New Strategies for High Efficiency Perovskite Single Crystal Solar Cells and Stable Luminescent Inorganic Materials

Turedi, Bekir

08 June 2021

Metal halide perovskite semiconductors offers bright future for optoelectronic applications due to their excellent optical and electrical properties and their low-cost solution-based facile fabrication. The most of the perovskite application are based on the defective polycrystalline films and they offer inadequate moisture/thermal chemical stability. Therefore, this dissertation is dedicated to find new strategies to deploy the single-crystal perovskites to photovoltaics and new methods to reduce the moisture/thermal instability of inorganic perovskite light-emitters. In first part of this dissertation, we aimed to reveal the potential of the single crystal in photovoltaics. Single-crystal semiconductors can outperforms their polycrystalline forms in terms of photovoltaic performance due to their better structural quality and less electronic traps. However, the most efficient perovskite solar cells are based on polycrystalline films. While single crystals can perform beyond the limits of polycrystalline films, their synthesis and device integration are complex. Therefore, we aimed to create new synthetic methods to unveil the potential of the single-crystal perovskites in photovoltaics. We developed new strategies leading the perovskite single crystals to go beyond 20% power conversion efficiency in Chapter 2. Also fundamental limits of the perovskite single crystals are investigated in Chapter 3 by fabricating single crystal cells with varying thicknesses, and the electron diffusion length is calculated to be 520 μm. In Chapter 4, we propose surface modification and compositional engineering techniques to bring the perovskite single crystal photovoltaic one step beyond of the previous point by reaching 21.9% and 22.8% efficiencies, respectively. In the second part of this dissertation (Chapter 5), a novel synthetic method is offered to achieve highly stable light-emitting perovskite-related materials since the fast degradation of perovskites in the presence of water and moisture is a challenge for perovskite-based technologies and hinders the material’s potential. We demonstrated that these a direct transformation of 3D CsPbBr3 films to CsPb2Br5 exhibiting excellent stability against humidity and heat while keeping the high photoluminescence quantum yield. We believe the strategies offered in this dissertation will open an avenue in photovoltaic and light emitting applications, and can be utilized in new optoelectronic applications in future.

perovskite

single crystal

solar cell

photovoltaics

light emitting

stable

Studies of sputtered CdTe and CdSe solar cells

Kwon, Dohyoung

January 2012

No description available.

Physics

CdTe

CdSe

solar cell

photovoltaic

AFM

scaling

PL

photoluminescence

Barium Oxide as an Intermediate Layer for Polymer Tandem Solar Cell

Li, Zhehui

07 June 2013

No description available.

Chemistry

polymer tandem solar cell

barium oxide

intermediate layer

Simulations of Organic Solar Cells with an Event-Driven Monte Carlo Algorithm

Robbiano, Vincent P.

15 August 2011

No description available.

Alternative Energy

Physics

Solar Cell

Monte Carlo

event driven

Organic

Enhancement of Light Absorption Efficiency of Solar Cell Using Dual

Ellaboudy, Ashton

01 December 2011

In this research we study the effect of adding a single diffraction grating on top of a solar cell. We simulated the square diffraction grating, as well as triangular diffraction grating. The single square grating showed more favorable results, achieved 330% power improvement compared to 270% power improvement in the single triangular grating case. We simulated a triangle/triangle (top-bottom) and triangular/rectangular (top-bottom) grating cases. The Triangular grating achieved higher light absorption compared to rectangular grating. The best top grating was around 200nm grating period. We realized solar cell efficiency improvement about 42.4% for the triangular rectangular (top-bottom) grating. We studied the light transmitted power in a silicon solar cell using double diffraction triangular nano-grating. We simulated the solar cell behavior as it absorbs sunlight through its structure in various cases, results showed 270% increase of the weighted transmitted power when the top grating period (At) varies from 300nm to 800nm, and the bottom grating period (Ab) is at 500nm. We finally studied the effect of changing the location of the diffraction gratings with respect to the solar cell. We were able to increase the light efficiency by 120%. The study showed that the power absorbed by the solar cell is not sensitive to the grating location.

photonic

solar cell

diffraction grating

Electrical and Computer Engineering

Solar Cell Production Facility

Kukulka, Jerry

January 1979

<p> A technology to produce low cost solar cells was transferred to a microelectronics institution. Appropriate processing equipment was obtained and modifications to the procedure were performed which would permit the manufacture of 100-200, 3 inch diameter silicon solar cells per day. </p> / Thesis / Master of Engineering (ME)

solar

cell

silicon solar cells

microelectronics

solar cell production

Fabrication of All-Inorganic Optoelectronic Devices Using Matrix Encapsulation of Nanocrystal Arrays

Kinder, Erich W.

26 July 2012

No description available.

Chemistry

Physics

Nanocrystal

Solar Cell

SMENA

Semiconductor

Photovoltaic

Depleted Heterojunction

ELECTROCHEMICAL FABRICATION OF THIN FILM PHOTOVOLTAIC DEVICES (CIGS & CIGSS)

Saeed, Mahfouz Ali

12 June 2014

No description available.

Chemical Engineering

Design and Synthesis of Organic Dyes for Solar Energy Conversion and Storage

Click, Kevin A.

01 September 2017

No description available.

Chemistry

solar cell technologies

Dye sensitized solar cells

Applications of Multichannel Spectroscopic Ellipsometry for CdTe Photovoltaics: From Window Layers to Back Contacts

Tan, Xinxuan

January 2017

No description available.

Physics

Ellipsometry

CdSO

CdTe solar cell

novel back contacts