Three-Dimensional Printing of a Model Atomic Force Microscope to Measure Force–Distance Profiles

Gruber, Daniel M.; Perez, Tynan; Layug, Bege Q.; Ohama, Margaret; Tran, Lydia; Rojas, Luis Angel Flores; Garcia, Antonio; Liu, Gang-yu; Miller, William J.

doi:10.1021/acs.jchemed.9b01099

Cited by 7 publications

(5 citation statements)

References 20 publications

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“…Future work will explore the further use of these instruments in undergraduate research and will develop chemistry experiments and activities involving these versatile instruments. More broadly, we plan to incorporate this work with our previous work , to create a suite of course-based undergraduate research experiences that can be completed remotely.…”

Section: Discussionmentioning

confidence: 99%

Using a Handheld Refractometer in Remote Environments to Measure the Refractive Indices of a Variety of Solutions: Sucrose, Coffee, Methanol/Water, and 2-Propanol/Water

et al. 2021

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A handheld refractometer (HHR) is a versatile instrument in the chemistry lab or in the workplace. It is also inexpensive enough (<$25 U.S.) that all students in a chemistry lab can have one or students completing laboratories remotely can purchase one. We report four applications of two different HHRs: one HHR for which the scale reads directly in refractive index from 1.333 to 1.360 and one HHR for which the scale reads from 0 to 80 °Brix corresponding to refractive indices from 1.333 to 1.491. The four applications involve linear relationships between solution concentration and refractive index for sucrose solutions and coffee solutions as well as nonideal solution behavior of methanol/water solutions and 2-propanol/water solutions. The use of an HHR is ideally suited to a range of inquiry-based experiments and can be incorporated into chemistry lab courses at a variety of levels and in remote learning lab experiences. We describe four broad categories of projects involving the use of HHRs.

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Section: Discussionmentioning

confidence: 99%

Using a Handheld Refractometer in Remote Environments to Measure the Refractive Indices of a Variety of Solutions: Sucrose, Coffee, Methanol/Water, and 2-Propanol/Water

et al. 2021

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“…Examples include cell grid holders (21) and incubation chambers (22). Sample surveying using Atomic Force Microscopy cantilevers has also been 3D printed (23). Microfluidics can be used to control the movement of small liquid and particle volumes in a network of interconnected microchannels.…”

Section: D Printing In Microscopymentioning

confidence: 99%

The Field Guide to 3D Printing in Microscopy

Rosario¹,

Heil²,

Mendes³

et al. 2021

Preprint

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The maker movement has reached the optics labs, empowering researchers to actively create and modify microscope designs and imaging accessories. 3D printing has especially had a disruptive impact on the field, as it entails an accessible new approach in fabrication technologies, namely additive manufacturing, making prototyping in the lab available at low cost. Examples of this trend are taking advantage of the easy availability of 3D printing technology. For example, inexpensive microscopes for education have been designed, such as the FlyPi. Also, the highly complex robotic microscope OpenFlexure represents a clear desire for the democratisation of this technology. 3D printing facilitates new and powerful approaches to science and promotes collaboration between researchers, as 3D designs are easily shared. This holds the unique possibility to extend the open-access concept from knowledge to technology, allowing researchers from everywhere to use and extend model structures. Here we present a review of additive manufacturing applications in microscopy, guiding the user through this new and exciting technology and providing a starting point to anyone willing to employ this versatile and powerful new tool.

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“…This activity introduces students to fundamental concepts in measurement science such as instrument calibration, spatial resolution, precision, and parameter optimization. After completing the activity, students should be able to use fundamental knowledge to understand other scanning probe-, light-, electron-, and X-ray-based imaging modes used in chemistry, geology, physics, and materials science. − …”

Section: Introductionmentioning

confidence: 99%

LBIC Imaging of Solar Cells: An Introduction to Scanning Probe-Based Imaging Techniques

et al. 2023

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Scanning probe-based microscopes (SPMs) are widely used in biology, chemistry, materials science, and physics to image and manipulate matter on the nanoscale. Unfortunately, high school and university departments lack expensive SPM tools and materials microscopy activities to educate a large number of students in this vital SPM imaging technique. As a result, students face challenges participating in and contributing value to the nanotechnology revolution driving modern scientific innovations. Here we demonstrate an affordable scanning laser-based imaging system (approximately $400, excluding the computer) to introduce students to the point-by-point image formation process underlying SPM methods. In this laboratory activity, students learn how to construct and optimize images of a working solar panel using a laser beam-induced current (LBIC) imaging system. We envision undergraduate and graduate students should be able to use this LBIC system for independent solar energy research projects as well as apply fundamental knowledge and measurement skills to understand other SPM techniques.

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Three-Dimensional Printing of a Model Atomic Force Microscope to Measure Force–Distance Profiles

Cited by 7 publications

References 20 publications

Using a Handheld Refractometer in Remote Environments to Measure the Refractive Indices of a Variety of Solutions: Sucrose, Coffee, Methanol/Water, and 2-Propanol/Water

Using a Handheld Refractometer in Remote Environments to Measure the Refractive Indices of a Variety of Solutions: Sucrose, Coffee, Methanol/Water, and 2-Propanol/Water

The Field Guide to 3D Printing in Microscopy

LBIC Imaging of Solar Cells: An Introduction to Scanning Probe-Based Imaging Techniques

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