HIGH-PERFORMANCE PEROVSKITE SOLAR CELLS BY ACTIVE LAYER COMPOSITION ENGINEERING

Shen, Lening

10 August 2021

No description available.

Chemical Engineering

Energy

Materials Science

Studies on Coating Process for Organic/Inorganic Thin-Films for Photovoltaics / 光電変換用有機/無機薄膜塗布プロセスに関する研究

Lee, Jae-Hyeong

24 March 2014

京都大学 / 0048 / 新制・課程博士 / 博士(エネルギー科学) / 甲第18381号 / エネ博第293号 / 新制||エネ||61(附属図書館) / 31239 / 京都大学大学院エネルギー科学研究科エネルギー基礎科学専攻 / (主査)教授 佐川 尚, 教授 八尾 健, 教授 萩原 理加 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DGAM

solar cell

spray coating

bulk heterojunction

donor/acceptor

polythiophene

thin-film

501

Synthèse d'oligomères et de polymères enrichis en porphyrines pour la conversion de l'énergie solaire / Synthesis of oligomers and polymers doped with porphyrins for solar energy conversion

Bucher, Léo

20 April 2017

Le projet de cette thèse consistait à élaborer de nouveaux matériaux donneurs d’électrons pour les cellules solaires organiques. Cette technologie photovoltaïque émergente en plein essor a d’ores et déjà atteint la limite d’efficacité lui permettant d’être industrialisée et commercialisée à grande échelle. Le faible coût de production des dispositifs photovoltaïques organiques les rendent compétitives vis-à-vis des technologies inorganiques déjà bien implantées. Mais leur plus gros avantage est surement leur légèreté et leurs propriétés mécaniques qui les rendent très souples. Elles devraient donc certainement avoir un rôle majeur à jouer dans le futur en complément des cellules solaires classiques, avec une utilisation pour des applications spécifiques. Nous avons ainsi développé des polymères en utilisant des chromophores réputés pour leurs propriétés photophysiques : les porphyrines, les BODIPY et les dicétopyrrolopyrroles. Ces différentes unités absorbent intensément la lumière, ce qui les rend adéquates pour être utilisées pour la conversion de l’énergie solaire en électricité. En concevant un design original et adapté à cette application, nous avons ainsi obtenu plusieurs nouveaux polymères prometteurs. Nous avons ensuite pu étudier leurs propriétés électrochimiques et électroniques, ainsi que leurs caractéristiques photophysiques. Pour cela nous avons utilisé de nombreux outils (caméra streak, absorption transitoire femtoseconde, etc.) afin de comprendre en détails leur propriétés d’absorption et de luminescence. Ces informations nous ont permis de pouvoir ensuite comprendre leur comportement une fois intégrés dans la couche active des dispositifs photovoltaïques. En effet, le mécanisme de fonctionnement pour la création d’un courant électrique met en jeu des transferts d’électrons ultrarapides (∼50 fs) vers un accepteur d’électron. Il est alors crucial de pouvoir comprendre et contrôler les paramètres pouvant influencer l’efficacité de ces transferts et la stabilisation des charges qui en résultent, pour pouvoir finalement mener à des rendements de conversion de l’énergie lumineuse élevés. / The aim of this thesis was to elaborate new electron donor materials for organic solarcells. This emerging photovoltaic technology is rapidly expanding, and has yet already reached the limit for its large-scale commercialization. The low manufacturing cost of organic photovoltaic devices make then competitive face to well-established inorganic technologies. Their biggest advantage is their weight and their mechanical properties which make them flexible. They should play a key role in future as a complement to classic solar cells, with their use in specific applications. We developed polymers by using different chomophores, well-known for their interesting photophysical properties: the porphyrin, the BODIPY and the diketopyrrolopyrrole. All these units intensively absorb the light, making them perfect candidates to be used to convert sunlight to electricity. By designing appropriate structures for this application, we synthesized several new promising polymers. Afterward, we studied their electrochemical and electronic properties, as well as their photophysics. We used powerful tools (streak camera, transient absorption, etc.) in order to understand in details their absorption and luminescence properties. These results enabled us to further understand their behavior once inside the active layer of photovoltaic devices. Indeed, the mechanism for the electric current creation involves ultrafast electron transfers (∼50 fs) toward electron acceptor. It is of utmost importance to understand and control parameters that could affect the electron transfer efficiency and the resulting charge stabilization, to finally lead to better power conversion efficiencies.

Cellules Solaires Organiques

Cellules à hétérojonction

Fluorescence

Photophysique

Polymères organiques

Organic solar cells

Bulk heterojunction

Fluorescence

Photophysics

Organic polymers

547

541.3

Novel poly(propylene thiophenoimine)-co poly(ethylenedioxythiophene) composites of naphthalene diimide for applications in organic photovoltaic cells

Yonkeu, Anne Lutgarde Djoumessi

January 2013

Magister Scientiae - MSc / Solar energy generation arises as a result of direct conversion of sunlight into electricity a by solar cell; which is mainly made up of a semiconducting material incorporated into a system. It is emerging as one of the most reliable and cost efficient renewable energy sources. Within the solar field, organic bulk heterojunction photovoltaic cells have proved of being able to have a great impact in the future years; mainly due to the easy processability of the active layer and substrate, their cost effectiveness and above all, a good power conversion efficiency associated to the close 3-dimensional interpenetrating network that is generated from blending donor and acceptor semiconducting materials together in a bulk heterojunction active layer. In this research work, we therefore report on the study of a newly developed organic bulk heterojunction active layer based on a blend of a star-copolymer generation 1 poly(propylenethiophenoimine)-co-poly(ethylenedioxythiophene) (G1PPT-co-PEDOT) as donor material with N,N-diisopropylnaphthalene diimide (NDI) as acceptor material. Both materials were chemically synthesized. The synthesis of G1PPT-co-PEDOT started first by the functionalization of generation 1 poly(propyleneimine) tetramine, G1PPI into G1PPT by condensation reaction in the presence of 2-thiophene carboxaldehyde under Nitrogen gas followed by the copolymerization of G1PPT with ethylene dioxythiophene (EDOT) monomer in the presence of ammonium persulfate, (NH4)2S2O8 as oxidant. On the other hand, NDI was also synthesized via condensation reaction of 1,4,5,8-naphthalene tetracarboxylic dianhydride in the presence of two (2) equivalences of N,N-diisopropylamine at 110 oC overnight in DMF. Both materials were characterized using FT-IR, UV-Vis spectroscopy, Fluorescence spectroscopy, Voltammetry, HRSEM microscopy and XRD. Based on the cyclic voltammetry and UV-Vis results, we were able to calculate the HOMO, LUMO and band gap energy (Eg) values of both the donor and acceptor to be -4.03 eV, -6.287 eV and 2.25 eV for iii the donor G1PPT-co-PEDOT respectively and -4.302 eV, -7.572 eV and 3.27 eV for the acceptor respectively. From these results, the energy diagram for both donor and acceptor was drawn and it comes out that the separation between the HOMO of the donor and the LUMO of the acceptor ΔEg = 1.985 eV, the ideal value for a good donor-acceptor combination. Also the offset energy that is, the energy difference between the LUMO of the donor and the LUMO of the acceptor is 0.302 eV.

Solar energy

Organic Photovoltaics

Bulk heterojunction cell

Star copolymer

G1PPT-co-PEDOT

Naphthalene diimide

HOMO

LUMO

Energy band gap, Eg

Design and Characterization of Electrospun Mats with Tailored Morphologies for Enhanced Active Layer Performance in Energy Conversion and Energy Storage Applications

Forbey, Scott

15 May 2014

The goal of this research was to utilize the morphological control inherently imparted by the electrospinning process to improve the active layer performance in energy conversion devices as well as to better understand the relationship between morphology and performance in energy storage devices. Discrete control of the active layer morphology can promote exciton dissociation in organic photovoltaic cells (OPVs), whereas developing efficient ion diffusion pathways and beneficial polymer-ion interaction in polymer-gel electrolytes is demonstrated to result in enhanced battery performance. We demonstrate the ability to develop unique morphologies in Poly(3-hexafluoro propylene) (P3HT) films with energy storage applications using various electrospinning techniques. Electrospinning in a solvent-saturated atmosphere allows for the design of ribbon architectures with polymer domains on the order of 5-10 um. These ribbon structures form what appear to be bi-continuous films, which could then be filled with an acceptor / fullerene type material to create a bulk heterojucton for OPV devices. Dropping chloroform onto the electrospinning needle during the spinning process results in P3HT fibers with porous surfaces. These fibers have diameters of ~ 2 um. Using a coaxial needle to electrospin a P3HT solution in the core, and a CHCl3 sheath solution created hybrid ribbon-fiber structures. These structures have even smaller domain sizes than the ribbons created using a solvent saturated atmosphere. Cospinning P3HT with sacrificial polymers results in P3HT fiber morphologies upon removal of the sacrificial template polymer. Additionally, introducing P3HT into an established fiber matrix results in fibrous P3HT architectures after the template fibers are removed. Developing hybrid polymer-gel electrolytes using crosslinked PEO electrospun fibers results in membranes with high affinity for liquid electrolyte components. These electrospun PEO fiber mats exhibit excellent ionic conductivities at room temperature (12 mS/cm) exceeding an electrospun PVDF control. Furthermore, the PEO fiber mats can absorb nearly three times as much liquid electrolyte as the PVDF control. PEO has been show to interact with lithium salts to aid in dissociation and diffusion during battery cycling. Although the ionic conductivity data suggest PEO to be a superior electrolyte, pulsed-field-gradient NMR shows that lithium diffusion is faster in PVDF samples. From coin cell discharge experiments, PEO is believed to interact strongly with Li+ ions, inhibiting them from diffusing rapidly during fast charge/discharge rates. However, PEO/PETA fiber electrolytes show nearly 100% theoretical capacity discharge at C/100 and a capacity retention of ~ 35% at a C/5 discharge rate in contrast to a glass fiber separator which shows only a capacity that is approximately 85% of the theoretical value. The unique mechanical properties of PEO/PETA electrospun mats could lead to interesting artificial skin and wound healing applications. Upon crosslinking at elevated temperatures (~40 degrees C), the fiber mats exhibit improved tensile strength and much higher ultimate stress at break. The porous nature of the materials lend to easy oxygen diffusion for wound healing, and the hydrophilicity promotes continued adhesion to existing tissue making these mats possible adhesive-less bandages. / Ph. D.

electrospinning

organic photovoltaic

bulk heterojunction

lithium polymer battery

ionic conductivity

photo initiator

cross linking

energy conversion

energy storage

Series interconnects and charge extraction interfaces for hybrid solar cells

Hey, Andrew Stuart

January 2013

This thesis investigates novel hole extraction interfaces and series interconnects for applications in organic photovoltaics, specifically in single junction solid-state dye-sensitized solar cells (DSSCs) and tandem DSSC/polymer bulk heterojunction solar cells. Improvements in hole extraction and device performance by using materials compatible with scalable deposition methods are presented, including tungsten- and molybdenum-disulphide (WS₂ and MoS₂), and p-type doped spiro-OMeTAD (2,2',7,7'-tetrakis-(N,N-di-p-methoxyphenylamine)9,9'-spirobifluorene) nanoparticle dispersions. WS₂ and MoS₂ hole extraction layers increase averaged short circuit currents by 20% and 16% respectively, and power conversion efficiencies by 19% and 14% respectively when compared with control devices. Similarly, doped spiro-OMeTAD nano-particle layers improved short circuit current densities by 32% and efficiencies by 9%. Tandem device interconnects using these novel hole extraction formats have been fabricated, but although devices did exhibit rectification, overall performance was poor. Possible reasons for their limited success have been analysed. Dye-sensitized solar mini-modules are also reported. In order to assure the scalability of DSSC technology, these larger area devices were constructed using doctor blade coating to deposit the hole transporter material. As well as achieving a respectable maximum power conversion efficiency of 2.6%, it has also been shown that the extent to which hole transporter infiltrates the mesoporous photoanode of these devices may be tuned by altering substrate temperature during deposition. It was found that an optimal coating temperature of 70 degrees C produced the best efficiency, with a corresponding pore-filling fraction of 41%.

621.31244

Diodos e dispositivos fotovoltaicos flexíveis / Diodes and flexibles photovoltaic devices

Souza Filho, Idomeneu Gomes de

11 June 2019

As aplicações dos dispositivos conversores de energia luminosa, principalmente da luz solar, em energia elétrica são muito variadas e com freqüência surge a possibilidade de uma nova aplicação. Muito tem sido discutido sobre aplicações de células solares em vestimentas, mochilas, tetos de estacionamentos e em embalagens eletrônicas. Esses tipos de aplicações não exigem dispositivos de alto desempenho, porém exigem que seja de baixo custo de processamento e, principalmente, que sejam flexíveis. Dispositivos fotovoltaicos flexíveis devem então ser fabricados por técnicas simples de processamento para permitir sua eventual produção em massa. Esse trabalho pretende dar uma contribuição na escolha dos materiais a serem usados em dispositivos fotovoltaicos flexíveis, focando seu desenvolvimento em células solares orgânicas de heterojunção de volume (BHJ), que são comumente processadas por solução. A estrutura escolhida foi a convencional de multicamadas onde o anodo transparente é o ITO (óxido de índio-estanho), seguida de uma camada transportadora de buracos (PEDOT:PSS), da camada ativa, e do cátodo, que em nosso caso foi formado por cálcio e alumínio, ambos depositados a vácuo. Como camada ativa, principal elemento de estudo nesse trabalho, foram estudados o P3HT:PC61BM, e o PTB7-Th:PC71BM, como elementos doador de elétrons (polímero) e aceitador de elétrons (derivado de fulereno). Em especial com o dispositivo fabricado com o PTB7-Th:PC71BM foi possível elaborar mudanças de processamento e assim melhorar consideravelmente a sua eficiência de conversão de potência. Em seguida, através de medidas de corrente-tensão (J-V) no escuro e sob iluminação, pudemos analisar a evolução dos parâmetros das células, como as resistências série (Rs) e paralelo (Rp), e também aqueles que definem a qualidade da célula solar: a corrente de curto-circuito (Jsc), a tensão de circuito aberto (Voc), o fator de preenchimento (FF), e a eficiência (η). Através dos ajustes das curvas J-V, no escuro e sob iluminação, usando expressões de J(V) extraídas de circuitos equivalentes, respectivamente, dos diodos e das células solares, pudemos realizar uma análise mais efetiva de como as resistências série e paralelo mudam com os elementos da camada ativa e também com diferentes processamentos. O fator de preenchimento (FF) é outro parâmetro importante que determina a eficiência de conversão de energia de uma célula solar orgânica, e existem vários fatores que podem influenciar significativamente o seu valor. Essa é uma das razões do porquê é difícil identificar a real origem desse parâmetro. Essa tese também deu elementos que correlacionam a estrutura química e morfológica da camada ativa com o fator de preenchimento. / The applications of light energy converters, especially the sunlight, in electrical energy are very varied and there is often the possibility of the appearance of new applications. Much has been discussed about solar cell applications in clothing, backpacks, parking ceilings and in electronic packaging. These types of applications do not require high-performance devices, but they do require low-cost processing and, above all, that they are flexible. Flexible photovoltaic devices must then be manufactured by simple processing techniques to allow their eventual mass production. This work intends to contribute to the choice of materials to be used in flexible photovoltaic devices, focusing their development on organic bulk heterojunction solar cells (BHJ), which are commonly processed via solution. The structure chosen for the device was the multilayer one, where the transparent anode is the ITO (indium- tin oxide), followed by a hole transport layer (PEDOT:PSS), the active layer, and the cathode, which in our case was formed by calcium and aluminum, both deposited under vacuum. As active layer, the main element of study in this work, we studied the P3HT: PC61BM and the PTB7-Th: PC71BM, as electron donor (polymer) and electron acceptor elements (derived from fullerene). In particular with the device made with the PTB7-Th:PC71BM it was possible to changes processing parameters and thus enhancing its power conversion efficiency. Then, through current-voltage measurements (J-V), in the dark and under illumination, we were able to analyze the evolution of the cell parameters, such as the series (Rs) and shunt (Rp) resistances, as well as those that define the solar cell quality: short-circuit current (Jsc), open-circuit voltage (Voc), fill factor (FF), and efficiency (η). Through the adjustments of the J-V curves, in the dark and under illumination, using J(V) expressions, for equivalent circuits of the diodes and solar cells respectively, we were able to perform a more effective analysis of how the series and shunt resistances change with the elements of the active layer and also with its processing. Fill factor (FF) is another important parameter that determines the energy conversion efficiency of an organic solar cell, and there are several factors that can significantly influence its value. This is one of the reasons why it is difficult to identify the true source of this parameter. This thesis also gave elements that correlate the chemical and morphological structure of the active layer with the fill factor.

Active layer

Camada ativa

P3HT:PC61BM

P3HT:PC61BM

PEDOT:PSS

PEDOT:PSS

PTB7-Th:PC71BM

PTB7-Th:PC71BM

Ultrafast spectroscopy of organic semiconductors : singlet fission and nonfullerene acceptors for organic photovoltaics

Kim, Vincent Oteyi

January 2019

In this dissertation, we investigate two emerging strategies for enhancing the performance of organic photovoltaics. The first takes advantage of a process called singlet exciton fission, and the second embodies an exodus from the fullerene electron acceptors prominent in organic solar cells. Indeed, this versatile class of tunable small molecules are aptly termed nonfullerene acceptors. However, both strategies would benefit from a greater understanding of underlying principles. Singlet exciton fission is a photon-multiplying process in which a singlet exciton from a high-energy absorbed photon splits into two triplet excitons. The process could significantly reduce energy lost to heat in photovoltaic devices, but its mechanisms are still misunderstood. One model involves direct coupling between the singlet and triplet states, and another model involves an intermediate charge transfer state. Transient absorption spectroscopy allowed us to examine singlet fission in films of pentacene, fluorinated pentacene, and coevaporated blends of various mixing ratios. We directly observe an intermolecular charge transfer state during singlet fission in solid films of coevaporated pentacene and peruoropentacene, which supports the model of charge transfer state-mediated singlet fission. Furthermore, we successfully induced singlet fission in one blend by directly exciting the charge transfer state below the bandgap. We use various types of steady state and time-resolved spectroscopy to characterize two types of nonfullerene electron acceptors. The first type is a group of tetraazabenzodiuoranthene diimide (BFI) dimers and a BFI monomer. The BFI dimers were designed to have twisted, nonplanar 3-dimensional structures and have helped achieve power conversion efficiencies of over 8% in organic solar cells. The other type of nonfullerene acceptor is a calamitic small molecule, and we consider the BAF-4CN electron acceptor, which has also been used in a solar cell whose efficiency exceeded 8%. Spectroscopic studies give insight into the performances of these nonfullerene devices in relation to fullerene-derivative counterparts. We find that the nonfullerene blends suffer from more geminate charge recombination. However, despite this drawback, in some cases, slower rates of nongeminate recombination may lead to successful power conversion efficiencies in nonfullerene solar cells.

Materials aspects in spin-coated films for polymer photovoltaics

Anselmo, Ana Sofia

January 2013

Polymer-based photovoltaics have the potential to contribute to boosting photovoltaic energy conversion overall. Besides allowing large-area inexpensive processing, polymeric materials have the added benefit of opening new market applications for photovoltaics due to their low-weight and interesting mechanical properties. The energy conversion efficiency values of polymer photovoltaics have reached new record values over the past years. It is however crucial that stability issues are addressed together with efficiency optimization. Understanding fundamental materials aspects is key in both areas. In the work presented in this thesis, the morphology of polymer:fullerene films and its influence on device performance was studied, as well as the effect of light exposure on the surface of fullerene films. Several polyfluorene copolymers were used for the morphology studies, where the effects of changing spin-coating solvent and of side chain engineering were investigated with dynamic secondary ion mass spectrometry (dSIMS) and near-edge X-ray absorption fine structure (NEXAFS) spectroscopy. Polymer-enriched surfaces were found in all blend films, even in the cases with homogeneous distributions in the bulk. Side chain engineering of the polymer led to gradual changes in the compositional variations perpendicular to the surface, and to slight variations in the photocurrent. The electronic structure of the fullerene derivative PCBM was studied in detail and the spectroscopic fingerprint of the materials was analysed by comparison with theoretically simulated spectra. Photo-stability studies done in air showed that the surface of fullerene films underwent severe damages at the molecular level, which is evident from changes in the valence band and X-ray absorption spectra. These changes were explained by transitions from sp2-type to sp3 hybridization of the carbon atoms in the cage that resulted in the destruction of the fullerene cage.

materials science

photovoltaics

conjugated polymer

polymer solar cell

bulk heterojunction

coating

morphology

fullerene

photostability

degradation

X-ray absorption spectroscopy

synchroton-based techniques

Studies of Charge Transport and Energy Level in Solar Cells Based on Polymer/Fullerene Bulk Heterojunction

Gadisa, Abay

January 2006

π-Conjugated polymers have attracted considerable attention since they are potential candidates for various opto-electronic devices such as solar cells, light emitting iodes, photodiodes, and transistors. Electronic de vices based on conjugated polymers can be easily processed at low temperature using inexpensive technologies. This leads to cost reduction, a key-deriving factor for choosing conjugated polymers for various types of applications. In particular, polymer based solar cells are of special interest due to the fact that they can play a major role in generating clean and cheap energy in the future. The investigations described in thesis are aimed mainly at understanding charge transport and the role of energy le vels in solar cells based on polymer/acceptor bulk heterojunction (BHJ) active films. Best polymer based solar cells, with efficiency 4 to 5%, rely on polymer/fullerene BHJ active films. These solar cells are in an immature state to be used for energy conversion purposes. In order to enhance their performance, it is quite important to understand the efficiency-limiting factors. Solid films of conjugated polymers compose conjugation segments that are randomly distributed in space and energy. Such distributio n gives rise to the localization of charge carriers and hence broadening of electron density of states. Consequently, electronic wave functions have quite poor overlap resulting into absence of continuous band transport. Charge transport in polymers and organic materials, in general, takes place by hopping among the localized states. This makes a bottleneck to the performance of polymer-based solar cells. In this context, the knowledge of charge transport in the solar cell materials is quite important to develop materials and device architectures that boost the efficiency of such solar cells. Most of the transport studies are based on polyfluorene copolymers and fullerene electron acceptor molecules. Fullerenes are blended with polymers to enhance the dissociation of excited state into free carriers and transport free electrons to the respective electrode. The interaction within the polymer-fullerene complex, therefore, plays a major role in the generation and transport of both electrons and holes. In this thesis, we present and discuss the effect of various polymer/fullerene compositions on hole percolation paths. We mainly focus on hole transport since its mobility is quite small as compared to electron mobility in the fullerenes, leading to creation of spa ce charges within the bulk of the solar cell composite. Changing a polymer band gap may necessitate an appropriate acceptor type in order to fulfill the need for sufficient driving force for dissociation of photogenerated electron-hole pairs. We have observed that different acceptor types give rise to completely different hole mobility in BHJ films. The change of hole transport as a function of acceptor type and concentration is mainly attributed to morphological changes. The effect of the acceptors in connection to hole transport is also discussed. The later is supported by studies of bipolar transport in pure electron acceptor layers. Moreover, the link between charge carrier mobility and photovoltaic parameters has also been studied and presented in this thesis. The efficiency of polymer/fullerene-based solar cells is also significantly limited by its open-circuit voltage (Voc), a parameter that does not obey the metal-insulator-metal principle due to its complicated characteristics. In this thesis, we address the effect of varying polymer oxidation potential on Voc of the polymer/fullerene BHJ based solar cells. Systematic investigations have been performed on solar cells that comprise several polythiophene polymers blended with a fullerene derivative electron acceptor molecule. The Voc of such solar cells was found to have a strong correlation with the oxidation potential of the polymers. The upper limit to Voc of the aforementioned solar cells is thermodynamically limited by the net internal electric filed generated by the difference in energy levels of the two materials in the blend. The cost of polymer-based solar cells can be reduced to a great extent through realization of all-plastic and flexible solar cells. This demands the replacement of the metallic components (electrodes) by highly conducting polymer films. While hole conductor polymers are available, low work function polymer electron conductors are rare. In this thesis, prototype solar cells that utilizes a highly conducting polymer, which has a work function of ~ 4.3 eV, as a cathode are demonstrated. Development of this material may eventually lead to fabrication of large area, flexible and cheap solar cells. The transparent nature of the polymer cathode may also facilitate fabrication of multi-layer and tandem solar cells. In the last chapter of this thesis, we demonstrate generation of red and near infrared polarized light by employing thermally converted thin films of polyfluorene copolymers in light emitting diodes. This study, in particular, aims at fabricating polarized infrared light emitting devices. / On the day of the defence day the status of article III was In press and article VI was Manuscript.

Bulk heterojunction

Charge transport

Space charge limited

Bipolar transport

Origin of open circuit voltage

Polymer-fullerene blend

Soft contact lamination

Polarized infrared emission

Physics

Fysik