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Kirthi Tennakone is a Sri Lankan scientist with an assortment of research interests in theoretical and experimental physics, chemistry and biological systems. He has authored over 350 publications covering a diverse variety of disciplines. He is the former Director of Institute of Fundamental Studies, Sri Lanka (now named as National Institute of Fundamental Studies) and the first Professor of Physics at the University of Ruhuna, Sri Lanka. He pursued studies leading to a doctoral degree in Theoretical Physics at the University of Hawaii under supervision of Sandip Pakvasa. Pakvasa and Tennakone were the first to suggest that neutrinos may be massive [1] and to consider the astrophysical implications. In condensed matter physics, Tennakone pioneered the studies on semiconducting properties copper(I) thiocyanate, [2] [3] a rare example of a transparent p-type semiconductor, currently adopted in many devices and developed techniques of its deposition as thin films. He was the first to introduce the concept of the dye-sensitized solid state solar [4] cell and demonstrate a working prototype of the same. Sri Lanka Government recognized his contribution to research and education and awarded National Honors on two occasions. He was one of the Union of Concerned Scientists who signed to the document presented to world leaders in 1992 about environmental degradation that threatens global life support systems on this planet.
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Born 1940 in a Village in Sri Lanka near the town of Veyangoda, he was exposed rural environment in early childhood. [5] He is a son of the poet and writer Piyathilaka Tennakone of Metitotumulla, Sri Lanka who inspired him to science and mathematics at an early stage. Kirthi Tennakone received primary education at the Central College, Veyangoda, Sri Lanka.
He earned a B.S in physics and mathematics from the University of Ceylon 1964. After serving as a teacher in the Department of Education for period of four years, he received an East-West Center Fellowship to pursue studies at the University of Hawaii and obtained a PhD degree in theoretical physics in 1972. He returned to Sri Lanka accepting an academic position at the University of Jayewardenepura and later appointed to the Chair of Physics at the University of Ruhuna. When the first endowed Chair in Sri Lanka (Sumanasekara Chair in Natural Science) was commissioned at the Institute of Fundamental Studies, he was appointed to this position by the President of Sri Lanka on basis of the recommendation of a high ranking search committee. Subsequently, he served as the director of this institution for a period of thirteen years, concurrently holding a professorship.
He has held visiting research positions at the International Center for Theoretical Physics, Trieste; Niels Bohr Institute, Copenhagen; Japan Society for Promotion of Science, Invitation Fellowship at the Shizuoka University, Japan; University of Cincinnati and currently an Adjunct Professor of Physics at Georgia State University.
Kirthi Tennakone has been awarded National Honors of the Government of Sri Lanka on two occasions, "Vidya Nidhi" in 1986 and "Desha Bandu" in 2005. University of Sri Jayewardenepura of Sri Lanka conferred an Honorary Doctor of Science Degree to him in 2007. He is a Fellow of The World Academy of Sciences, elected 1990. He was one of the invited scholars to visit Solar Cell Materials & Devices Group, Beijing, China.
Neutrino Physics: In 1972 Sandip Pakvasa and Kirthi Tennakone suggested that neutrinos may be massive and discussed consequences of massiveness, notably - astrophysical implications. [1] They pointed out the possibility assessing the neutrino mass by detecting the light and neutrino signals of supernova explosion. [1] Tennakone has also examined macroscopic changes in linear and angular momentum associated with neutrino bursts from astrophysical systems. [6] [7]
Condensed Matter Physics: Kirthi Tennakone and co-workers pioneered [8] the studies on semiconducting properties Copper(I) Thiocyanate, a rare example of a transparent p-type semiconductor, currently adopted in many devices and developed techniques of its deposition as thin films. [2] [3] [9] He has also worked on electrical conduction in unconventional materials, nanostructured films and electroceramics. Tennakone and co-workers introduced the idea of using crystal growth inhibitors to secure intimate contact and pore filling in nanostructured heterojunctions.
Solar Energy Conversion and Photochemistry: The concept of the dye-sensitized solid-state solar cell was first proposed by Tennakone et al. in a 1988 publication titled "Dye-sensitized solid-state solar cells". [10] The invention of practical device based on the idea was also first reported by Tennakone et al. in 1995. [4] Perovoskite solar cells are vigorously pursued nowadays are based on extremely thin layer of a low band gap semiconductor sandwiched between two nanostructured n and p type high band gap semiconductors, the concept subsequently referred to as eta cell was reported by Tennakone et al. in 1998. [11] Dye-sensitized solar cells are generally based mesoporous films of TiO2,.Tennakone’s group is also credited with development of a dye-sensitized cell of comparable efficiency adopting ZnO/SnO2composite films. [12] Tennakone et al. has also studied the dye-sensitization effect of plants derived compounds. [13] [14]
Biological Systems: Tennakone has worked on the problem of biological L-D stereoselection [15] and right-left symmetries in plants., suggesting that former could be spontaneous symmetry breaking in prebiotic chemical reactions or rapid growth of accidentally created, self-replicating handed molecule in racemic prebiotic medium. According to his findings, right-left asymmetries in plants can be classified into three distinct categories. (a) All individuals of the species has same handedness. (b) Individuals have either right or left-handedness, occurring with equal probabilities. (c) Individuals have no definable handedness, but some organs possesses either right or left-handedness.
Static Electricity: Tennakone has published several papers in the area of static electricity including atmospheric effects. [16] Recently he has hypothesized that perchlorate in Mars could be produced by electrolysis of sodium chloride following static electrification regolith and moisture condensation. [17]
Aluminum Leaching: Tennakone observed that fluoride enhance leaching of aluminum from cooking utensils. [18] A subsequent work and repetition of the experiments by Tennakone et al. [19] found that at 1ppm of F− leaching is not high as reported previously to pose a major toxicity issue. Later work of Tennakone [20] and several other investigators have confirmed the enhancement Al leaching under culinary conditions, when F− concentration is 10 ppm or more. [21]
Gallium is a chemical element with the symbol Ga and atomic number 31. Discovered by French chemist Paul-Émile Lecoq de Boisbaudran in 1875, Gallium is in group 13 of the periodic table and is similar to the other metals of the group.
Organic electronics is a field of materials science concerning the design, synthesis, characterization, and application of organic molecules or polymers that show desirable electronic properties such as conductivity. Unlike conventional inorganic conductors and semiconductors, organic electronic materials are constructed from organic (carbon-based) molecules or polymers using synthetic strategies developed in the context of organic chemistry and polymer chemistry.
Helioseismology, a term coined by Douglas Gough, is the study of the structure and dynamics of the Sun through its oscillations. These are principally caused by sound waves that are continuously driven and damped by convection near the Sun's surface. It is similar to geoseismology, or asteroseismology, which are respectively the studies of the Earth or stars through their oscillations. While the Sun's oscillations were first detected in the early 1960s, it was only in the mid-1970s that it was realized that the oscillations propagated throughout the Sun and could allow scientists to study the Sun's deep interior. The modern field is separated into global helioseismology, which studies the Sun's resonant modes directly, and local helioseismology, which studies the propagation of the component waves near the Sun's surface.
A heterojunction is an interface between two layers or regions of dissimilar semiconductors. These semiconducting materials have unequal band gaps as opposed to a homojunction. It is often advantageous to engineer the electronic energy bands in many solid-state device applications, including semiconductor lasers, solar cells and transistors. The combination of multiple heterojunctions together in a device is called a heterostructure, although the two terms are commonly used interchangeably. The requirement that each material be a semiconductor with unequal band gaps is somewhat loose, especially on small length scales, where electronic properties depend on spatial properties. A more modern definition of heterojunction is the interface between any two solid-state materials, including crystalline and amorphous structures of metallic, insulating, fast ion conductor and semiconducting materials.
Organic semiconductors are solids whose building blocks are pi-bonded molecules or polymers made up by carbon and hydrogen atoms and – at times – heteroatoms such as nitrogen, sulfur and oxygen. They exist in form of molecular crystals or amorphous thin films. In general, they are electrical insulators, but become semiconducting when charges are either injected from appropriate electrodes, upon doping or by photoexcitation.
A "photoelectrochemical cell" is one of two distinct classes of device. The first produces electrical energy similarly to a dye-sensitized photovoltaic cell, which meets the standard definition of a photovoltaic cell. The second is a photoelectrolytic cell, that is, a device which uses light incident on a photosensitizer, semiconductor, or aqueous metal immersed in an electrolytic solution to directly cause a chemical reaction, for example to produce hydrogen via the electrolysis of water.
A dye-sensitized solar cell is a low-cost solar cell belonging to the group of thin film solar cells. It is based on a semiconductor formed between a photo-sensitized anode and an electrolyte, a photoelectrochemical system. The modern version of a dye solar cell, also known as the Grätzel cell, was originally co-invented in 1988 by Brian O'Regan and Michael Grätzel at UC Berkeley and this work was later developed by the aforementioned scientists at the École Polytechnique Fédérale de Lausanne (EPFL) until the publication of the first high efficiency DSSC in 1991. Michael Grätzel has been awarded the 2010 Millennium Technology Prize for this invention.
A solar cell, or photovoltaic cell, is an electronic device that converts the energy of light directly into electricity by the photovoltaic effect, which is a physical and chemical phenomenon. It is a form of photoelectric cell, defined as a device whose electrical characteristics, such as current, voltage, or resistance, vary when exposed to light. Individual solar cell devices are often the electrical building blocks of photovoltaic modules, known colloquially as solar panels. The common single junction silicon solar cell can produce a maximum open-circuit voltage of approximately 0.5 volts to 0.6 volts.
MiniBooNE is a Cherenkov detector experiment at Fermilab designed to observe neutrino oscillations. A neutrino beam consisting primarily of muon neutrinos is directed at a detector filled with 800 tons of mineral oil and lined with 1,280 photomultiplier tubes. An excess of electron neutrino events in the detector would support the neutrino oscillation interpretation of the LSND result.
Photosensitizers produce a physicochemical change in a neighboring molecule by either donating an electron to the substrate or by abstracting a hydrogen atom from the substrate. At the end of this process, the photosensitizer eventually returns to its ground state, where it remains chemically intact until the photosensitizer absorbs more light. This means that the photosensitizer remains unchanged before and after the energetic exchange, much like heterogeneous photocatalysis. One branch of chemistry which frequently utilizes photosensitizers is polymer chemistry, using photosensitizers in reactions such as photopolymerization, photocrosslinking, and photodegradation. Photosensitizers are also used to generate prolonged excited electronic states in organic molecules with uses in photocatalysis, photon upconversion and photodynamic therapy. Generally, photosensitizers absorb electromagnetic radiation consisting of infrared radiation, visible light radiation, and ultraviolet radiation and transfer absorbed energy into neighboring molecules. This absorption of light is made possible by photosensitizers' large de-localized π-systems, which lowers the energy of HOMO and LUMO orbitals to promote photoexcitation. While many photosensitizers are organic or organometallic compounds, there are also examples of using semiconductor quantum dots as photosensitizers.
Hybrid solar cells combine advantages of both organic and inorganic semiconductors. Hybrid photovoltaics have organic materials that consist of conjugated polymers that absorb light as the donor and transport holes. Inorganic materials in hybrid cells are used as the acceptor and electron transporter in the structure. The hybrid photovoltaic devices have a potential for not only low-cost by roll-to-roll processing but also for scalable solar power conversion.
The standard solar model (SSM) is a mathematical treatment of the Sun as a spherical ball of gas. This model, technically the spherically symmetric quasi-static model of a star, has stellar structure described by several differential equations derived from basic physical principles. The model is constrained by boundary conditions, namely the luminosity, radius, age and composition of the Sun, which are well determined. The age of the Sun cannot be measured directly; one way to estimate it is from the age of the oldest meteorites, and models of the evolution of the Solar System. The composition in the photosphere of the modern-day Sun, by mass, is 74.9% hydrogen and 23.8% helium. All heavier elements, called metals in astronomy, account for less than 2 percent of the mass. The SSM is used to test the validity of stellar evolution theory. In fact, the only way to determine the two free parameters of the stellar evolution model, the helium abundance and the mixing length parameter, are to adjust the SSM to "fit" the observed Sun.
A quantum dot solar cell (QDSC) is a solar cell design that uses quantum dots as the absorbing photovoltaic material. It attempts to replace bulk materials such as silicon, copper indium gallium selenide (CIGS) or cadmium telluride (CdTe). Quantum dots have bandgaps that are tunable across a wide range of energy levels by changing their size. In bulk materials, the bandgap is fixed by the choice of material(s). This property makes quantum dots attractive for multi-junction solar cells, where a variety of materials are used to improve efficiency by harvesting multiple portions of the solar spectrum.
Building-integrated photovoltaics (BIPV) are photovoltaic materials that are used to replace conventional building materials in parts of the building envelope such as the roof, skylights, or facades. They are increasingly being incorporated into the construction of new buildings as a principal or ancillary source of electrical power, although existing buildings may be retrofitted with similar technology. The advantage of integrated photovoltaics over more common non-integrated systems is that the initial cost can be offset by reducing the amount spent on building materials and labor that would normally be used to construct the part of the building that the BIPV modules replace. In addition, BIPV allows for more widespread solar adoption when the building's aesthetics matter and traditional rack-mounted solar panels would disrupt the intended look of the building.
Organic photovoltaic devices (OPVs) are fabricated from thin films of organic semiconductors, such as polymers and small-molecule compounds, and are typically on the order of 100 nm thick. Because polymer based OPVs can be made using a coating process such as spin coating or inkjet printing, they are an attractive option for inexpensively covering large areas as well as flexible plastic surfaces. A promising low cost alternative to conventional solar cells made of crystalline silicon, there is a large amount of research being dedicated throughout industry and academia towards developing OPVs and increasing their power conversion efficiency.
Henry James Snaith is a professor in physics in the Clarendon Laboratory at the University of Oxford. Research from his group has led to the creation of a new research field, based on halide perovskites for use as solar absorbers. Many individuals who were PhD students and postdoctoral researchers in Snaith's group have now established research groups, independent research portfolios and commercial enterprises.
Copper(I) thiocyanate is a coordination polymer with formula CuSCN. It is an air-stable, white solid used as a precursor for the preparation of other thiocyanate salts.
Uwe Rau is a German physicist who made important contributions to the physics of the photovoltaic device, notably on explaining energy losses in thin-film solar cells and on the use of the reciprocity principle to characterize solar cells by electroluminescence techniques. This led to the development of this technique as a standard in research and industry.
Robert P. H. Chang is an American materials scientist who served as the president of the Materials Research Society (1989) and as a general secretary and president of the International Union of Materials Research Societies (IUMRS). Currently Chang heads the Materials Research Institute at Northwestern University. He is a member of advisory boards of the National Institute for Materials Science and of the journal Science and Technology of Advanced Materials.
Light soaking refers to the change in power output of solar cells which can be measured after illumination. This can either be an increase or decrease, depending on the type of solar cell. The cause of this effect and the consequences on efficiency varies per type of solar cell. Light soaking can generally cause either metastable electrical or structural effects. Electrical effects can vary the efficiency depending on illumination, electrical bias and temperature, where structural effects actually changes the structure of the material and performance is often permanently altered.