Development of Carbon Nanotube Inks for Printed Electronics

Ritaine, Dialia

January 2023

Single-walled carbon nanotubes (SWNTs) have excellent electronic, mechanical, and optical properties that make them promising materials for various applications. However, SWNT production methods produce a mixture of semiconducting and metallic species and non-SWNT impurities limiting their incorporation into devices. Among the different purification methods, conjugated polymer sorting has proven to be a scalable and cost-effective method. Conjugated polymers can easily be tuned to disperse SWNT species and obtain solubility in target solvents. They are multifunctional structures that enable the purification and extraction of specific SWNTs while simultaneously enhancing their processability. Therefore, they are suitable as purification methods for the fabrication of SWNT-based devices, particularly for printed electronics. However, the polymer backbone and the non-conductive side-chains negatively impacts the performance of SWNT devices by preventing good contact between the nanotubes. We first functionalized our polymer with thermally cleavable side-chains and demonstrated that the removal of the side-chains leads to a higher conductivity. We obtained stable dispersions in two green solvents compatible with inkjet printing. We also functionalized our polymer with photocleavable side-chains and showed efficient cleavage in solution. These investigations represent a proof-of-concept that could be used for the development of SWNT-based devices where the removal of the side-chains will improve the device performance. Lastly, we synthesized a fluorene-based polymer that contains a photocleavable ortho-nitrobenzylether unit and is functionalized with hydrophilic side-chains. We demonstrated the degradation of the polymer in organic and aqueous solvents. These investigations highlight the challenges of dispersing SWNTs in aqueous solvents using conjugated polymer. / Thesis / Doctor of Philosophy (PhD) / The objective of this thesis is to develop cleavable complexes between conjugated polymers and single-walled carbon nanotubes (SWNTs) to maximize the potential performance of printed devices post-processing. We functionalized a conjugated polymer with cleavable side-chains and investigated the impact on the conductivity after their removal. In addition, this work also focuses on dispersing SWNTs in green solvents that are compatible with printing processes such as inkjet printing. Lastly, we synthesized a degradable and water-soluble conjugated polymers to produce dispersant free-SWNTs.

Organic Chemistry

Carbon Nanotubes

Conjugated Polymers

Supramolecular Functionalization

Click Chemistry

Printed Electronics

Supramolecular Functionalization of Single Walled Carbon Nanotubes with Conjugated Polymers

Patiguli, Yiming

10 1900

<p>Single-walled carbon nanotubes (SWNTs) are of special interest in current research due to their extraordinary mechanical, electronic and optical properties. Their unique structure, remarkable thermal and electrical conductivity, and high mechanical strength make SWNTs viable candidates for a wide range of device applications. However, pristine CNTs are not dispersible in most solvents, the main difficulties in CNT applications are related to their purification and solution-phase processing. In recent years, the supramolecular functionalization of SWNTs with conjugated polymers has received significant attention. Research within this field has been driven by the desire to find polymer structures that can selectively disperse certain nanotubes species with high efficiency.</p> <p>After a brief overview of the studies that are related to the investigation of the supramolecular interaction between various conjugated polymers and SWNTs (chapter 1), the synthesis of fluorene and thiophene-based conjugated polymers and their supramolecular complex formation properties with SWNTs are described (chapter 2, 3, 4, 5 and 6). In order to understand the effect that conjugated polymer structure has on formation of supramolecular complexes with SWNTs, various factors were investigated by: (1) altering the polymer backbone composition; (2) varying the polymer molecular weight; (3) introducing different solubilizing groups while the polymer backbone remained the same; (4) changing the polymer conformation. All of the resulting polymer-nanotube assemblies exhibit excellent solution stability in THF in the absence of excess unbound free polymer. The spectroscopic characterization of the polymer-SWNT complex materials indicated that the interaction between the conjugated polymers and SWNTs is strongly influenced by polymer structure.</p> <p>The interaction between a water soluble polythiophene derivative, poly[3-(3-N,N-diethylaminopropoxy)-thiophene] (PDAOT), and SWNTs is discussed in chapter 7. It is also demonstrated that the PDAOT-SWNT complexes form stable aqueous solutions that can be used for the fabrication of highly sensitive amperometric glucose biosensors.</p> / Doctor of Philosophy (PhD)

Carbon nanotube

conjugated polymer

supramolecular functionalization

polyfluorene

polythiophene

molecular weight

glucose biosensor

Polymer Chemistry

Polymer Chemistry

Photoresponsive supramolecular polymer films : comparison of the hydrogen and ionic bonding strategies

Kamaliardakani, Mahnaz

08 1900

No description available.

Supramolecular Functionalization

Azobenzene

Azopolymer Complex

Photo-Orientation

Photoisomerization

Photoinduced Surface Relief Grating

Fonctionnalisation Supramoléculaire

Azobenzène

Complexe Azopolymère

Photoisomérisation

Réseau de Relief de Surface