What does this research mean for the field?

In situ sulphur microadditions enhance the machinability of additively manufactured Ti-6Al-4V by reducing cutting forces by approximately 8% and decreasing tool flank wear threefold. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

The aim is to enhance the machinability of Ti-6Al-4V by incorporating trace sulphur during additive manufacturing.

March 14, 2026Open Access

Tailoring Ti-6Al-4V during additive manufacturing with in situ sulphur microadditions to enhance machinability

Key Points

The aim is to enhance the machinability of Ti-6Al-4V by incorporating trace sulphur during additive manufacturing.
Incorporated trace sulphur (<300ppm) via MoS₂ during wire-based directed energy deposition (W-DED)
Assessed machinability through machining trials measuring cutting forces and tool wear
Examined changes in chip morphology and surface roughness
Average cutting forces reduced by approximately 8% compared to the unmodified alloy
Tool flank wear decreased significantly, showing a threefold reduction
Chip morphology changed from distinctly serrated to more continuous
Surface roughness improved from 3.16 µm to 0.71 µm due to stable chip formation

Abstract

Improving the machinability of titanium alloys remains a major barrier in aerospace manufacturing, particularly for additively manufactured Ti-6Al-4V components that exhibit heterogeneous microstructures and high cutting resistance. This study introduces a new alloy modification machinability enhancement strategy by incorporating trace sulphur (<300ppm) via MoS₂ during wire-based directed energy deposition (W-DED). The modified alloy meets the composition requirements of Ti-6Al-4V ELI (ASTM Grade 23) titanium and retains its structural integrity while developing sulphur-rich particles at the grain boundary that act as low-strength shear paths and facilitate plastic flow during cutting. Machinability improvements include an approximate 8% reduction in average cutting forces (F r ) and a th r eefold decrease in tool flank wear compared to the unmodified alloy. Additionally, there was a noticeable change in chip morphology, shifting from distinctly serrated to more continuous. Machining trials show lower cutting forces, delayed crater and flank wear, and a shift in chip morphology from distinctly serrated to more continuous. This behaviour parallels the classical free-cutting effect of sulphur in steels yet is demonstrated here for the first time in an additively manufactured titanium alloy system. This work establishes in-process sulphur micro-addition as an effective pathway for tailoring the machining response of additively manufactured Ti-6Al-4V, offering a practical route for producing difficult-to-cut aerospace components with improved manufacturing efficiency. • Trace sulphur added to Ti-6Al-4V via W-DED without affecting mechanical properties • Sulphur precipitates at prior-β grain boundaries, forming particles that ease machining • Cutting forces drop ~8%, with crater and flank wear greatly reduced • Chip morphology shifts to continuous, aided by higher shear angle and less segmentation • Up-milling roughness improves from 3.16 µm to 0.71 µm due to stable chip formation

Tailoring Ti-6Al-4V during additive manufacturing with in situ sulphur microadditions to enhance machinability

Key Points

Abstract

Cite This Study