Balancing the Selective Absorption and Photon‐to‐Electron Conversion for Semitransparent Organic Photovoltaics with 5.0% Light‐Utilization Efficiency

Abstract: Efficiently converting invisible light while allowing full visible light transmission is key to achieving high‐performance semitransparent organic photovoltaics (ST‐OPVs). Here, a detailed balance strategy is explored to optimize the ST‐OPV via taking both absorption and carrier dynamics into consideration. Based on this principle, comprehensive optimizations are carried out, including a ternary strategy, donor:acceptor blend ratio, thickness, antireflection, etc., to compromise the invisible energy conversion… Show more

“…6h suggests the potential of semi-transparent OSCs for aesthetic and colorful solar windows. 60–62 Overall, non-halogenated and non-aromatic THF-processed PBDB-T-2F(3/4) successfully demonstrated its great potential as an eco-friendly photoactive donor for real applications of OSCs as a clean energy source.…”

A newly designed benzodithiophene building block: tuning of the torsional barrier for non-halogenated and non-aromatic solvent-processible photovoltaic polymers

“…6h suggests the potential of semi-transparent OSCs for aesthetic and colorful solar windows. 60–62 Overall, non-halogenated and non-aromatic THF-processed PBDB-T-2F(3/4) successfully demonstrated its great potential as an eco-friendly photoactive donor for real applications of OSCs as a clean energy source.…”

A newly designed benzodithiophene building block: tuning of the torsional barrier for non-halogenated and non-aromatic solvent-processible photovoltaic polymers

“…4,5 With the fast evolution in photo-active materials and device architecture designs, the performance of OPVs, which is one of their major shortcomings compared to their counterparts, has continued to soar in recent years. [6][7][8][9][10][11][12][13][14][15][16][17][18][19][20] To date, the highest power conversion efficiencies (PCEs) of OPVs have reached as high as 19.76% and 20.2% for single-junction and tandem devices, respectively, which can basically meet the commercialization threshold of the photovoltaic industry. 21,22 Although OPVs can potentially be more flexible and adaptive for future applications, the present high-performance device is realized with a brittle and expensive indium tin oxide (ITO)-glass substrate, which removes most of OPVs' merits.…”

Versatile organic photovoltaics with a power density of nearly 40 W g⁻¹

“…As one of the promising photovoltaic technologies for addressing energy and environmental issues, organic solar cells (OSCs) have the characteristics of low cost, flexibility, lightweightness, environmental friendliness, large-area printing manufacture, etc. 1–5 To date, the power conversion efficiency (PCE) of OSCs has reached remarkable values exceeding 19% owing to the invention of new active layer materials, especially non-fullerene acceptors (NFAs) with acceptor–donor–acceptor (A–D–A) architectures 6–13 and efficient morphology control 14–18 for device fabrication and optimization. In the past decade, side chain engineering has proven to be an efficient method for the delicate design of active layer materials and precise regulation of the corresponding morphology because solubility, 19,20 crystallization 21 and packing modes, 22,23 etc.…”

Side chain isomerization enables high efficiency and thickness tolerant organic solar cells