TY - JOUR
T1 - Improving compactness of 3d metallic microstructures printed by laser-induced forward transfer
AU - Gorodesky, Niv
AU - Sedghani-Cohen, Sharona
AU - Fogel, Ofer
AU - Silber, Amir
AU - Tkachev, Maria
AU - Kotler, Zvi
AU - Zalevsky, Zeev
N1 - Publisher Copyright:
© 2021 by the authors. Licensee MDPI, Basel, Switzerland.
PY - 2021/3
Y1 - 2021/3
N2 - Laser-induced forward transfer (LIFT) has been shown to be a useful technique for the manufacturing of micron-scale metal structures. LIFT is a high-resolution, non-contact digital printing method that can support the fabrication of complex shapes and multi-material structures in a single step under ambient conditions. However, LIFT printed metal structures often suffer from inferior mechanical, electrical, and thermal properties when compared to their bulk metal counterparts, and often are prone to enhanced chemical corrosion. This is due mostly to their non-compact structures, which have voids and inter-droplet delamination. In this paper, a theoretical framework together with experimental results of achievable compactness limits is presented for a variety of metals. It is demonstrated that compactness limits depend on material properties and jetting conditions. It is also shown how a specific choice of materials can yield compact structures, for example, when special alloys are chosen along with a suitable donor construct. The example of printed amorphous ZrPd is detailed. This study contributes to a better understanding of the limits of implementing LIFT for the fabrication of metal structures, and how to possibly overcome some of these limitations.
AB - Laser-induced forward transfer (LIFT) has been shown to be a useful technique for the manufacturing of micron-scale metal structures. LIFT is a high-resolution, non-contact digital printing method that can support the fabrication of complex shapes and multi-material structures in a single step under ambient conditions. However, LIFT printed metal structures often suffer from inferior mechanical, electrical, and thermal properties when compared to their bulk metal counterparts, and often are prone to enhanced chemical corrosion. This is due mostly to their non-compact structures, which have voids and inter-droplet delamination. In this paper, a theoretical framework together with experimental results of achievable compactness limits is presented for a variety of metals. It is demonstrated that compactness limits depend on material properties and jetting conditions. It is also shown how a specific choice of materials can yield compact structures, for example, when special alloys are chosen along with a suitable donor construct. The example of printed amorphous ZrPd is detailed. This study contributes to a better understanding of the limits of implementing LIFT for the fabrication of metal structures, and how to possibly overcome some of these limitations.
KW - 3D metal printing
KW - Additive manufacturing
KW - Improved properties
KW - Laser-induced forward transfer
KW - Metal glass
KW - Printing of micro-electronics devices
UR - http://www.scopus.com/inward/record.url?scp=85103250226&partnerID=8YFLogxK
U2 - 10.3390/cryst11030291
DO - 10.3390/cryst11030291
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AN - SCOPUS:85103250226
SN - 2073-4352
VL - 11
JO - Crystals
JF - Crystals
IS - 3
M1 - 291
ER -