Miniaturization of InGaP/InGaAs/Ge solar cells for micro‐concentrator photovoltaics

Albert, Pierre; Jaouad, Abdelatif; Hamon, Gwénaëlle; Volatier, M.; Valdivia, Christopher E.; Deshayes, Yannick; Hinzer, Karin; Béchou, Laurent; Aimez, Vincent; Darnon, Maxime

doi:10.1002/pip.3421

Cited by 19 publications

(21 citation statements)

References 34 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…These tuning capabilities in adjustable SCs cover a multitude of aspects such as bandgap, [22] transparency, [17,20] color, [21] thermal management, [23][24][25] mechanical flexibility, [26][27][28] weight, [29] and size. [30][31][32][33] Tunable PV can be defined as SC technologies that present a manipulation of inherent properties through material design of the functional components and retrofits or via device architecture engineering. The primary aim is to enable suitable customization and adaptation to the specific requirements of a given application.…”

Section: Introductionmentioning

confidence: 99%

Tunable Photovoltaics: Adapting Solar Cell Technologies to Versatile Applications

Meddeb

Götz‐Köhler

Neugebohrn

et al. 2022

Advanced Energy Materials

View full text Add to dashboard Cite

solar, wind, hydro, geothermal, and biomass, to enable a steady mitigation of greenhouse gas emissions, which are causing the planetary climate change and global warming. [5][6][7] Additionally, due to the economic development and the worldwide urbanization, a continuous rise of the global energy consumption across all key sectors, that is, power, heating, industry, and transport is occurring. This is expressed by an increase in the annual global electricity demand by 4.5% in 2021 corresponding to additional 1000 TWh. [4] Hence, strict criteria for the selection of competitive and abundant energy alternatives are imposed, requiring high yield at affordable prices. [8] The share of total renewables power generation excluding hydropower exceeded 3000 TWh in 2020, corresponding to almost 12% of the global electricity generation. [3] Considering an effective synergy between various sustainable energy candidates, solar photovoltaics (PV) have demonstrated great capabilities that can satisfy the requirements in the pathway towards 100% renewable electricity. [9][10][11][12] Owing to the research and development activities over the last decades, the power conversion efficiencies of solar cells (SC) have skyrocketed with a prolonged operation lifetime (>15 years) and a drastic plummeting in manufacturing costs (global average module selling price below $0.25 per W). [6,[13][14][15] The rapid universal deployment of PV resulted in a contribution of about 3.4% in the worldwide electricity generation in 2020. [3] Presently, the global installed PV capacity is approaching 1 TW and it is envisioned to reach ≈10 TW by 2030 and 30 to 70 TW by 2050. [16] Interestingly, along with massive electricity production using conventional solar power plants and rooftop solar panels, ancillary concepts of PV offer new strategies for supplying modern systems in versatile applications. [17][18][19] Moreover, diverse functionalities beyond solar energy harvesting can be afforded by adaptive PV, including aesthetic appearance, visual comfort and thermal management. [17,18,20,21] The distributed nature and the ubiquitous accessibility of multifunctional PV products are substantial features of solar PV in contrast to other renewable energies. However, traditional SCs dominating the market impose intrinsic optoelectronic and thermomechanical limitations, that prohibit their multifunctional utilization. To overcome these drawbacks, novel functional materials and innovative device architecture Solar photovoltaics (PV) offer viable and sustainable solutions to satisfy the growing energy demand and to meet the pressing climate targets. The deployment of conventional PV technologies is one of the major contributors of the ongoing energy transition in electricity power sector. However, the diversity of PV paradigms can open different opportunities for supplying modern systems in a wide range of terrestrial, marine, and aerospace applications. Such ubiquitous and versatile applications necessitate the development of PV technologies with customized desig...

show abstract

Section: Introductionmentioning

confidence: 99%

Tunable Photovoltaics: Adapting Solar Cell Technologies to Versatile Applications

Meddeb

Götz‐Köhler

Neugebohrn

et al. 2022

Advanced Energy Materials

View full text Add to dashboard Cite

show abstract

“…As hundreds of multijunction solar cells can be fabricated from a single wafer, each component must be electrically isolated from one to another, at the end of the fabrication cycle. This step is commonly referred as mesa isolation and it can be performed by saw-dicing [de Lafontaine et al (2021a); de Lafontaine et al (2016)], wet etching [Kim et al (2014); Raappana et al (2021); Bennett et al (2015); de Lafontaine et al (2021a); Malevskaya et al (2019); Turala et al (2013); Geisz et al (2020); Helmers et al (2011)] or plasma etching [Raappana et al (2021); Albert et al (2021); de Lafontaine et al (2021a); de Lafontaine et al (2016); Lafontaine et al (2019); de Lafontaine et al (2021b)]. Saw-dicing relies on physical abrasion, wet etching uses chemical reaction and plasma etching uses a combination of chemical reactions and ion-assisted sputtering to consume the target material.…”

Section: Introductionmentioning

confidence: 99%

“…The solar cell performance is affected by recombinations at the sidewalls of the cells (perimeter recombination) [de Lafontaine et al (2021a); Espinet-Gonzalez et al (2014); Belghachi and Khelifi (2006)]. Understanding these mechanisms is especially important considering the fact that the performance loss increases when the cell dimension is reduced towards the submillimetric range needed for micro-concentrator photovoltaics (Micro-CPV) [Espinet-Gonzalez et al (2014); Belghachi and Khelifi (2006); Albert et al (2021); Wiesenfarth et al (2020)]. One can expect the cell performance to depend on the sidewall fabrication method, herein, the mesa isolation etching.…”

Section: Introductionmentioning

confidence: 99%

“…Despite the improvement provided by plasma etching, the underlying mechanisms and the morphological characteristics of mesa isolation and their impact on III-V/Ge solar cell performance have yet to be investigated. Therefore, identifying the critical mesa isolation characteristics and the optimization pathways represent the keystone for the development of smaller (<200x200 µm 2 ) micro-multijunction solar cells for Micro-CPV applications [Albert et al (2021); Dominguez et al (2017); Wiesenfarth et al (2020)]. In this study, III-V/Ge triple junction solar cells were fabricated with the three different mesa isolation techniques and their open-circuit voltages were assessed under AM1.5D illumination.…”

Section: Introductionmentioning

confidence: 99%

“…The post-isolation wet clean enables to reduce even more the roughness down to a Sdr value below 1.5 %. Plasma etching offers an interesting pathway for multijunction solar cell miniaturization[Albert et al (2021)]. Despite the fact that this study is focussed on triple junction solar cells, all mesa isolation methods could be relevant for other III-V-based devices such as four, five or six junction solar cells, phototransducers and light-emitting diodes.6.…”

mentioning

confidence: 99%

See 2 more Smart Citations

Multijunction solar cell mesa isolation: Correlation between process, morphology and cell performance

Lafontaine

Ayari

Pargon

et al. 2022

Solar Energy Materials and Solar Cells

Self Cite

View full text Add to dashboard Cite

Fabrication of Crystalline Si Thin Films for Photovoltaics

Shen

Cabarrocas

et al. 2022

Physica Rapid Research Ltrs

View full text Add to dashboard Cite

Crystalline Si (c‐Si) thin films have been widely studied for their application to solar cells and flexible electronics. However, their application at large scale is limited by their fabrication process. As reviewed in this paper, many approaches have been studied, but only some of them have been made into large‐scale industrial production. The standard wire sawing of Si ingots cannot be scaled down to produce thin c‐Si wafers and films due to the brittle nature of c‐Si material, the resulting significant thickness variations, and the waste of material. Therefore, techniques based on the kerf‐less processes including “top‐down” and “bottom‐up” approaches have been developed in recent decades. In this review, photovoltaic applications of thin c‐Si wafers with thicknesses ranging from 50 μm down to 1 μm are presented first. Then, methods to fabricate c‐Si thin films based on both approaches are detailed, including slim‐cut, “smart‐cut,” epi‐free, as well as various growth processes such as molecular beam epitaxy, liquid phase epitaxy, ion beam, and chemical vapor deposition processes at a wide range of growth temperatures, from 1000 °C down to 150 °C. The advantages and disadvantages of these methods are presented and compared.

show abstract

Miniaturization of InGaP/InGaAs/Ge solar cells for micro‐concentrator photovoltaics

Cited by 19 publications

References 34 publications

Tunable Photovoltaics: Adapting Solar Cell Technologies to Versatile Applications

Tunable Photovoltaics: Adapting Solar Cell Technologies to Versatile Applications

Multijunction solar cell mesa isolation: Correlation between process, morphology and cell performance

Fabrication of Crystalline Si Thin Films for Photovoltaics

Contact Info

Product

Resources

About