Understanding and Modulating Interactions Between Polymers and Nanoparticles for Effective Catalyst Design in Polymer Upcycling Anirban Majumder

Format:

Book

Thesis/Dissertation

Author/Creator:

Majumder, Anirban, author.

Contributor:

University of Pennsylvania. Chemical and Biomolecular Engineering., degree granting institution.

Language:

English

Subjects (All):

Chemical engineering.

Physical chemistry.

Polymer chemistry.

Nanotechnology.

Plastics.

0542.

0795.

0652.

0495.

0494.

Local Subjects:

Chemical engineering.

Physical chemistry.

Polymer chemistry.

Nanotechnology.

Plastics.

0542.

0795.

0652.

0495.

0494.

Physical Description:

1 electronic resource (149 pages)

Contained In:

Dissertations Abstracts International 86-12B

Place of Publication:

Ann Arbor : ProQuest Dissertations and Theses, 2025

Language Note:

English

Summary:

Despite recent advances in catalytic conversion of plastic waste into high-value chemicals, the interactions between polymers and catalysts, which are highly porous nanomaterials, are not well understood. Fundamental understanding of these interactions and the ability to modulate them would allow us to design effective catalysts for polymer upcycling reactions. To study the interactions between polymers and nanomaterials, quantifying them is essential. In this thesis, we employ a quantitative technique to directly measure the contact angle between polymers and nanoparticles, enabling us to investigate various aspects of polymer-catalyst interactions that are crucial for polymer upcycling reactions. We measure the contact angle of polyolefins with silica nanoparticles, a commonly used support in heterogeneous catalysis, and modify the surface chemistry of these nanoparticles by depositing catalytic metals and metal oxides via atomic layer deposition (ALD) and using silane chemistry. Our findings show that the polarizability of polyolefins plays a significant role in their interactions with catalytic support materials, and modifying the polarity of the support material could be an effective way to tune polymer-catalyst interactions. Further, we find that the polymer-catalyst interactions are dominated by interactions of the polymers with the support materials and not with the metal catalytic sites. We also probe the influence of common plastic additives, namely primary antioxidants (PAOs), benzophenones and hindered amine light stabilizers (HALS), on the polymer-catalyst interactions by adding them to purified high-density polyethylene (HDPE) and measuring the contact angle on silica nanoparticles. We observe that while the addition of PAOs and benzophenones to polyolefins does not affect their interactions with silica significantly, HALS strongly alter the polymer-silica interactions. Hence, the presence of different types of additives in plastics might necessitate different strategies to design catalysts for polymer upcycling reactions. Overall, this thesis sheds light on some key unanswered questions on polymer-catalyst interactions and paves the way for future innovations in polymer upcycling and engineering catalysts for other polymeric reactions

Notes:

Source: Dissertations Abstracts International, Volume: 86-12, Section: B.

Advisors: Lee, Daeyeon Committee members: Vohs, John M.; Winey, Karen I.; Riggleman, Robert A.

Ph.D. University of Pennsylvania 2025

Local Notes:

School code: 0175

ISBN:

9798280758087

Access Restriction:

Restricted for use by site license