CAREER: Advancing the Printability of Aluminum Alloys via In-situ Alloying and Hybrid Processing Strategies

NSF Award Search · 01002627DB NSF RESEARCH & RELATED ACTIVIT · $550,000 · view on nsf.gov ↗

Abstract

This Faculty Early Career Development Program (CAREER) award supports the NSF mission of securing national defense, with the aim of advancing the printability of aluminum (Al) alloys which are utilized heavily in structural applications in the naval and aerospace sectors. Printed aluminum components have the potential to enable increased fuel efficiency and enhance resistance to stress corrosion cracking compared to steel counterparts. Laser powder blown Directed Energy Deposition (L-DED) is a popular metal additive manufacturing (AM) technique due to its capabilities to repair metal components and fabricate large scale parts with high deposition rate. However, only a small percentage of alloys can be reliably manufactured using AM process which hinders widespread industrial deployment of the process. One of the major reasons behind this challenge is solidification cracking. Many high-performance alloys, including aluminum, nickel-based alloys, and refractory alloys, have high cooling rates, thermal gradients and tensile residual stress which contribute to solidification cracking during AM-based processing. The goal of this CAREER project is to first understand the crack initiation and propagation mechanisms in L-DED processed Al and establish new strategies, guided by deposition science and based on laser-material interactions, to resolve these challenges. Major difficulties related to L-DED processing of Al are solidification cracking induced by tensile residual stress, large solidification range and poor aluminum melt fluidity. Research activities will be pursued systematically to reveal the interrelationship between macro-cracks and porosities along with crack nucleation and propagation mechanisms. Strategic ‘in-situ’ alloying efforts will be pursued to advance scientific understanding about the individual effect of select alloying elements that can tune melt fluidity, solidification range and powder flowability synergistically reducing the defects in depo

Key facts

NSF award ID
2542988
Awardee
Iowa State University (IA)
SAM.gov UEI
DQDBM7FGJPC5
PI
Sougata Roy
Primary program
01002627DB NSF RESEARCH & RELATED ACTIVIT
All programs
CAREER-Faculty Erly Career Dev, MATERIALS PROCESSING AND MANFG, Materials Engineering, Advanced Materials Processing, Advanced Manufacturing, EXP PROG TO STIM COMP RES, UNDERGRADUATE EDUCATION, GRADUATE INVOLVEMENT, MANUFACTURING
Estimated total
$550,000
Funds obligated
$550,000
Transaction type
Standard Grant
Period
08/01/2026 → 07/31/2031