si, Cu, Au additions on the magnetic properties.