Towards the Automation of Scalable Carbon Nanotube Sorting via Aqueous Two-Phase Extraction
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Date
2022-09-29
Authors
Robitaille, Marcel
Advisor
Kim, Na Young
Journal Title
Journal ISSN
Volume Title
Publisher
University of Waterloo
Abstract
Carbon nanotubes are an exciting quantum material with numerous interesting and unique
properties. Notable electric properties are their variable band-gap and metallic and semi-
conducting variants. Carbon nanotubes are a prime candidate for beyond-silicon devices
and have already been used in experimental computer processors. Carbon nanotubes have
valuable optical, chemical, and mechanical properties as well.
Many of these novel properties such as the band-gap and absorption spectrum depend
on the carbon nanotube’s chirality, which is related to its diameter. Unfortunately, no
method for carbon nanotube synthesis has yet been able to produce pure, single-chirality
nanotubes. Applications requiring a specific chirality must thus sort the synthesised nan-
otubes after the fact. The most scalable and affordable sorting method is aqueous two-
phase extraction (ATPE). However, this procedure requires significant time and skill as it
involves many stages of micro-pipetting.
The subject of this thesis is the automation of ATPE. Since this is a water-based
procedure, the core around which the automated system is built is an off-the-shelf liquid
handling robot. The majority of this text describes the custom extensions to this robot that
make it capable of ATPE. The Photo Stage provides an environment to capture consistent
images of the two-phase system, and the accompanying computer vision software analyses
the image and locates the phase boundary. This information is used to programmatically
extract the top phase. Transportation of vials is accomplished by the addition of the
Gripper. The caps are removed from vials and tubes using the Vial Opener. The Powder
Handling System has the goal of automating the creation of chemical stocks. The Inventory
System is designed to track the contents and history of ATPE process vials. Finally,
a robotic arm will integrate external instruments including a centrifuge, sonicator, and
spectrophotometer. However, this is not complete and is planned for the second generation
of the project.
Without the integration of the centrifuge, which is required at every step of ATPE to
partition the solution into two phases, it is impossible to carry out ATPE from start to
finish. Thus, the system is being used in a mode referred to as hybrid ATPE. Under these
conditions, when the centrifuge is needed, the system is paused so that a human operator
can transfer the vials to the centrifuge. When the centrifuge has finished, the vials are
transferred back to the liquid handling robot and the system is resumed. This hybrid
system takes advantage of the Gripper, Vial Opener, and Photo Stage. The Inventory
System is incomplete in that the camera has not been mounted, however the associated code
can already be used to track the contents of vials if the identifier is entered manually rather than automatically being read from a barcode or other marker. The Powder Handling
System, which is for the pre-processing step of stock-making and not for the main ATPE
process, is not complete. A precision balance has been purchased and a conveyor has been
developed, but there have been multiple failed attempts to fabricate a powder dispenser.
Thus, the Powder Handling System is not used and stocks are still created manually.
Finally, the external robotic system is not complete and is not used for hybrid ATPE.
Under hybrid ATPE, it has been possible to automatically extract the top phase from
two-phase systems. The reliability of the computer vision boundary recognition system has
been increased to > 95 %. However, the results of automated separation leave room for
improvement. The robotic system leaves more discarded waste around the boundary than
when ATPE is performed manually, and there is a heightened risk of contaminating the
boundary. The reason for this is that the pipettes of the liquid handling robot are always
vertical, parallel to the vial. This prevents the liquid that wicks up the vial walls by
capillary action from being properly extracted. This will be addressed by future additions
to the robotic system.
Description
Keywords
carbon nanotube, aqueous two-phase extraction, automation, robotics