First-in-class organic materials for efficient multiple exciton generation

This technology identifies several first-in-class organic polymers exhibiting intramolecular singlet fission at yields approaching 200% that are extremely tunable and amenable to mass-production.

Unmet Need: Singlet fission materials for increased photovoltaic efficiency

Silicon-based photovoltaics (PV) are used in the vast majority of solar energy devices, but are limited by (a) the wavelength of an incoming photon and (b) the ability to generate only a single electron-hole pair per incoming photon, leading to a theoretical maximum efficiency of ~33%. Singlet fission (SF) occurs when a single high-energy particle is absorbed by a material and divides the energy into two or more excitons, each capable of generating an electron-hole pair. This process, referred to as multiple exciton (ME) generation, has recently attracted much interest for its potential to increase the theoretical maximum efficiency of any optoelectronic system, notably raising the efficiency of solar cells from ~33% to ~44%. Aggregates of conjugated/aromatic molecules have been shown to exhibit SF, but lack tunability, efficiency, and triplet formation rate/stability, which make their applications limited. Alternatively, currently available conjugated polymers that exhibit SF suffer from lack of solubility, limited efficiency, or are difficult to synthesize which make their applications impractical.

The Technology: Materials capable of intramolecular singlet fission that generate long-lasting, high energy excitons

This technology addresses these shortcomings by describing several first-in-class polymers that can undergo rapid singlet fission while generating a large population of long lived triplets (microsecond time scale). By linking the acceptor and donor molecules into a co-polymer, design and manufacturing constraints on previously described solid intermolecular SF systems are relieved. These materials have been optimized for adoption in third-generation solar cells by offering high solubility for mass-production combined with high yield of ME that approaches 200% to dramatically improve efficiency. Importantly, by combining various derivations of linkers, polymer subunits, and functionalized acceptor or donor molecules, the materials allow for extensive tuning of electronic, optical, structural, and physical properties, offering a suite of applications beyond solar cells, to include photonic devices, sensors, and integrated circuits.

Applications:

Conventional and inverted OPV devices and solar cells
Hybrid photovoltaic devices, fission sensitizer in inorganic applications (e.g., silicon, CIGS, etc.)
Organic field effect transistors (OFETs), organic thin film transistors (OTFTs), organic light emitting diodes (OLEDs), organic light emitting transistors (OLETs)
Nanoparticle/Quantum dot devices
Integrated circuits (ICs) and logic circuits
Capacitors
Radio frequency identification (RFID) tags
Laser diodes
Photoconductors/photodetectors
Electrophotographic devices
Organic memory devices
Sensor devices
Charge injection/planarising layers
Schottky diodes
Antistatic films
Conducting substrates/patterns
Photonic systems

Advantages:

High yield (170-200%) of triplet excitons
Increase maximum yield of PV from 33% to 44%
Rapid generation of remarkably stable excitons
Simpler synthesis and material deposition than existing materials
Made from non-toxic, organic materials

Lead Inventor:

Luis M. Campos, Ph.D.

Patent Information:

Patent Status

Related Publications:

Tech Ventures Reference:

IR CU17103
Licensing Contact: Greg Maskel