Scalable Stamp Printing and Fabrication of Hemiwicking Surfaces

Thomas Germain; Chance Brewer; James Scott; Shawn A. Putnam

doi:10.3791/58546

Scalable Stamp Printing and Fabrication of Hemiwicking Surfaces

JoVE Journal
Engineering

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JoVE Journal Engineering

Scalable Stamp Printing and Fabrication of Hemiwicking Surfaces

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06:16 min

December 18, 2018

DOI: 10.3791/58546-v

Thomas Germain¹, Chance Brewer¹, James Scott¹, Shawn A. Putnam¹

¹Department of Mechanical and Aerospace Engineering,University of Central Florida

Overview

This article presents a protocol for fabricating hemiwicking structures using physical stamping and PDMS molding techniques. The method is designed to explore microfluid dynamics, particularly the impact of nanostructures on wicking behavior.

Key Study Components

Area of Science

Microfluidics
Nanostructures
Wicking dynamics

Background

Understanding microfluid dynamics is crucial for various applications.
Nanoscale structures can significantly influence fluid behavior.
Efficient fabrication methods are needed for research and application.
This study aims to provide a cost-effective solution for creating wicking structures.

Purpose of Study

To develop a protocol for creating hemiwicking structures.
To investigate the effects of surface nanostructures on fluid dynamics.
To demonstrate a time-efficient fabrication method for researchers.

Methods Used

Physical stamping technique for structure creation.
PDMS molding for shaping the structures.
Thin-film surface modifications using deposition techniques.
Utilization of a stamping device mounted on an XY stage.

Main Results

The protocol allows for the fabrication of various wicking pillar arrays.
Demonstrated efficiency in terms of cost and time.
Provides insights into the relationship between nanostructures and wicking velocity.
Facilitates further research in microfluid dynamics.

Conclusions

The developed method is effective for creating hemiwicking structures.
It opens new avenues for studying fluid dynamics at the nanoscale.
Future applications may benefit from this fabrication technique.

Frequently Asked Questions

What are hemiwicking structures?

Hemiwicking structures are designed to manipulate fluid movement through surface modifications.

How does the stamping device work?

The stamping device uses an XY stage to accurately position the mold for creating structures.

What materials are used in this protocol?

Common materials for deposition techniques are utilized, including PDMS.

What are the advantages of this method?

It is cost-effective and time-efficient for fabricating various wicking structures.

Who demonstrated the procedure?

Thomas Germain, a graduate student, demonstrated the procedure in the study.

A simple protocol is provided for the fabrication of hemiwicking structures of varying sizes, shapes, and materials. The protocol uses a combination of physical stamping, PDMS molding, and thin-film surface modifications via common materials deposition techniques.

This method can help answer key questions in the microfluid dynamics field, such as the effects of nanostructures on a surface to the thin film profile and wicking velocity. The main advantage of this technique is that it provides a method of fabricating various wicking pillar arrays in a cost and time-efficient manner. Demonstrating the procedure will be Thomas Germain, a graduate student from our laboratory.

To start, prepare the stamping device for the protocol. The essential details of this stamping device are in this schematic. A backing plate to support the mold is mounted on an XY stage.

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