What question did this study set out to answer?

The aim is to investigate how grain size affects the mechanical properties and interface evolution of C7701/Ti composite foils.

February 17, 2026Open Access

Grain Size Governs Mechanical Properties of Roll-Bonded C7701/Ti/C7701 (Cu–Ni–Zn Alloy) Composite Foils via a Bonding–Diffusion–Intermetallic Cascade

Key Points

The aim is to investigate how grain size affects the mechanical properties and interface evolution of C7701/Ti composite foils.
Controlled initial grain size via pre-annealing of foils
Assessment of mechanical properties through tensile testing
Analysis of intermetallic compound (IMC) formation at the interface
Moderate grain size of ~7-8 μm yields optimal strength-ductility synergy
Ultimate tensile strength (UTS) recorded at ~217.5 MPa
Excessively fine or coarse grains lead to brittle IMCs or interfacial defects, degrading performance

Abstract

Grain size plays a decisive role in governing the interface evolution and mechanical properties of ultra-thin metal composite foils. This study systematically investigates this relationship in roll-bonded C7701/Ti/C7701 (Cu-Ni-Zn alloy) composite foils. By controlling the initial grain size via pre-annealing, we demonstrate that a moderate grain size (~7–8 μm) optimally regulates a sequential “bonding–diffusion–intermetallic compound (IMC) formation” process at the interface. This results in a continuous, thin IMC layer and the best strength–ductility synergy (e.g., UTS ~217.5 MPa, elongation ~4.15%). In contrast, excessively fine or coarse grains lead to thick, brittle IMCs or interfacial defects, respectively, degrading performance. The mechanism by which grain size influences performance is revealed through a sequential mechanism of “bonding–diffusion–intermetallic compound formation.”

Grain Size Governs Mechanical Properties of Roll-Bonded C7701/Ti/C7701 (Cu–Ni–Zn Alloy) Composite Foils via a Bonding–Diffusion–Intermetallic Cascade

Key Points

Abstract

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