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Contact; Name Title Thomas Anthopoulos Professor of Experimental Physics, Department of Physics. Research is centered on understanding the physical properties of functional electronic materials and applying this fundamental understanding to develop improved materials and devices for application in electronics, displays, lighting, energy generation & harvesting and
Organic photovoltaic (OPV) cells have highly tunable light-response ranges, enabling them to achieve high power conversion efficiencies (PCEs) in various scenarios. Until now, most studies of these devices have focused on developing highly efficient OPV cells under the standard AM 1.5G solar radiation. Howev
High-performance organic photovoltaic modules using eco-friendly solvents for various indoor application scenarios. Joule, 6 (2022), pp. 2138-2151. View PDF View article View in Scopus Google Scholar Tandem organic solar cell with 20.2% efficiency. Joule, 6 (2021), pp. 171-184. View in Scopus Google Scholar
Organic photovoltaic (OPV) cells hold the promise of providing energy to support the Internet of Things (IoT) ecosystem smart instruments including remote sensors, calculators, smart meters, wearable devices, and communication devices, are increasingly being adopted in various applications such as smart homes, factories, offices, and wearable technology [3, 4].
Organic solar cells (OSCs), which are widely regarded as the promising power source for next-generation electronics, have potential applications in architecture-integrated photovoltaics, the internet of things (IoTs), self-powered wearable sensors, electronic textiles, and implantable sensors due to their instinct nature of flexibility and high
In such a scenario, the photovoltaic modules would actually upgrade the value of land by its double usage. fill factor) and resulting power conversion efficiency for a solar
The past decade has witnessed tremendous advances in the power conversion efficiency (PCE) of organic photovoltaic cells. Concomitantly, the chemical structures of
Conversion of solar energy into useful electrical light by semiconducting materials is termed as photovoltaics (PV) and the device involved in conversion is called as photovoltaic cell. Main component and building block of a PV is a solar cell. A cell which converts energy of photons into electricity i.e., direct current (DC) is coined as solar
Harvesting indoor light to power electronic devices for the Internet of Things has become an application scenario for emerging photovoltaics, especially utilizing organic photovoltaics (OPVs).
An organic solar cell (also known as OPV) is a type of solar cell where the absorbing layer is based on organic semiconductors (OSCs). Typically, these are either polymers or small
Organic PV cells offer diverse and promising applications, with one notable use being building-integrated photovoltaics (BIPV). BIPV involves seamlessly incorporating solar
Organic photovoltaic cells are thin, lightweight, flexible and semi-transparent. These characteristics unlock new possibilities for applications in agriculture, architecture, wearable electronics
With the growing development of the Internet of Things, organic photovoltaic (OPV) cells are highly desirable for indoor applications due to the unique features of lightweight, flexibility and
This paper provides a concise summary on the latest progress of the promising applications of OSCs, including flexible cells, semitransparent cells and indoor cells. More
Organic photovoltaic (OPV) cells, also known as organic solar cells, are a type of solar cell that converts sunlight into electricity using organic materials such as polymers and small
Organic solar cells (OSCs) have unique advantages such as simple fabrication process, low manufacturing cost, flexible and foldable, which can be applied to scenarios where rigid inorganic solar cells are not applicable, , , and form complementary advantages with inorganic solar cells.
Combing with the stability investigations of the opaque IOPV ternary modules, our work represents an important step forward in the optimized photoactive layer system to
Recent works demonstrated that most efficient systems for the development of novel PVs are based on either the organic solar cell (OSC) or perovskite solar cell (PSC)
Non-fullerene acceptors have revolutionized organic photovoltaics by offering customizable molecular structures, enabling precise energy levels and absorption characteristics, making them ideal for customizing materials for specific applications [20, 22].Non-fullerene materials offer excellent stability and resistance to degradation, making them more durable
An organic solar cell (OSC) uses p-type and n-type organic layers sandwiched between a transparent electrode and a metallic electrode. OSCs have the advantage of providing feasible solution processed fabrication, low costs, color-tuning, and weight-light and flexible device fabrication.
Combining a ternary strategy with green solvents for overcoming the lack of high-performance wide-band-gap acceptors and harmful solvents suitable for indoor applications is demonstrated. The tetrahydrofuran-processed opaque and semitransparent modules not only exhibit promising efficiencies of 21.98% and 14.77% but also possess excellent operational
High-performance organic photovoltaic modulesusingeco-friendlysolventsforvarious indoor application scenarios Combining a ternary strategy with green solvents for overcoming the lack of high-performance wide-band-gap acceptors and harmful solvents suitable for indoor applications is demonstrated. The tetrahydrofuran-processed opaque and
One of the biggest application scenarios of semitransparent PV technology is to integrate into the building facade to achieve building photovoltaic integration. But so far, this kind of building integrated photovoltaic is still dominated by crystalline silicon solar modules. (BHJ) of the organic solar cell is also easily damaged. Therefore
High-performance organic photovoltaic modules using eco-friendly solvents for various indoor application scenarios Qiang Wu, Yue Yu, Xinxin Xia, Yuhan Gao, Tao Wang, Rui Sun, Jing Guo, Shanshan external quantum efficiency was measured by a Solar Cell Spectral Response Measurement System QE-R3011 (Enli Technology Co., Ltd.). A calibrated silicon
In 1986, Tang reported the first organic solar cell with a power conversion efficiency (PCE) close to 1% . In this work, a heterojunction composed of a p-type (donor) and an n-type (acceptor) organic semiconductors provides the energy difference to dissociate the photogenerated excitons at the donor/acceptor interface, carrying the holes in the highest
Organic photovoltaic (OPV) cells, also known as organic solar cells, are a type of solar cell that converts sunlight into electricity using organic materials such as polymers and small molecules. 83,84 These materials are carbon-based and can be synthesized in a laboratory, unlike inorganic materials like silicon that require extensive mining and processing. 84,85 OPV cells work by
Organic solar cells have the potential to become the cheapest form of electricity, beating even silicon photovoltaics. This article summarizes the state of the art in
Figure 1A illustrates some application scenarios of bifacial solar cells. Now, commercialized bifacial silicon solar cells have shown great superiority in solar energy conversion. Notably, the thickness of the silicon
Perovskites have emerged as promising light harvesters in photovoltaics. The resulting solar cells (i) are thin and lightweight, (ii) can be produced through solution processes, (iii) mainly use low-cost raw materials, and (iv) can be flexible. These features make perovskite solar cells intriguing as space technologies; however, the extra-terrestrial environment can easily cause the