Relevant bibliographies by topics / Light absorbing materials

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  1. Journal articles
  2. Dissertations / Theses
  3. Books
  4. Book chapters
  5. Conference papers

Academic literature on the topic 'Light absorbing materials'

Author: Grafiati
Published: 4 June 2021
Last updated: 1 February 2022

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Journal articles on the topic "Light absorbing materials"

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Yu, Zhang. "Research on Absorbing Properties of New Porous Metals Materials with Light Weight." Key Engineering Materials 815 (August 2019): 42–47. http://dx.doi.org/10.4028/www.scientific.net/kem.815.42.

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The development of electronic science technology makes electromag-netic radiation problems increasingly severe. High-performance absorbing and shielding electromagnetic wave materials with light weight are researched and developed as one of effectiveness methods to restrain electromagnetic radiation and prevent information leakage. The absorbing properties of aluminium foams coating absorbing paint were studied and tested by making use of RCS in “the reflectivity testing measurement of radar absorbing material” of GJB 2038-94 in this work. The effect of absorbent species and metal base structu
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XIE, Wei, Hai-Feng CHENG, Zeng-Yong CHU, Zhao-Hui CHEN, and Yong-Jiang ZHOU. "Radar Absorbing Properties of Light Radar Absorbing Materials Based on Hollow-porous Carbon Fibers." Journal of Inorganic Materials 24, no. 2 (2009): 320–24. http://dx.doi.org/10.3724/sp.j.1077.2009.00320.

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Niu, Chunhui, Ting Zhu, and Yong Lv. "Influence of Surface Morphology on Absorptivity of Light-Absorbing Materials." International Journal of Photoenergy 2019 (September 8, 2019): 1–9. http://dx.doi.org/10.1155/2019/1476217.

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Absorptivity of three kinds of surface morphology, i.e., V-type groove surface, sinusoidal surface, and random distribution, is investigated using a rigorous electromagnetic theory and a finite element method. Influences of surface contour parameters (span distance, intersection angle, and height) and light wave parameters (incident angle and wavelength) on absorptivity are numerically simulated and analyzed for the three kinds of surfaces, respectively. Absorbing spectra about three silicon wafers with different surface roughness are recorded, and the results are coincident with simulated res
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Grinberg, Ilya, D. Vincent West, Maria Torres, et al. "Perovskite oxides for visible-light-absorbing ferroelectric and photovoltaic materials." Nature 503, no. 7477 (2013): 509–12. http://dx.doi.org/10.1038/nature12622.

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Kulbek, М. К., and E. Dzhaksigeldinova. "STUDY OF WATER-ABSORBING PROPERTIES OF LIGHT POROUS SOLID MATERIALS." BULLETIN Series of Physics & Mathematical Sciences 71, no. 3 (2020): 128–32. http://dx.doi.org/10.51889/2020-3.1728-7901.18.

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Various porous solid materials are widely used in engineering, technology, and various industries; therefore, the study of their physical properties is of great scientific and practical importance. The article describes the methods for determining and the results of experimental work on the study of water-absorbing properties of light porous materials. Light porous materials, the density of which is less than water, are considered as objects of research. Mathematical design conditions for the application of a new experimental method for studying such light porous materials are presented. Speci
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van Olfen, U. "Light-induced transparency in absorbing powders." physica status solidi (a) 121, no. 1 (1990): K121—K124. http://dx.doi.org/10.1002/pssa.2211210168.

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Goswami, Subhadip, Seda Cekli, Erkki Alarousu, et al. "Light-Harvesting Two-Photon-Absorbing Polymers." Macromolecules 53, no. 15 (2020): 6279–87. http://dx.doi.org/10.1021/acs.macromol.0c01035.

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Saleema, N., M. Farzaneh та R. W. Paynter. "Fabrication of light absorbing TiO2 μ-donuts". Materials Letters 63, № 2 (2009): 233–35. http://dx.doi.org/10.1016/j.matlet.2008.09.062.

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Wang, Yun Ming, Bing Tao Tang, and Shu Fen Zhang. "Ultraviolet-Visible Light-Thermal Conversion Organic Solid-Liquid Phase-Change Materials." Advanced Materials Research 679 (April 2013): 29–34. http://dx.doi.org/10.4028/www.scientific.net/amr.679.29.

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UV-vis light-driven organic solid-liquid phase change materials exhibited excellent performances of UV-vis light-harvesting, UV-vis light-thermal conversion and thermal energy storage, which is promoted by UV absorbing dye as an effective ‘‘photon capture and molecular heater’’ for direct and efficient use of solar radiation.
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Horri, Bahman, Chong Nan, Xiao Chen, and Huanting Wang. "Modelling of Solar Evaporation Assisted by Floating Light-Absorbing Porous Materials." Current Environmental Engineering 1, no. 2 (2014): 73–81. http://dx.doi.org/10.2174/2212717801666141021001740.

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Dissertations / Theses on the topic "Light absorbing materials"

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Anderson, Michele Lynn 1968. "Characterization of organic/organic' and organic/inorganic heterojunctions and their light-absorbing and light-emitting properties." Diss., The University of Arizona, 1997. http://hdl.handle.net/10150/282555.

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Increasing the efficiency and durability of organic light-emitting diodes (OLEDs) has attracted attention recently due to their prospective wide-spread use as flat-panel displays. The performance and efficiency of OLEDs is understood to be critically dependent on the quality of the device heterojunctions, and on matching the ionization potentials (IP) and the electron affinities (EA) of the luminescent material (LM) with those of the hole (HTA) and electron (ETA) transport agents, respectively. The color and bandwidth of OLED emission color is thought to reflect the packing of the molecules in
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Fast, Jonatan. "Investigation of Bismuth Iodine as Light Absorbing Materials for Solar Cell Applications: From Synthesis to XPS Characterisation." Thesis, Uppsala universitet, Molekyl- och kondenserade materiens fysik, 2017. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-331340.

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During the last years perovskite materials have taken the photovoltaic community by storm, bringing promises of solar cells with efficiencies comparable to conventional silicon devices but at a lower price. However perovskite solar cells so far are facing two main obstacles, they are unstable in the presence of air, moisture and heat and they are usually toxic due to being based on lead-halide materials. This has spurred investigations into alternative materials with similar properties but without the mentioned drawbacks. Just next to Pb in the periodic table is bismuth (Bi) with just one more
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Ghanavi, Saman. "Organic-inorganic hybrid perovskites as light absorbing/hole conducting material in solar cells." Thesis, Uppsala universitet, Fysikalisk kemi, 2013. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-205605.

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Solar cells involving two different perovskites were manufactured and analyzed. The perovskites were (CH3NH3)PbI3 and (CH3NH3)SnI3. Both perovskites have a shared methyl ammonium group (MA) and are used as both light absorbing material and hole conducting material (HTM) in this project. The preparation procedures for the complete device were according to previous attempts to make stable organic-inorganic hybrid perovskites and involved different layers and procedures. Both perovskites were manufactured by mixing methyl ammonium iodide with either lead iodide or tin iodide in different concentr
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"Nanoscale Heterogeneities in Visible Light Absorbing Photocatalysts: Connecting Structure to Functionality Through Electron Microscopy and Spectroscopy." Doctoral diss., 2019. http://hdl.handle.net/2286/R.I.55547.

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abstract: Photocatalytic water splitting over suspended nanoparticles represents a potential solution for achieving CO2-neutral energy generation and storage. To design efficient photocatalysts, a fundamental understanding of the material’s structure, electronic properties, defects, and how these are controlled via synthesis is essential. Both bulk and nanoscale materials characterization, in addition to various performance metrics, can be combined to elucidate functionality at multiple length scales. In this work, two promising visible light harvesting systems are studied in detail: Pt-functi
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Books on the topic "Light absorbing materials"

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Martin, Ronald. Tacitus: Annals V and VI. Liverpool University Press, 2001. http://dx.doi.org/10.3828/liverpool/9780856687211.001.0001.

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Books V and VI of Tacitus' Annals, when complete, carried the narrative of Tiberius' reign from AD 29 to 37. Unfortunately, most of Book V has been lost, and, with it, Tacitus' account of the sensational events that led to the execution on 18 October in AD 31 of Aelius Sejanus. Nevertheless, Annals VI contains a fascinating variety of incidents both at Rome and on Capri, to which Tiberius had retired permanently in AD 27. But, in addition to all the material that portrays Tiberius in a highly unfavourable light, there is much in Annals VI that shows a very different side to his character. Wher
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Book chapters on the topic "Light absorbing materials"

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Castelli, Ivano E., Korina Kuhar, Mohnish Pandey, and Karsten W. Jacobsen. "Chapter 3. Computational Screening of Light-absorbing Materials for Photoelectrochemical Water Splitting." In Advances in Photoelectrochemical Water Splitting. Royal Society of Chemistry, 2018. http://dx.doi.org/10.1039/9781782629863-00062.

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Wang, Meng, Qunliang Song, and Sam Zhang. "2D Organic-Inorganic Hybrid Perovskite Light-Absorbing Layer in Solar Cells." In Solar Cells [Working Title]. IntechOpen, 2020. http://dx.doi.org/10.5772/intechopen.93725.

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With the rapid development of high-performance perovskite solar cell, its instability has become an urgent problem to be solved. 2D perovskite is considered as a potential light absorbing material for perovskite solar cells due to its excellent stability. However, the preparation of high quality 2D perovskite films suitable for photovoltaic devices remains a challenge. In this chapter, based on the structural and photophysical properties of 2D perovskite thin film materials, the latest progress in 2D perovskite cells in recent years and the strategy of controlling the film quality of 2D perovskite are summarized, which is of great significance for the further development of 2D perovskite photovoltaic devices.
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Zuk, Patrick. "Prokofiev and the Development of Soviet Composition in the 1920s and 1930s." In Rethinking Prokofiev. Oxford University Press, 2020. http://dx.doi.org/10.1093/oso/9780190670764.003.0004.

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Chapter 2 examines the influence and reception history of Prokofiev’s music in his homeland from the 1920s until his death in 1953—a subject of absorbing interest for the light it sheds on the factors shaping Soviet musical creativity during the Stalinist period. His output became central to discussions of the ways in which Soviet composition could and should develop. However, Soviet responses to Prokofiev’s work were complex; it was regarded by some as evincing traits that were to be repudiated, and by others as displaying approaches worthy of emulation. The source materials consulted for this chapter include the contemporary musicological and periodical literature, as well as letters, diaries, and reminiscences of Prokofiev’s colleagues. The chapter also draws on unpublished archival documents from the late Soviet period, among them the reminiscences of Evgeny Golubev, Olga Lamm, and Iulian Krein.
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Kishino, Motoaki. "Interrelationships between Light and Phytoplankton in the Sea." In Ocean Optics. Oxford University Press, 1994. http://dx.doi.org/10.1093/oso/9780195068436.003.0008.

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Light energy penetrating the sea is diminished almost exponentially with depth with an accompanying drastic change in the energy spectrum as the result of absorption by various components in the seawater. Such a change in the light environment will affect phytoplankton life directly. Accordingly, in the study of light in the sea, much attention has been drawn toward the contribution of phytoplankton to the light field and also how much energy or which parts of the light spectrum are utilized at various depths by phytoplankton. Spectral distribution of underwater irradiance is determined by the processes of absorption and scattering from various components of the seawater. Since absorption plays a much more important role in spectral variation than scattering (Preisendorfer, 1961), the spectral absorption of each component should be studied in order to adequately interpret the variation of spectral irradiance in the sea. The materials absorbing light are phytoplankton, other particles, dissolved organic substances, and the water itself. Spectral characteristics of the light environment in the sea are determined by the variable ratios of these components. Several authors have attempted to measure directly the spectral absorption of individual components in seawater (Kirk, 1980; Okami et al., 1982; Kishino et al., 1984; Carder and Steward, 1985; Weidemann and Bannister, 1986). However, the determination of the absorption coefficient of natural phytoplankton is quite difficult, because no suitable technique is available for the direct measurement of absorption. Accordingly, there is still considerable uncertainty about light absorption by phytoplankton under natural conditions. Phytoplankton photosynthetic efficiency is important for the algae as well as the other organisms in the same ecosystem. Photosynthetic efficiency can be estimated fundamentally from quantum yield, which is obtained by measuring three parameters: photosynthetic rate, spectral downward irradiance, and the spectral absorption coefficient of phytoplankton. The optical system of a recently designed spectral irradiance meter is shown in Fig. 4-1. The meter has two independent cosine collectors that receive downward and upward spectral irradiance, respectively, by rotation of the mirror placed behind the collectors. After collimation, light reflected by the mirror is separated by a beam splitter.
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"Absorber Materials for Solar Cells." In Materials for Solar Cell Technologies I. Materials Research Forum LLC, 2021. http://dx.doi.org/10.21741/9781644901090-8.

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Solar cell production has grown rapidly in the last few decades. Essentially a solar cell (SC), known as a photovoltaic (PV) cell, is nothing more than a p-n junction, composed of a p-type and n-type semiconductor. The electric field is generated at the junction when electrons and holes pass towards the positive and negative terminals respectively. Light consists of photons, and when the light of a sufficient wavelength falls on the cells, the energy from the photon is passed to the valence band electrons, allowing electrons to move to a higher energy state called the conductive band. The entire process is carried out in the absorber layer that lies under the anti-reflective coating of the SC. Since most energy in sunlight and artificial light is within the visible range of electromagnetic radiation (EMR), a SC absorber can absorb radiation effectively at these wavelengths. Because a SC can be made using a variety of materials, its output depends solely on the properties of the material used. This chapter discusses different absorbent materials that are used for solar cells.
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Thomas, Edmund. "Introduction." In Monumentality and the Roman Empire. Oxford University Press, 2007. http://dx.doi.org/10.1093/oso/9780199288632.003.0008.

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Roman buildings are among the most impressive and conspicuous legacies of the ancient world. To the millions who visit their ruins and reconstructed forms every year they are an absorbing and fascinating sight, not only because of their physical size and beauty as works of art, but for their historical value as a suggestive reminder of the past. For Edward Gibbon, these architectural remains were evidence of cultural and economic prosperity and supported his conclusion that: ‘[i]f a man were called to fix the period during which the condition of the human race was most happy and prosperous, he would without hesitation name that which elapsed from the death of Domitian [AD 96] to the accession of Commodus [AD 180].’ Since Gibbon’s time, excavation and scholarly analysis have reinforced this impression. Most regions within the Roman Empire have produced archaeological evidence of imposing buildings from this period. Foundations, scattered finds of building materials and architectural decoration, and building inscriptions, together suggest that the volume of buildings erected at this time was substantially greater than the surviving structures might suggest. This book is about Roman monumental architecture erected under the Antonine emperors, particularly during the reigns of Antoninus Pius (AD 138–61) and Marcus Aurelius (AD 161–80). Although there have been many individual regional and site studies, there has never been a general synthesis which evaluates the architecture of the Antonine period as a whole in the light of the increasing quantity of evidence. The present book does not aim to provide that synthesis in the manner of a conventional art-historical analysis of forms and styles. Nor does it set out to analyse the technologies and materials of Roman buildings, the logistics or practicalities of their construction, or the processes of their design, aspects which have been well studied in recent years. It attempts, rather, to consider the significance of the architecture of this period for contemporaries. Its focus is the question of architectural meaning. In the ancient world, buildings were not only a backdrop and setting for social interaction but also a form of social language.
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Thomas, Edmund. "Principles of Monumental Form in Antiquity." In Monumentality and the Roman Empire. Oxford University Press, 2007. http://dx.doi.org/10.1093/oso/9780199288632.003.0010.

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Roman buildings are among the most impressive and conspicuous legacies of the ancient world. To the millions who visit their ruins and reconstructed forms every year they are an absorbing and fascinating sight, not only because of their physical size and beauty as works of art, but for their historical value as a suggestive reminder of the past. For Edward Gibbon, these architectural remains were evidence of cultural and economic prosperity and supported his conclusion that: ‘[i]f a man were called to fix the period during which the condition of the human race was most happy and prosperous, he would without hesitation name that which elapsed from the death of Domitian [AD 96] to the accession of Commodus [AD 180].’ Since Gibbon’s time, excavation and scholarly analysis have reinforced this impression. Most regions within the Roman Empire have produced archaeological evidence of imposing buildings from this period. Foundations, scattered finds of building materials and architectural decoration, and building inscriptions, together suggest that the volume of buildings erected at this time was substantially greater than the surviving structures might suggest. This book is about Roman monumental architecture erected under the Antonine emperors, particularly during the reigns of Antoninus Pius (AD 138–61) and Marcus Aurelius (AD 161–80). Although there have been many individual regional and site studies, there has never been a general synthesis which evaluates the architecture of the Antonine period as a whole in the light of the increasing quantity of evidence. The present book does not aim to provide that synthesis in the manner of a conventional art-historical analysis of forms and styles. Nor does it set out to analyse the technologies and materials of Roman buildings, the logistics or practicalities of their construction, or the processes of their design, aspects which have been well studied in recent years. It attempts, rather, to consider the significance of the architecture of this period for contemporaries. Its focus is the question of architectural meaning. In the ancient world, buildings were not only a backdrop and setting for social interaction but also a form of social language.
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Gordon, Howard R. "Modeling and Simulating Radiative Transfer in the Ocean." In Ocean Optics. Oxford University Press, 1994. http://dx.doi.org/10.1093/oso/9780195068436.003.0005.

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The propagation of light in the sea is of interest in many areas of oceanography: light provides the energy that powers primary productivity in the ocean; light diffusely reflected by the ocean provides the signal for the remote sensing of subsurface constituent concentrations (particularly phytoplankton pigments); light absorbed by the water heats the surface layer of the ocean; light absorbed by chemical species (particularly dissolved organics) provides energy for their dissociation; and the attenuation of light with depth in the water provides an estimate of the planktonic activity. Engineering applications include the design of underwater viewing systems. The propagation of light in the ocean-atmosphere system is governed by the integral-differential equation of radiative transfer, which contains absorption and scattering parameters that are characteristic of the particular water body under study. Unfortunately, it is yet to be shown that these parameters are measured with sufficient accuracy to enable an investigator to derive the in-water light field with the radiative transfer equation (RTE). Furthermore, the RTE has, thus far, defied analytical solution, forcing one to resort to numerical methods. These numerical solutions are referred to here as “simulations.” In this chapter, simulations of radiative transfer in the ocean-atmosphere system are used (1) to test the applicability of approximate solutions of the RTE, (2) to look for additional simplifications that are not evident in approximate models, and (3) to obtain approximate inverse solutions to the transfer equation, e.g., to derive the ocean’s scattering and absorption properties from observations of the light field. The chapter is based on a lecture presented at the Friday Harbor Laboratories of the University of Washington directed to both students and experts. For the students, I have tried to make the material as self-contained as possible by including the basics, i.e., by providing the basic definitions of the optical properties and radiometry for absorbing-scattering media, developing the approximate solutions to the RTE for testing the simulations, detailing the model used for scattering and absorbing properties of ocean constituents in the simulations, and briefly explaining the simulation method employed. For the experts, I hope I have provided some ideas worthy of experimental exploration.
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Conference papers on the topic "Light absorbing materials"

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Murray, Brian W., Dennis R. Floyd, and Eric Ulph, Sr. "Light-absorbing, lightweight beryllium baffle materials." In Orlando '91, Orlando, FL, edited by Max J. Riedl, Robert R. Hale, and Thomas B. Parsonage. SPIE, 1991. http://dx.doi.org/10.1117/12.46526.

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Saucedo, Edgardo. "Status and perspectives of emerging thin film photovoltaic inorganic materials." In International Conference on Advanced Light Absorbing Materials for Next Generation Photovoltaics. Fundació Scito, 2020. http://dx.doi.org/10.29363/nanoge.absogen.2020.011.

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Chen, Tao. "Antimony Selenosulfide: An Emerging Solar Material with Efficiency Overcoming 10%." In International Conference on Advanced Light Absorbing Materials for Next Generation Photovoltaics. Fundació Scito, 2020. http://dx.doi.org/10.29363/nanoge.absogen.2020.003.

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Sánchez-Palencia, Pablo, Gregorio García, José Carlos Conesa, Perla Wahnón, and Pablo Palacios. "New Absorbing Materials for Solar Cells beyond the Shockley-Queisser Limit: Transition Metal Hyperdoped (SnGe)3N4 Spinels." In International Conference on Advanced Light Absorbing Materials for Next Generation Photovoltaics. Fundació Scito, 2020. http://dx.doi.org/10.29363/nanoge.absogen.2020.012.

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Chigarev, N., J. Zakrzewski, V. Tournat, and V. Gusev. "Nonlinear laser optoacoustics of cracks in light-absorbing materials." In 11th European Quantum Electronics Conference (CLEO/EQEC). IEEE, 2009. http://dx.doi.org/10.1109/cleoe-eqec.2009.5196251.

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Turkevych, Ivan. "Progress in photovoltaic rudorffites: perspectives of silver iodobismuthates for next generation photovoltaics." In International Conference on Advanced Light Absorbing Materials for Next Generation Photovoltaics. Fundació Scito, 2020. http://dx.doi.org/10.29363/nanoge.absogen.2020.001.

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Ishizuka, Shogo. "Prospects for CIS solar cell research in Japan." In International Conference on Advanced Light Absorbing Materials for Next Generation Photovoltaics. Fundació Scito, 2020. http://dx.doi.org/10.29363/nanoge.absogen.2020.004.

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Chen, Weijian, Xiaoming Wen, Baohua Jia, and Xiaojing Hao. "Optical characterization & analysis routines of photogenerated carriers and mobile ions in perovskite." In International Conference on Advanced Light Absorbing Materials for Next Generation Photovoltaics. Fundació Scito, 2020. http://dx.doi.org/10.29363/nanoge.absogen.2020.006.

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Miyasaka, Tsutomu. "Interfacial engineering for high voltage performance of perovskite solar cells." In International Conference on Advanced Light Absorbing Materials for Next Generation Photovoltaics. Fundació Scito, 2020. http://dx.doi.org/10.29363/nanoge.absogen.2020.007.

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Siebentritt, Susanne. "How to use photoluminescence to improve your solar cells." In International Conference on Advanced Light Absorbing Materials for Next Generation Photovoltaics. Fundació Scito, 2020. http://dx.doi.org/10.29363/nanoge.absogen.2020.008.

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