20.109(S15):Module 3

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20.109(S15): Laboratory Fundamentals of Biological Engineering

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Contents

Module 3

Lecturer: Angela Belcher
Instructors: Shannon Hughes, Noreen Lyell, and Leslie McClain

TA: Cherry Gao

“Invention” is a wonderful word, derived from words meaning “scheme” and “a finding out.” Inventors draw on materials provided by the natural world, refining and combining them in insightful ways, to make something useful. In this experimental module we will invent materials by manipulating biological systems, namely the bacteriophage M13. We will use a very slightly modified phage to build Titanium dioxide nanowires and then we'll let the phage themselves do the building, assembling them into a solar cell. Drawing on the rich stockroom of biological elements and a good but incomplete understanding of their behavior, we’ll hope to invent some novel materials with real-world applications.

This module has been developed thanks to the generous time and thoughtful efforts of several Belcher lab members, in particular Xiangnan Dang
Image:Au nanowires credit blue.png

Module 3 Goals:
Create a dye-sensitized solar cell containing nanocomposites of gold nanoparticle-TiO2, using engineered M13 bacteriophage as the template to synthesize these materials. Visualize these virus-templated structures using transmission electron microscopy, and assess how the size of gold nanoparticles impacts the efficiency metrics of the assembled solar cell.


Module 3 Experimental Overview:
Two different engineered M13 bacteriophage are used in this module: DSPH, which binds singled-walled carbon nanotubes (SWNTs), and p8#9, which can bind gold nanoparticles (AuNPs). First, DSPH and p8#9 will be isolated from separate infected bacterial cultures by centrifugation and PEG precipitation, and the resulting phage concentrations determined using a spectrophotometer. The SWNTs will be combined with the DSPH phage at an ratio that has been optimized by the Belcher lab -- these complexes will be utilized by Tahoura and Jackie to build a control solar cell. You will complex your phage (p8#9) with three different sizes of gold nanoparticles (AuNP) to determine there exists an optimal diameter of the gold nanoparticle for light collection. These phage:SWNT or phage:AuNP complexes will next be coated with biotemplated titanium dioxide, imaged using transmission electron microscopy (TEM), and ultimately ground into a titania paste which will be incorporated into the dye-sensitized solar cell (DSSC). You will then text the DSSC using an instrument that mimics sunlight.


Background Links:
- Nature Nanotechnology: Virus Templated self-assembled single-walled carbon nanotubes for highly efficient collection in photovoltaic devices
- An animation video of how DSSC's are assembled. Remember, Dr. Belcher's procedure is a little different from what is described here, but it provides a good visual overview.

Lab links: day by day

Day 1: Growth of phage nanowires
Day 2: Biotemplating on phage nanowires
Day 3: TEM
Day 4: Solar cell assembly
Day 5: Solar cell testing
Day 6: Wrap-up and data summary
Day 7: Student presentations

Assignments

Research proposal presentation
Biomaterial engineering report
20.109 Blog summary

Notes for Teaching Faculty

TA notes, mod 3
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