Inorganic semiconductor solar cells

Overview: Photovoltaic Solar Cells, Science, Materials, Artificial

In the first generation of solar cells most inorganic semiconductors are based on pn-junctions obtained from single-crystal or doped polycrystalline silicon. As the second most abundant element in the crust of the Earth, Si offers to manufacturers easier access to raw materials. The second generation materials include thin films of amorphous silicon, CIGS,

Optimization of a high-performance lead-free cesium

In this work, an ultra-thin (0.815 μm) lead-free all-inorganic novel PV cell structure consisting of solid-state layers with the configuration SnO 2 /ZnOS/CsGeI 3 /CZTSe/Au has been optimized using SCAPS-1D simulator.

A review of photovoltaic performance of organic/inorganic solar

This article reviews the rapid progress in the developments of inorganic and organic solar cells (SCs) such as silicon SCs, perovskite SCs, III-V SCs, quantum dot SCs,

Solution Processed Polymer–Inorganic Semiconductor Solar Cells

Hybrid solar cells based upon organic–inorganic semiconductor heterojunctions are currently the subject of significant interest as they incorporate the attractive properties of both organic and inorganic materials, including the ability to tune both the electronic and structural properties over a wide range using solution-based fabrication methods. 1-7 A configuration of

Advances in organic solar cells: Materials, progress, challenges

Bandgap energies of inorganic semiconductors match more suitably to the solar spectrum than organic materials but have lower absorptivity. Thus, stouter absorbing layers with increased purities are demanded in inorganic solar cells to ensure an efficient function. Cathode materials used are Ag, TiO 2, and Al, Mg, Ca for Organic and inorganic SCs, respectively.

Progress of inverted inorganic cesium lead halide perovskite solar cells

Inverted inorganic cesium lead halide (CsPbX3) perovskite solar cells (PSCs) have shown great potential in photovoltaic applications. Herein, Wang et al. overview their progress, summarize the strategies for optimizing functional layers and interfaces, and provide perspectives for future development.

Optimization of a high-performance lead-free cesium-based inorganic

In this work, an ultra-thin (0.815 μm) lead-free all-inorganic novel PV cell structure consisting of solid-state layers with the configuration SnO 2 /ZnOS/CsGeI 3 /CZTSe/Au has been optimized using SCAPS-1D simulator.

A universal Urbach rule for disordered organic semiconductors

Recently, research on organic solar cells has seen significant progress through the development of non-fullerene electron acceptors (NFAs), in particular delivering increases in single-junction

The Energy Level Conundrum of Organic Semiconductors in Solar Cells

For J–V characterization of solar cells, up to 12 identical cells were measured for each type of devices. Acknowledgements This publication was based upon the work supported by King Abdullah University of Science and Technology (KAUST) Office of Sponsored Research (OSR) under Award no: OSR-2018-KAUST-KAU Initiative-3902, OSR-2019-CARF/CCF-3079,

All-solid-state dye-sensitized solar cells with high

Dye-sensitized solar cells based on titanium dioxide (TiO 2) are promising low-cost alternatives to conventional solid-state photovoltaic devices based on materials such as Si, CdTe and CuIn...

Selenium substitution for dielectric constant improvement and

Typical inorganic solar cell semiconductors exhibit higher ε r such as Si (~12) 11 and Gallium Arsenide (~12) 12,13, the emerging organic/inorganic hybrid perovskite solar cells present ε r of

Progress of inverted inorganic cesium lead halide

Inverted inorganic cesium lead halide (CsPbX3) perovskite solar cells (PSCs) have shown great potential in photovoltaic applications. Herein, Wang et al. overview their progress, summarize the strategies for optimizing

Amorphous inorganic semiconductors for the

Recently, amorphous inorganic semiconductors have been applied in a variety of new technologies, including solar cells, photoelectrocatalysis, and photocatalysis. It has been reported that

Inorganic photovoltaic cells

The inorganic semiconductor materials used to make photovoltaic cells include crystalline, multicrystalline, amorphous, and microcrystalline Si, the III-V compounds and alloys, CdTe, and the chalcopyrite compound, copper indium gallium diselenide (CIGS). We show the structure of the different devices that have been developed, discuss the main methods of

Efficient inorganic–organic hybrid heterojunction solar cells

Inorganic–organic hybrid structures have become innovative alternatives for next-generation dye-sensitized solar cells, because they combine the advantages of both systems.

Organic–Inorganic Hybrid Solar Cells | SpringerLink

Organic–inorganic hybrid solar cells combine organic materials, often polymers, with inorganic materials like semiconducting nanoparticles to create solar cells with

Amorphous inorganic semiconductors for the

This review first introduces the general background of amorphous inorganic semiconductor properties and synthesis. Then, the recent successes and current challenges of amorphous inorganic semiconductor

Research status of all-inorganic perovskite solar cells: A review

Due to the excellent bipolar carrier transport properties and micro-scale electron-hole diffusion length of perovskite materials, planar heterojunction all-inorganic

Organic Semiconductor Interfaces and Their Effects in Organic Solar Cells

Energy levels and energy level alignment at interfaces play a decisive role in designing efficient and stable organic solar cells (OSCs). In this review two usually used technologies in organic photovoltaic communities for measuring energy levels of organic semiconductors, photoelectron spectroscopy and electrochemical methods, are introduced,

All-solid-state dye-sensitized solar cells with high efficiency

Dye-sensitized solar cells based on titanium dioxide (TiO 2) are promising low-cost alternatives to conventional solid-state photovoltaic devices based on materials such as Si, CdTe and CuIn...

Device modeling of perovskite solar cells based on structural

Device modeling of CH3NH3PbI3−xCl3 perovskite-based solar cells was performed. The perovskite solar cells employ a similar structure with inorganic semiconductor solar cells, such as Cu(In,Ga

Research status of all-inorganic perovskite solar cells: A review

Due to the excellent bipolar carrier transport properties and micro-scale electron-hole diffusion length of perovskite materials, planar heterojunction all-inorganic perovskite solar cells have emerged to simplify the cell preparation process and draw inspiration from the structure of organic solar cells [27].

Inorganic photovoltaic cells

The inorganic semiconductor materials used to make photovoltaic cells include crystalline, multicrystalline, amorphous, and microcrystalline Si, the III-V compounds and alloys, CdTe, and the chalcopyrite compound, copper indium gallium diselenide (CIGS). We show the structure of the different devices that have been developed, discuss the main

Organic–Inorganic Hybrid Solar Cells | SpringerLink

Organic–inorganic hybrid solar cells combine organic materials, often polymers, with inorganic materials like semiconducting nanoparticles to create solar cells with unique properties and advantages. These hybrid solar cells aim to harness the benefits of both organic and inorganic materials to improve efficiency, stability, and cost

A review of photovoltaic performance of organic/inorganic solar cells

This article reviews the rapid progress in the developments of inorganic and organic solar cells (SCs) such as silicon SCs, perovskite SCs, III-V SCs, quantum dot SCs, dye sensitized SCs, flexible SCs, thin film SCs and tandem SCs. This article highlights the factors influencing the photovoltaic (PV) performance of SCs such as solar cell

Amorphous Inorganic Semiconductors for the Development of Solar Cell

1 Amorphous Inorganic Semiconductors for the Development of Solar Cell, Photoelectrocatalytic and Photocatalytic Applications Bing Wang,a,b# Gill M. Biesold,a# Meng Zhang,a Zhiqun Lina* aSchool of Materials Science and Engineering, Georgia Institute of

Amorphous inorganic semiconductors for the development of solar cell

This review first introduces the general background of amorphous inorganic semiconductor properties and synthesis. Then, the recent successes and current challenges of amorphous inorganic semiconductor-based materials for applications in solar cells, photoelectrocatalysis, and photocatalysis are addressed. In particular, we discuss

Selenium substitution for dielectric constant improvement and

Typical inorganic solar cell semiconductors exhibit higher ε r such as Si (~12) 11 and Gallium Arsenide (~12) 12,13, the emerging organic/inorganic hybrid perovskite solar cells

Inorganic semiconductor solar cells

6 FAQs about [Inorganic semiconductor solar cells]

Are amorphous inorganic semiconductors suitable for solar cells and photoelectrocatalysis?

Then, the recent successes and current challenges of amorphous inorganic semiconductor-based materials for applications in solar cells, photoelectrocatalysis, and photocatalysis are addressed. In particular, we discuss the mechanisms behind the remarkable performances of amorphous inorganic semiconductors in these fields.

How efficient are solar cells based on inorganic-organic hybrids?

Solar cells based on these inorganic–organic hybrids exhibit a short-circuit current density Jsc of 16.5 mA cm −2, Voc of 0.997 V and fill factor of 0.727, yielding a power conversion efficiency of 12.0% under standard AM 1.5 conditions.

What is the efficiency of organic tandem solar cells?

The highest efficiency reported for organic tandem PV cell is 13.76%. The PV-performance of state of the art organic SCs is given in Table-9. Finally, the absorption range of solar cells plays a critical role in determining the PCE. The bandgap of active layer material determines the absorption range and PCE.

Which semiconductors can be used for solar energy conversion?

Different band-gap semiconductors can be used for the effective utilization of the solar spectrum for solar energy conversion. Based on this fact, various research groups have developed hetero-junction (HJ) SCs and HJ bipolar transistor SCs [ 13 ]. In 2013, B. Endres et al. [ 14] demonstrated a spin solar cell based on GaAs p-n junction.

Can thin film technology reduce the cost of organic solar cells?

Thin film technology can significantly reduce the cost of organic solar cells [ 336 ]. Low carrier mobility and poor optical absorption coefficient are the two most critical issues in the production of polymer based thin film organic SCs. Light trapping techniques and anti reflection techniques can be used for enhancing the PCE of organic SCs.

Can tandem cell technology improve PCE of organic solar cells?

Tandem cell technology can be used for effectively enhancing the PCE of organic PV cells. In the future, the stability, reliability, flexibility and optical transparency of the organic solar cells needs to be addressed before enter into the photovoltaic market.

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