Oct 26

Synthesis and Fabrication of New Generation of Solar Cells

Full Name: Akshaya Subhramaniyan Rasappagounder

Research Area: Dye Sensitized Solar Cells

Title of The Research: Platinum free counter electrode for Dye‐Sensitized Solar Cells

Description: Dye- Sensitized Solar Cell (DSSC) is known for its low-cost, simple fabrication process, durability and relatively high efficiency. Typical DSSCs is made of I-/I3- redox couple liquid electrolyte sandwiched between dye coated TiO2 (photo anode) and transparent Tin oxide coated by platinum (Pt) substrate (counter electrode). Although Pt is one of the most selected superior material for catalyzing I^– to I^{3 –}, its weak chemical stability i.e., it decomposes to PtI₄ or H₂PtI₂ in triiodide/iodide electrolyte and its high cost restricts the scale up production for DSSC. So, it is necessary to go for an alternative counter electrode with high stability from abundant materials. In that case, Metal sulphides are found to be one of the best alternative materials. I’m currently working on synthesis part of metal sulphides and followed by fabrication process.

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Full Name: Asitha Udayanga Malikaramge

Research Area: Nanoscience and Nanotechnology

Title of The Research: Photon Upconversion as a Tool to Harvest Infrared Radiation for Direct Illumination in the Dark and to Fabricate Dye-sensitized Solar Cells to Generate Electricity Under Illumination as well as in the Dark.

Description:This is project which has been designed for direct application in two broad areas, namely, visible light generation from stray infrared radiation for illumination in the dark and electricity generation in the daytime as well as in the night by utilizing both dyes capable of absorbing visible radiation and generating visible radiation from upconverted infrared photons by photon upconverting materials embedded in solar cells. These devices will generate visible light without any cost in the first case and electricity by converting both visible and infrared radiation to electricity by upconverting infrared radiation to visible light. As such, illuminating houses in the night without any electricity or fuel is anticipated in the first case and generation of electricity from entire visible and infrared regions of the solar spectrum is anticipated in the second case.

Full Name: Kajana Thirunavukarasu

Research Area: Photocapacitor

Title of The Research: Storage of solar energy by heterostructured Silver-Metal oxides-SnS₂ photocapacitors

Description: In the present world, solar radiation acts as the energy input in the growth of energy systems, which can meet the future global energy demand. There are mainly two different approaches to store the energy, batteries and capacitors. Batteries convert and store the electrical energy as chemical energy but capacitors store the electrical energy and give this energy again to the circuit when necessary. In my proposed study, heterostructured materials in the form of nanocomposites will be synthesized, characterized and their solar energy storage efficiency will be thoroughly investigated.

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Full Name: Pavithrakumar Palanichamy

Research Area: Perovskite Solar Cells

Title of The Research: Advances and Perspectives of Environmental Friendly Perovskite Solar Cells

Description: The main reason of Perovskite solar cells in today’s photovoltaic is its rapidly increased PCE up to 22.1% within a decade. This highest PCE obtained by using only lead (Pb) based metal as light absorbing material. Though the chemical instability and environmental hazardous of lead being a big challenge, many efforts based on improving stability has been achieved by modifying the halogen ions (Cl-, Br- and I-) and by exchanging divalent organic cation (CH3NH3I). Although, the percentage of lead consumption in perovskite is low; its water solubility and chemical instability can lead to harmful environment and acts as carcinogenic agent to the humans.

Herein, we will be clearly focusing on research works based on the various active absorbing materials which could replace lead (Pb) having all its significant properties such as i) high absorption co-efficient ii) high charge carrier mobility iii) optimal energy band gap iv) large carrier diffusion length etc. This incents would help the research community of thin film photovoltaic to fabricate toxicity free, environmental harmless metal halide perovskite solar cells.

Full Name: Pirashanthan Arumugam

Research Area: Hybrid titanium dioxide/polymer and dye sensitized solar cells

Title of The Research: Role of thiophene derivative dyes in enhancing the performance of hybrid titanium dioxide / polymer solar cells

Description: The modern world is experiencing the shortage of fossil fuel resources due to the rapid growth of population and technology. This prompted the search for developing cost-efficient clean energy sources. Regarding electricity supply, photovoltaic device (Solar cells) is the best clean energy sources among all other energy sources due to the advantages such as direct solar energy conversion without any intermediate stage, no moving parts, require little maintenance and they are silent in operations. Molecular electronic materials such as dyes, conjugated polymers, and small molecules are gaining much interest for applications in Photovoltaics. In particular, polymer blend and dye synthesized (photo electrochemical) solar cells play a major role in the field of organic Photovoltaics.

Here I interested to work with hybrid titanium dioxide/polymer and dye sensitized solar cells.

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Full Name: Nagarajan Prabavathy

Research Area: Thin Film Solar cells

Title of The Research: Dye Sensitized Solar cells (DSSC)

Description: Titania nanorods with rutile phase are prepared by hydrothermal method. This functions as photo electrode for DSSC. The aim of the project is to utilize natural dyes as sensitizers for DSSC. This minimizes the cost of the solar cell and the preparation is also easier. But the stability of dye is very short compared to synthetic dye. The factors affecting the degradation of dye are studied and improvements are taken to increase the photovoltaic performance of the cell using natural dye. Dye from rose flower is used as a sensitizer. Platinum and iodine/ iodide are used as counter electrode and liquid electrolyte respectively for DSSC fabrication. The following strategies such as using citric acid as solvent to extract dye, adding algal buffer layers on the TiO₂ film to improve the dye anchoring, preparing Ca doped nanorods to reduce the photocatalytic activity and utilizing algal co-sensitization to improve the dye stability were the measures performed to improve the solar performance of the cell from 0.67% to 3.01%.

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Full Name: Tharmakularasa Rajaramanan

Research Area: Dye Sensitized Solar Cells

Title of The Research: Ruthenium and selected rare earth element co-doped Titanium dioxide electrode for Dye Sensitized Solar Cells

Description: Dye Sensitized Solar Cells (DSSCs) are found to be low cost energy conversion devices with simple fabrication procedures, lightweight and environment friendly operation. However, relaxation and recombination processes hinder the performance of DSSCs. Use of doped or co-doped TiO₂ electrode in DSSCs may improve its performance as doping aﬀects the band structure and traps TiO₂ states which in turn modifies properties such as the conduction band energy, charge transport, recombination and collection. Hence, Our research will focus on improving charge transport and minimizing electron-hole recombination in DSSCs using Ruthenium and selected rare earth element co-doped TiO₂ as electron transporting material (ETM).

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Full Name: Selvakumar Pitchaiya

Research Area: Perovskite Solar Cells

Title of The Research: Perovskite Solar Cells: Surface/Interfacial Engineering on Enhancing Stability and Efficiency

Description: The primary objective of this proposed work is to fabricate perovskite based solar cells with enhanced performance and long-term stability by using appropriate interfacial/surface engineering. It has been proposed to use interfacial/surface modification in the perovskite-based solar cells by introducing a carbon based or doped nanocarbon layer into perovskite device architecture.

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Full Name: Shobana Manoharan

Research Area: All-Inorganic Perovskite Solar Cells

Title of The Research: Fabrication of Electron Transport Layer by employing TiO₂ based one dimensional Nanostructures

Description: My main stream of research is on the fabrication of Electron Transport Layer by employing TiO₂ based one dimensional nanostructures for All-Inorganic Perovskite solar cell application. I am currently engaged in the synthesis of TiO₂ based nanostructures by chemical and physical synthesis routes. Even though lot of research studies have been published using TiO₂ as an electron transport layer (ETL) in solar cell application, I found deep interest in elucidating the interaction between TiO₂based one dimensional nanostructured ETL and Perovskite layer. Moreover I’m highly motivated to emphasize the dual role of Electron transport layer, serves as a photoanode and scaffold to the perovskite layer, and to study its performance by adopting different surface engineering techniques. Here I have particularly chosen the All-Inorganic perovskite material to overcome the stability issues pointed by organic –inorganic perovskite materials.

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Full Name: Siva Uthayaraj

Research Area: Perovskite Solar cells

Title of The Research: Enhancing the performance of Perovskite solar cells by incorporating carbonaceous nanomaterials

Description: According to International Energy Agency 16 % of the global population (1.2 billion people), do not have access to electricity. Since the solar irradiation is a non-exhausting reservoir of energy, cost efficient Solar panels are expected to be a key sustainable solution for meeting electrical energy needs of the world. In this regard, the perovskite solar cells (PSC) gain much attention due to its high efficiency and low-cost of production. However, stability of perovskite and carrier conducting materials towards moisture and UV irradiation is found to be the major challenge in its long-term application. This study focuses on improving the efficiency of PSCs by utilizing different types of carbonaceous materials as the electron transporting material (ETM) and hole transporting materials (HTM).

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Full Name: Venkatraman Madurai Ramakrishnan

Research Area: Semiconduting nanomaterials/structures for dye sensitized and Perovskite solar cells

Title of The Research: Semiconduting nanomaterials/structures based Electron Transport layers (ETL’s) for dye sensitized and Perovskite solar cells

Description: In the present global scenario, clean and green energy have attrated wide attention and solar energy posessing the above candidature is considered as one the prime energy resource. Electron transport layers (ETL’s) is an important part in the solar cells. Among the different type of ETL’s used, Semiconducting nanoparticles/nanostructures in Dye sensitized and Perovskite solar cells are more efficient and it has a better stability when compared to other types of ETL’s.

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Full Name: Vinoth Pandi Dharmalingam

Title of The Research: Studies on CdS/CdSe quantum dot sensitized ZnO nanorods thin films for solar cell applications

Description: Semiconductor quantum dots such as CdS, CdSe which can absorb light in visible region, can serve as sensitizers as they are able to transfer electrons to large band gap semiconductors such as ZnO and TiO₂. In addition these quantum dots open up new way to utilize hot electrons or generate multiple charge carriers with a single photon and also offers better junction formation with solid hole conductors. Impact ionization process results in the production of two or more excitons with a single photon of energy greater than twice the band gap. My research aims in realizing quantum dot sensitized solar cells by deposition of CdS and CdSe quantum dot on to ZnO/ TiO₂

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Full Name: Yuvaraj Selvaraj

Research Area: Plasma Ion Implantation

Title of The Research: Plasma Ion Implantation of Nano Structured Carbon on Different Polymer Substrates for Bio-Medical Implant Applications

Description: The Plasma Based Ion implantation process is versatile technique to modify the surface of the materials. The new form of construction of surface modification has been achieved through this technique with very low-pressure environment to ensure the purity. Carbon is a main tool to incorporate at different substrates such as Polymers, Metal-Oxides and etc., by Plasma Ion Implantation method, to produce high purity materials for the excessive properties of super hydrophobic and biomedical implant applications. The specific tool as Invitro bioactivity deals the enhanced property of Anti-Bacterial activity, highly cell adhesive and drug delivery system.

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Oct 26

Tissue engineering

Full Name: Haja Sherief N Musthafa

Research Area: Engineering Computing

Title of The Research: Computer Aided Design and Modelling of Biomaterials for Tissue Engineering

Description: The main task of the research will be focused on modelling and simulation of multi-structural, large bone scaffolds with mechanical strength and surface layer properties suitable for cell adhesion and tissue generation based on new technologies. The specific tasks will be modelling and optimization of design, architecture and construction of 3-D printed multi-component scaffolds to improve mechanical properties and support vascularization within the entire volume of the implant. Gradients in stiffness, degradation profiles, porosity or mechanical/biological properties are important factors to improve vascularization. The objective will be achieved by developing computer-aided design technology to predict suitable pore size, filament size and orientation to control mechanical strength, cell adhesion, formability and in vitro and in vivo degradation profiles. By combining three-dimensional imaging, flow modeling, and numerical simulation of scaffold physical properties, and by using the synthesized biodegradable polymers and composites, it will be aimed to develop a novel 3D printed custom-made scaffold/biomaterial as a carrier for stem cells and for personalized medicine.

This research project will be part of the research collaboration between HVL-Bergen and Tissue Engineering research group at Department of Clinical Dentistry, Center for Clinical Dental Research, UiB-Bergen who are aiming to implement stem cell therapy and biomaterials for bone regeneration as an alternative of bone grafts. The project at HVL-Bergen will also aim to develop software tools to model bone structures and to assess the relationship between bone morphology and load transfer to optimize the design of the implants.

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Oct 26

Modelling of Energy Driven Water Splitting Materials

Full Name: Håkon Eidsvåg

Research Area: Quantum simulations and modelling of new materials for solar driven water splitting.

Title of The Research: Quantum mechanical modelling of Energy Driven Water Splitting materials.

Description: According to the International Energy Agency the global energy demand will increase by 30% by 2040, which is equivalent with adding an extra China and India to today’s energy market. Hence, it is clear that we need more energy if we are going to meet this new demand. This is where solar driven water splitting comes in. The idea is quite simple; a carefully chosen material can act as a catalyst, allowing solar energy to split water into oxygen and hydrogen. This allows us to store excess power as hydrogen for periods with less solar radiation or use it as fuel for cars, airplanes, cargo ships etc. The goal in this work is to find new alternative materials, which can bring down the cost and increase the solar to hydrogen efficiency for solar driven water splitting. I will do this through quantum modelling and simulations, which makes it possible to screen a high number of potential materials before the promising ones are thoroughly investigated. The work will not only focus on titanium dioxide with various dopants and similar materials, but will also look into exciting new materials and techniques as perovskites and localised surface plasmon resonance.

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Oct 26

Synthesis and Characterization of Waterspliting Materials

Full Name: Asitha Udayanga Malikaramge

Research Area: Nanoscience and Nanotechnology

Description: This is project which has been designed for direct application in two broad areas, namely, visible light generation from stray infrared radiation for illumination in the dark and electricity generation in the daytime as well as in the night by utilizing both dyes capable of absorbing visible radiation and generating visible radiation from upconverted infrared photons by photon upconverting materials embedded in solar cells. These devices will generate visible light without any cost in the first case and electricity by converting both visible and infrared radiation to electricity by upconverting infrared radiation to visible light. As such, illuminating houses in the night without any electricity or fuel is anticipated in the first case and generation of electricity from entire visible and infrared regions of the solar spectrum is anticipated in the second case.

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Full Name: Sivagowri Shanmugaratnam

Research Area: Chemistry

Title of The Research: “Transition metal chalcogenide [MS₂] embedded TiO₂ nanocomposites for hydrogen production over extended solar irradiation”

Description: Depletion of fossil fuel is gaining more public attention and receiving more financial and legislative support. In addition, development in industrial and technological sectors results in severe environmental issues. Therefore, there is a need for us to find an alternative way to overcome these challenges. Harvesting solar energy using potential materials is of prime for their applications towards energy and environmental processes. My work will focus on studying the impact of incorporation of transition metal chalcogenide on the active TiO₂ nano composites for hydrogen production over extended solar irradiation.

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Oct 26

Computational Modeling of Photovoltaic Materials

Full Name: Murugesan Rasukkannu

Research Area: Theoretical Studies of Photovoltaic solar cells

Title of the Research: Computational modeling of Photovoltaic materials

Description: The PhD position will focus on computer modeling and simulation of Intermediate band solar cells and Non-silicon solar cells. Computational modeling can substantially enrich the understanding of material properties thus helping the developing of solar cells that are more efficient.

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Oct 19

Research seminar of the ANCEHA

On the 19^th October 2018, ANCEHA conducted a half-day research seminar at HVL. PhD Research fellows, visiting exchange students and two visiting professors from Sri Lanka and one post-doctoral fellow from CET participated in the seminar along with Professor Dhayalan Velauthapillai. Students, PhD research fells and the post-doctoral fellow made presentations of their research. Lively and stimulating discussion followed each presentation.

Oct 18

Clean energy workshop for 3rd year undergraduate students at the HVL

ANCEHA research group on the 18th October 2018 conducted a half a day workshop on clean energy technologies for the third year undergraduate students of the HVL. Prof Dhayalan Velauthapillai gave introductory lecture on the basic principles of the clean energy with special focus on the photovoltaic devices. Prof. Ravirajan Punniamoorthyn who was visiting from University of Jaffna gave a presentation on their research on clean energy technologies with special focus on third generation solar cells and the ongoing research collaboration with HVL under the ANCEHA project. PhD Research Fellow Håkon Eidsvåg followed it up with his work on computer simulations and basic principles about solar driven waters splitting mechanisms. Finally, Prof. G. Rajanya Asoka Kumara, visiting from NIFS, Kandy, Sri Lanka did a presentation with practical demonstrations on solar cell applications and super capacitors made from coconut shell.

Oct 18

International Conference on Advanced Materials for Clean Energy & Health Applications

ABOUT AMCEHA 2019

The growing world population and the environmental challenges demand more focus on clean energy and health technologies. Advanced nanomaterials have paved the way for innovation and new applications in the field of clean energy and health sector. As the demand for clean energy is going to be immense in the future and many countries consider transforming themselves into clean energy economies, it is of utmost interest for the research community to work on novel ideas and find solutions for the challenges facing the clean energy sector. Rapid progress in nanotechnology in the past decade has provided significant breakthroughs in the area of energy sector and health applications. The International Conference on Advanced Materials for Clean Energy and Health Applications (AMCEHA 2019) will provide a forum for exchange of technical and scientific information between international researchers in the field of materials for clean energy and health applications.

Photovoltaics have received increasing attention in the last decade from the research community as well as industry and solar energy is considered as a promising source of clean energy. Emerging areas in solar cell research such as dye sensitized, quantum dot sensitized, organic and perovskite solar cells have given hope in producing low cost and flexible alternatives for Si based solar technology. Idea of floating solar cell installations have also created enthusiasm among the industrial community.

Accurate modelling and simulation methodologies have helped the wind energy sector in efficient wind turbine installations. Rapid technological developments in the wind energy sector has reduced the cost of installation, maintenance and production of wind power, many nations have started investing in both inshore and offshore wind turbine facilities.

Energy storage is one of the challenges both the solar and wind energy sectors face, and storing the energy as Hydrogen is one of the solutions the research community is interested of. Technological developments in fabricating fuel cells and in Hydrogen production has paved the way for use Hydrogen as clean energy source in the transport sector. Biomass is another area of interest for the research community in producing carbon neutral energy.

Biomaterials and Tissue Engineering is a promising field of research interest and covers diverse fields such as medicine, biology, chemistry, materials science and engineering. Biomaterials can be used for drug discovery, tissue regeneration, organ development, regenerative medicines and so on. Production of biodegradable and biocompatible materials has become a fascinating area which could be used in dentistry, orthopedics and as a diagnostic tool in the field of medicine. The biennial symposium will be a promising, and another exciting event bringing together the researchers, clinicians, scientists, engineers and industrial personnel to establish new collaborations, knowledge transfer and discuss the recent scenario in promising biomaterials. Symposia on materials for regenerative medicine and drug delivery will be organized as part of the conference and will be led by internationally renowned experts in the field.

Computational modeling and software tools are increasingly important to realize nanomaterials for both clean energy and health applications. The fundamental techniques of theory, modeling, and simulation have undergone a revolution that parallels the extraordinary experimental advances on which the new field of nanoscience is based. The development of density functional algorithms, Quantum Monte Carlo techniques, ab initio molecular dynamics, advances in Classical Monte Carlo methods, mesoscale methods for soft matter, fast-multipole and multigrid algorithms have made computational modeling the best tool to study nanomaterials. The combination of new theoretical methods together with increased computing power has made it possible to simulate systems with millions of degrees of freedom. This conference will throw light on the computational modeling and simulation used to study about nanomaterials.

AMCEHA 2019 Home Page

Oct 17

Haja Sherif participates in a workshop on Lean Innovation in Life Sciences

PhD Research Fellow Haja Sherief attended the ‘Lean innovation in Life Sciences’ workshop held on the 17th to 18th October 2018 at Oslo Science park, Oslo (Norway) organised by Centre for Digital Life Norway collaboration with The Life Science Cluster, Catapult Life Science and Share Lab, Science for Society and Digital Life Norway Research School.

Oct 16

The mobility of the Scholars

Professor Ravirajan Punniamoorthy and Professor G. Rajanya Asoka Kumara were invited by Professor Dhayalan Velauthapillai to HVL. Both Scholars arrived at Bergen on the 16th October 2018. Both of them took part in a seminar conducted for Undergraduate students and the students were given demonstrations on solar cells. The scholars also the met the Rector of the HVL and also participated in a half a day research seminar conducted for the ANCEHA group including research fellows, exchange students, and scholars from CIT.