Mahsa Kaltwasser scite author profile

Mahsa Kaltwasser

4Publications

22Citation Statements Received

66Citation Statements Given

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Affiliations

Technische Universität Ilmenau

Publications

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Core–Shell Transformation-Imprinted Solder Bumps Enabling Low-Temperature Fluidic Self-Assembly and Self-Alignment of Chips and High Melting Point Interconnects

Kaltwasser

Schmidt

Biswas

et al. 2018

ACS Appl. Mater. Interfaces

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We demonstrate the realization of core−shell transformation-imprinted solder bumps to enable low-temperature chip assembly, while providing a route to high-temperature interconnects through transformation. The reported core−shell solder bump uses a lower melting point BiIn-based shell and a higher melting point Sn core in the initial stage. The bumps enable fluidic self-assembly and selfalignment at relatively low temperatures (60−80 °C). The bumps use the high surface free energy of the liquid shell during the self-assembly to capture freely suspended Si dies inside a heated (80 °C) water bath, leading to well-ordered defect-free chip arrays; the molten liquid shell wets the metal contact (binding site) on the chips and yields self-aligned and electrically connected devices. The solid core provides the anchor point to the substrate. After the completion of the assembly, a short reflow raises the melting point, yielding a solid electrical connection. The low melting point liquid diffuses into the high melting point core. The tuning of the material ratios leads to tailored transformation-imprinted solders with high melting points (160−206 °C) in the final structure. KEYWORDS: core−shell transformation-imprinted solder bumps, low-temperature fluidic self-assembly, high melting point interconnects, Pb-free solder bumps, self-alignment

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Fluidic Self-Assembly on Electroplated Multilayer Solder Bumps with Tailored Transformation Imprinted Melting Points

Kaltwasser

Schmidt

Lösing

et al. 2019

Sci Rep

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This communication presents fluidic self-assembly of Si-chip on a sequentially electroplated multilayer solder bump with tailored transformation imprinted melting points. The multilayer solder bump is a lead free ternary solder system, which provides a route to transform the melting point of interconnects for applications in solder directed fluidic self-assembly. The outermost metal layers form a low melting point Bi 33.7 In 66.3 solder shell (72 °C). This solder shell enables fluidic self-assembly and self-alignment of freely in water suspended Si-dies at relatively low temperature (75 °C) leading to well-ordered chip arrays. The reduction of the free surface energy of the shell-water interface provides the driving force for the self-assembly. The lowermost metal layer is a high melting point solder and acts as a core. After the self-assembly is complete, a short reflow causes the transformation of the core and the shell yielding a stable high melting point solder with adjustable melting points. The chosen ternary solder system enables the realization of interconnects with melting points in the range of 112 °C to 206 °C.

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Localized collection of airborne biological hazards for environmental monitoring

Reiprich

Gebinoga

Traue

et al. 2018

Sensors and Actuators B: Chemical

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Glass-LTCC-Interposer, a New Plattform for HF-Applications

Kaltwasser

Schulz

Müller

2023

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