Litcius/Paper detail

Microstructure and wettability of the micro-laminated Ti6Al4V/304 stainless steel composite fabricated by diffusion bonding

Dejun Gao, Chun Li, Chenghao Zhang, Bo Yang, Tong Lin, Lei Chen, Xiaoqing Si, Junlei Qi, Jian Cao

2023Journal of Materials Research and Technology15 citationsDOIOpen Access PDF

Abstract

Laminated composites have been extensively researched due to their excellent mechanical properties, but their application in superwetting fields has been rarely reported. In this work, the surfaces with extreme wettability were prepared based on laminated composites. The Ti6Al4V/304 stainless steel (304 SS) micro-laminated composites were fabricated by diffusion bonding the Ti6Al4V foils and 304 SS foils with the thickness of 10–50 μm in vacuum. The typical interfacial microstructure and the effect of diffusion temperature on the microstructure were investigated. The bonded interface of joints is mainly composed of β-Ti, Ti2Ni, FeTi, Fe2Ti, Fe–Cr from the Ti6Al4V side to the 304 SS. The effect of diffusion temperature on the microstructure was researched. Based on the prepared Ti6Al4V/304 SS micro-laminated composites, an array structure with micro grooves was fabricated through the simple chemical etching. The 304 SS foils were etched to form grooves, while Ti6Al4V foils still remained as bulges. Due to surface modification and rough morphology, the etched surfaces exhibited the excellent hydrophobicity. Increasing the width and depth of grooves and decreasing the width of bulges led to the higher water contact angles and improved hydrophobicity. The highest water contact angles of 148.3° has been achieved under the conditions of grooves with a width of 50 μm, a depth of 60 μm, and the bulges with a width of 10 μm. The surfaces exhibited nearly superhydrophobicity and performed self-cleaning property. The processing method of this work could expand the application of laminated composite in extreme wettability fields.

Topics & Concepts

Materials scienceMicrostructureWettingComposite materialContact angleComposite numberTitanium alloyDiffusionEtching (microfabrication)Diffusion bondingLayer (electronics)AlloyThermodynamicsPhysicsSurface Modification and SuperhydrophobicityAdhesion, Friction, and Surface InteractionsFluid Dynamics and Heat Transfer