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In a setup resembling traditional Korean doors, scientists from Korea have made dye-sensitised solar cells (DSCs) that are bendy enough to be rolled around a pen and twisted, while maintaining their energy conversion efficiency at 90% of that of the flat form. Bendable DSCs have potential applications in commercial advertising and small portable power sources.  

Current DSCs are built up of layers in a sandwich-type structure. They consist of two expensive transparent conductive oxide (TCO)-coated substrates with a spacer inserted between them to provide space for an electrolyte. Unfortunately, they are not very flexible because bending causes a strain on the two electrodes as they are bent in opposite directions – one substrate is under compressive strain and the other is under tensile strain. This causes the substrates to detach from the spacer. 

The dye-sensitised solar cell is highly bendable because of its structure - based on traditional Korean doors. © Shutterstock

To circumvent this problem, Seung Cha and his team from the Korea Electrotechnology Research Institute, Boolmosangil, have bonded all the DSC components to glass paper, forming a structure similar to Korean doors. ‘The traditional Korean door is a beautiful and interesting internal door that consists of a wooden frame and traditional paper called “Hanji”,’ says Cha. ‘Hanji is very strong and can keep out the wind. At the same time, some light can penetrate the Hanji, creating good mood lighting in a living room.’  

First, the team attached a stainless steel mesh to one side of a sheet of glass paper. ‘The metal mesh acts as the wooden frame and the glass paper acts as the Hanji,’ explains Cha. Then, they deposited platinum – the electrochemical catalyst and conductor – on the other side. They deposited a TiO₂ photoelectrode onto the mesh and filled the pores in the glass paper with the electrolyte. ‘The structure is flexible, and expensive and fragile TCO films are not required,’ says Cha. 

Tests on the team’s DSC showed that it had an energy conversion efficiency of 2%. Cha admits that the 2% efficiency is not high compared to current DSC systems and that an efficiency of 5% is needed for commercial applications. DSCs with glass substrates have shown efficiencies of more than 10% and flexible DSCs using TCO film coated plastic substrates have efficiencies of more than 5%. ‘However, our structured cell can be rolled around a pen and this degree of flexibility has not reported before,’ he says.    

Cha’s team is working towards increasing the efficiency and he expects that they can achieve 4-5% efficiency with their concept in time.  

‘As the cost of depositing the semiconductor in solar cells has dropped significantly in recent years, attention is shifting to reducing the cost of the substrate and electrodes,’ says Michael McGehee, an expert in DSCs from Stanford University, US. ‘Using paper, instead of conventional substrate materials like glass, metal or plastic, is very attractive, but has proven to be difficult because paper is rough. The authors have come up with a very clever design for making dye-sensitised solar cells with glass paper that allows the electrolyte to go right through the paper. Their approach could lead to substantially cheaper solar cells.’ 

Elinor Richards 

Read the paper from EES: 

Dye-sensitized Solar Cells on Glass Paper: TCO-free Highly Bendable Dye-sensitized Solar Cells Inspired by Traditional Korean Door Structures
Seung Il Cha, Yuhyun Kim, Kyu Hyeon Hwang, Yunji Shin, S. H. Seo and Dong Y. Lee
Energy Environ. Sci., 2012, Accepted Manuscript
DOI: 10.1039/C2EE03096A 

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Scientists from Japan and India have created a dye-sensitised solar cell (DSSC) with the highest recorded efficiency of 11.4%, breaking the record set five years ago.

In the search for alternative energy sources to silicon-based photovoltaic cells, DSSCs have been heavily researched. They are a promising option, as they have a low manufacturing cost and the potential for high efficiency. Unfortunately, their conversion efficiency is currently still below that of silicon cells and the research to improve them is extensive.

Interested to know more? Read the full article in Chemistry World here…

High-Efficiency Dye-Sensitized Solar Cell with a Novel Co-Adsorbent
Liyuan Han, Ashraful Islam, Han Chen, Chandrasekharam Malapaka, Shufang Zhang, Xudong Yang and Masatoshi Yanagida
Energy Environ. Sci., 2012, Accepted Manuscript
DOI: 10.1039/C2EE03418B

Fancy submitting an article to EES? Then why not submit to us today! 

With the increasing energy demands of the 21st century creating a pressing interest in alternative power sources, the demand for high performing, state-of-the-art fuel cells has never been greater. However, these fuel cells require the precious metal platinum to generate their high power output, and this drawback has led scientists in Taiwan to develop a competitive replacement by combining carbon, and curiously, vitamin B12.

‘The limited abundance of platinum and other noble metals on Earth restricts the development of fuel cells. Searching for a non-noble-metal catalyst is a major issue,’ explains Kuei-Hsien Chen, from the Institute of Atomic and Molecular Science, Taipei, who, along with other colleagues, has developed this peculiar solution.

In order to generate electricity, most modern fuel cell devices require an oxygen reduction reaction (ORR) at the cathode of the cell, whilst simultaneously, another chemical (often hydrogen) is oxidised at the anode. This redox reaction for power generation has been limited by the slow ORR process, which in nature requires complex enzymes to proceed at any meaningful rate.

Although scientists have been investigating methods for speeding up the ORR, it has been notoriously difficult to produce a cathode that can achieve this and so they have had to resort to loading high amounts of expensive platinum onto the cathode to generate the required ORR rate. 

However, Chen and co-workers have dispensed with the need for platinum altogether, by using cheap carbon that has vitamin B12 dispersed throughout, to form the cathode of their polymer electrolyte fuel cell (PEFC). The performance of this cathode doesn’t quite match that of platinum based cathodes, but at a fraction of the cost, this cathode could open up real opportunities for the practical application of these fuel cells. 

Fuel cell expert John Varcoe, from the University of Surrey, UK, thinks that Chen’s advance clearly shows ‘promise for use as a fuel cell catalyst’, however, he urges caution by noting that the fuel cell’s performance over ‘many thousands of hours will need to be demonstrated before it will rival current (more expensive) fuel cell catalysts’.

Chen hopes to continue to develop his PEFC to make the cathode more effective, but in the meantime, this research may make fuel cells more accessible as a power source for the world’s future energy needs.

Ross McLaren



Read the paper from Energy & Environmental Science:

Vitalizing fuel cells with vitamins: pyrolyzed vitamin B12 as a non-precious catalyst for enhanced oxygen reduction reaction of polymer electrolyte fuel cells
Sun-Tang Chang, Chen-Hao Wang, He-Yun Du, Hsin-Cheng Hsu, Chih-Ming Kang, Chia-Chun Chen, Jeffrey C. S. Wu, Shi-Chern Yen, Wen-Fei Huang, Li-Chyong Chen, M. C. Lin and Kuei-Hsien Chen
Energy Environ. Sci., 2011
DOI: 10.1039/c1ee01962g

The latest issue of Energy & Environmental Science is now online. You can read the full issue here:



The outside front cover features an article on High and selective CO2 uptake, H2 storage and methanol sensing on the amine-decorated 12-connected MOF CAU-1 by Xiaoliang Si, Chengli Jiao, Fen Li, Jian Zhang, Shuang Wang, Shuang Liu, Zhibao Li, Lixian Sun, Fen Xu, Zelimir Gabelica and Christoph Schick.





Metabolite-based mutualism between Pseudomonas aeruginosa PA14 and Enterobacter aerogenes enhances current generation in bioelectrochemical systems is the article highlighted on the inside front cover by Arvind Venkataraman, Miriam A. Rosenbaum, Sarah D. Perkins, Jeffrey J. Werner and Largus T. Angenent.

Issue 11 contains the following Perspective and Review articles – take a look at these exciting feature articles:

• On the electrical conductivity of microbial nanowires and biofilms 
• From Ni-YSZ to sulfur-tolerant anode materials for SOFCs: electrochemical behavior, in situ characterization, modeling, and future perspectives
• Organic solar cells: A new look at traditional models
• Membrane-based production of salinity-gradient power 
• Precipitation estimates for hydroelectricity 
• Chemical solutions for the closed-cycle storage of solar energy
• Theoretical studies of dye-sensitised solar cells: from electronic structure to elementary processes

Fancy submitting an article to EES? Then why not submit to us today!