Atomic force microscopy analysis of alkali textured silicon  substrates for solar cell applications

Fashina, Adebayo Adeboye; Adama, K. K.; Abdullah, Lookman; Ani, C.J.; Oyewole, Oluwaseun K.; Asare, Joseph; Anye, Vitalis C.

doi:10.14419/ijpr.v6i1.8795

Cited by 5 publications

(2 citation statements)

References 29 publications

(40 reference statements)

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“…[155] The influence of surface properties for textured silicon substrates has been explored with AFM for potential light trapping applications in silicon solar cells, with results suggesting that modulated texturing of silicon substrates can be beneficial in the augmentation of photoconversion and the efficiency of silicon solar cells. [156] Most importantly, the first successful mapping of photocarrier lifetimes on silicon nanocrystal-based solar cell structures using KPFM has presented an analytical approach on conducting KPFM lifetime measurement with a higher lateral resolution for surface potential investigation and with satisfactory precision. [157] The image displayed in Figure 7 was obtained under tapping mode AFM condition from a degraded solar cell structure containing heterojunction with intrinsic thin layer (HIT).…”

Section: Silicon-based Solar Cellsmentioning

confidence: 99%

Advances in the Use of Atomic Force Microscopy as a Diagnostic Tool for Solar Cells Characterization: From Material Design to Device Applications

Ahia,

Meyer

2023

Physica Status Solidi (a)

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Considerable efforts in search for an effective characterization technique for photovoltaic devices with utmost precision is on the increase. For precise analysis and tailoring of device performance, a reliable technique is vital. Atomic force microscopy is one of the leading surface analysis techniques of choice for probing surface patterns in a variety of materials with atomic precision using a cantilever. It has evolved as a reliable technique for the investigation of subatomic scale properties of materials such as photocurrent heterogeneity, electromechanical response, charge distribution, molecular weight effects, and many other material parameters. The integration of artificial intelligence hybrid algorithms in atomic force microscope for optoelectronic device fabrication and characterization has increasingly emerged to be desirable due to its reliability and effectiveness in achieving high image resolution, automated analysis, actuation, and the coupling of manufactured units with a precision down to atomic units. In this review, an investigation of topical developments in the use of atomic force microscopy as a diagnostic tool for solar cells characterization is presented with special focus on polymer solar cells, perovskite solar cells, quantum dots‐sensitized solar cells, dye‐sensitized solar cells, fullerene‐based solar cells, III‐V‐based solar cells, and silicon‐based solar cells.

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Section: Silicon-based Solar Cellsmentioning

confidence: 99%

Advances in the Use of Atomic Force Microscopy as a Diagnostic Tool for Solar Cells Characterization: From Material Design to Device Applications

Ahia,

Meyer

2023

Physica Status Solidi (a)

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“…However, the solar cell technologies that are required to convert solar energy into electricity have to be efficient, cost effective and must have a long lifespan before it can be put forward for commercialization. Presently, crystalline silicon-based solar cells with relatively high efficiency of about 22 percent accounts for a large portion of the solar panels sold in the world [2]. Although, silicon is in abundant as a raw material used for these solar cells, its processing appears to be complicated and thus increases the manufacturing costs, making the end-product to be quite expensive.…”

Section: Introductionmentioning

confidence: 99%

Is there a possibility of perovskite taking over the solar technology market by 2030?

O.Fashina

2019

IJPR

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In recent time, there have been enormous advances in the development of perovskite solar cells in terms of its efficiency, rising from 3.8 percent in 2009 to 23.7 percent in 2018. This took other solar technologies over thirty years of research to accomplish. On the other hand, perovskite proffers a more affordable solution since it is potentially much cheaper to produce and relatively simple to manufacture than silicon solar cells. In spite of this great potential, perovskite solar cell technology is still in the premature stages of commercialization due to a number of concerns. Moreover, like with many new technologies, there is a difference between what works in the laboratory at small-scale and in the factory at large-scale. Thus, looking at perovskites as a material, it has the tendency to be a bit unstable at high temperature and susceptible to moisture and these could cause the decomposition of cells. The question here is: can perovskite outshine silicon solar cel1s in the next 10 years considering the successes so far and the vigorous research that is presently taking place globally?

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Experimental Investigation of AWJ Slicing of Single Crystal Silicon Using Fuzzy Grey Relational Analysis (FGRA)

Raj

Sethuramalingam

2022

Silicon

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Atomic force microscopy analysis of alkali textured silicon substrates for solar cell applications

Cited by 5 publications

References 29 publications

Advances in the Use of Atomic Force Microscopy as a Diagnostic Tool for Solar Cells Characterization: From Material Design to Device Applications

Advances in the Use of Atomic Force Microscopy as a Diagnostic Tool for Solar Cells Characterization: From Material Design to Device Applications

Is there a possibility of perovskite taking over the solar technology market by 2030?

Experimental Investigation of AWJ Slicing of Single Crystal Silicon Using Fuzzy Grey Relational Analysis (FGRA)

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