Optoelectronics Reports https://ojs.acad-pub.com/index.php/OER <p><em>Optoelectronics Reports</em> (OER) is a strictly peer-reviewed open-access journal. It accepts original academic submissions with unique innovation and novel research ideas in the field of optoelectronics. <em>Optoelectronics Reports</em> (OER) is committed to providing a forum for global researchers to promote the development of optoelectronics technology. Original research articles, reviews, and case reports are very welcomed.</p> <p>Topics include but are not limited:</p> <ul> <li class="show">Organic Semiconductors;</li> <li class="show">Organic Photonics</li> <li class="show">Organic Optoelectronic Materials and Devices.</li> </ul> en-US <p>Authors contributing to this journal agree to publish their articles under the <a href="http://creativecommons.org/licenses/by-nc/4.0" target="_blank">Creative Commons Attribution-Noncommercial 4.0 International License</a>, allowing third parties to share their work (copy, distribute, transmit) and to adapt it, under the condition that the authors are given credit, that the work is not used for commercial purposes, and that in the event of reuse or distribution, the terms of this license are made clear. With this license, the authors hold the copyright without restrictions and are allowed to retain publishing rights without restrictions as long as this journal is the original publisher of the articles.</p><p><img src="/public/site/by-nc.png" alt="" height="30px" /></p> editorial-oer@acad-pub.com (Managing Editor) admin@acad-pub.com (IT Support) Tue, 09 Jan 2024 13:56:16 +0000 OJS 3.1.2.4 http://blogs.law.harvard.edu/tech/rss 60 Exploring the efficiency and transparency in toxic and non-toxic perovskite solar cells by using SCAPS-1D https://ojs.acad-pub.com/index.php/OER/article/view/283 <p align="justify">In the quest for sustainable energy solutions, we undertook a rigorous examination of both toxic and non-toxic perovskite solar cells (PSCs), assessing their potential across different absorber thicknesses and their viability within Building-Integrated Photovoltaics (BIPV). Our MAPbI<sub>3</sub>-based solar cell, utilizing TiO<sub>2</sub> and Cu<sub>2</sub>O as electron and hole transport layers, respectively, exhibited an efficiency of 20.65% with a 400 nm opaque absorber. Interestingly, when this thickness was reduced to 200 nm, endowing the PSC with semitransparent properties, certain performance metrics altered, revealing insights crucial for BIPV integration. Further experiments with the toxic FAPbI<sub>3</sub> absorber resulted in an efficiency of 23.37% for its 400 nm opaque variant. However, the semitransparent 200 nm layer presented distinct characteristics, emphasizing the complex interplay between thickness, transparency, and efficiency. Our exploration did not stop at toxic materials; we delved into non-toxic alternatives, MAGeI<sub>3</sub> and RbGeI<sub>3</sub>. These variants produced efficiencies of 14.59% and 20.40% for their 400 nm configurations. Yet again, their 200 nm semitransparent counterparts showcased performance nuances. Synthesizing our findings, it becomes evident that semitransparent PSCs hold significant promise for BIPV applications, but achieving an optimal blend of efficiency, transparency, and architectural appeal demands further focused research.</p> Abdul Haseeb Hassan Khan, Hameed Ullah, Liping Li, Abdul Basit, Khadija Boughanbour, Sumayya Khan, Aimal Daud Khan Copyright (c) 2024 Abdul Haseeb Hassan Khan, Hameed Ullah, Liping Li, Abdul Basit, Khadija Boughanbour, Sumayya Khan, Aimal Daud Khan https://creativecommons.org/licenses/by-nc/4.0 https://ojs.acad-pub.com/index.php/OER/article/view/283 Tue, 09 Jan 2024 00:00:00 +0000 Photovoltaic sensibility of optical biosensor produced by flexible and stretchable rubber utilized physical paradigm of solar cell https://ojs.acad-pub.com/index.php/OER/article/view/354 <p>It is expected that the physical paradigm of solar cells will be possible to fabricate optical biosensors that mimic the human eye, including flexibility and stretchability. The purpose of this article is to demonstrate the morphological fabrication of an optical biosensor made of rubber by utilizing the physical paradigm of solar cells involving electric and chemical processes. However, a critical problem of current solar cells is their use of pieces of solid transparent conductive glass as electrodes, as especially shown in organic thin-film type solar cells involving dye-synthesized and perovskite-type solar cells. Therefore, we must solve this problem in order to be able to develop flexible and stretchable solar cells for optical biosensors. The key point of the solution is to avoid using rigid conductive glass and to coat a flexible and stretchable material such as rubber with TiO<sub>2</sub>. In the present study, we proposed a novel fabrication technique for a flexible and stretchable rubber coated with TiO<sub>2</sub> by electrolytic polymerization utilizing our developed magnetic responsive intelligent fluid, hybrid fluid (HF), in order to produce the optical biosensor. The photovoltaic results experimentally demonstrated the photovoltage response to illumination with around 3–60 mV enhancement. In addition, we elucidated the photovoltaic mechanism by using electrochemical measurement involving the cyclic voltammetry (CV) profile and electrochemical impedance spectroscopy (EIS), introducing the equivalent electric circuit's intrinsic structure. The results demonstrated that the rubber type behaves dominantly in the area outside the electrical double layer (EDL) under illumination, and then the response time of photovoltage to illumination is slow with non-linear CV profiles. On the other hand, the optical biosensor type behaves dominantly in the EDL under illumination, and then the response time is fast with linear CV profiles, which denotes that the optical biosensor type is optimal for photodiodes. Furthermore, these results can demonstrate the chemical-photovoltaic reaction of the HF rubber involving TiO<sub>2</sub>. The investigation might present the viability of the fabrication of ophthalmological systems that mimic the human eye.</p> Kunio Shimada Copyright (c) 2024 Kunio Shimada https://creativecommons.org/licenses/by/4.0 https://ojs.acad-pub.com/index.php/OER/article/view/354 Mon, 05 Feb 2024 09:24:32 +0000