Organic Radicals for Symmetric Redox Flow Batteries

Jelte S. Steen

doi:10.33612/diss.252020984

Organic Radicals for Symmetric Redox Flow Batteries

Jelte S. Steen

Moleculaire Anorganische Chemie

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Samenvatting

Redox flow batteries (RFBs) are considered one of the pivotal technologies for addressing the intermittency problem in renewable energy sources, due to their modular design that allows for the decoupling of power and energy and high cost-effectiveness in long-duration storage. In this thesis we present several new developments in the field of (symmetric) organic RFBs, which are the following: (1) development of Blatter radicals as novel bipolar redox-active organic molecules for both aqueous and non-aqueous symmetric RFBs. (2) Study of decomposition pathways of electrolytes containing Kuhn’s verdazyl and Blatter radicals as active material that occur during battery charge/discharge cycling. Gaining a better understanding of the degradation mechanism at play is essential for the design of more stable battery material. (3) Method development of spectroscopies for studying battery performance during cycling.

Originele taal-2	English
Kwalificatie	Doctor of Philosophy
Toekennende instantie	Rijksuniversiteit Groningen
Begeleider(s)/adviseur	Otten, Edwin, Supervisor Browne, Wesley, Supervisor
Datum van toekenning	22-nov.-2022
Plaats van publicatie	[Groningen]
Uitgever	University of Groningen
DOI's	https://doi.org/10.33612/diss.252020984
Status	Published - 2022

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10.33612/diss.252020984

Title and contentsFinal publisher's version, 359 KB
Chapter 1Final publisher's version, 3,22 MB
Chapter 2Final publisher's version, 2,91 MB
Chapter 3Final publisher's version, 1,81 MB
SummaryFinal publisher's version, 131 KB
SamenvattingFinal publisher's version, 132 KB
AcknowledgementsFinal publisher's version, 136 KB
PropositionsFinal publisher's version, 102 KB

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Citeer dit

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AB - Redox flow batteries (RFBs) are considered one of the pivotal technologies for addressing the intermittency problem in renewable energy sources, due to their modular design that allows for the decoupling of power and energy and high cost-effectiveness in long-duration storage. In this thesis we present several new developments in the field of (symmetric) organic RFBs, which are the following: (1) development of Blatter radicals as novel bipolar redox-active organic molecules for both aqueous and non-aqueous symmetric RFBs. (2) Study of decomposition pathways of electrolytes containing Kuhn’s verdazyl and Blatter radicals as active material that occur during battery charge/discharge cycling. Gaining a better understanding of the degradation mechanism at play is essential for the design of more stable battery material. (3) Method development of spectroscopies for studying battery performance during cycling.

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