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Meet Chengdu Liang: Energy & Environmental Science’s newest Advisory Board member

Chengdu Liang

Energy & Environmental Science (EES) is delighted to welcome Dr Chengdu Liang as an Advisory Board member.

Chengdu Liang is a scientist at the Center for Nano-phase Materials Sciences, Oak Ridge National Laboratory, USA. His research focusses on energy conversion and storage, catalytic nanomaterials, mesoporous materials and metal and metal oxide/sulfide nanoparticles. He is well known for his work on developing lithium-sulfur batteries and lithium-ion batteries.Energy & Environmental Science

On behalf of Chengdu Liang and the Editor-in-Chief Nathan Lewis (Caltech) we invite you to submit your best research to Energy & Environmental Science.

EES publishes outstanding, community-spanning, agenda-setting research covering all aspects of energy and environmental research. With an Impact Factor of 11.65, which is rising fast, it the ideal place to publish your work.

So you can see for yourself the quality of work in EES, we have collected together some recent articles in Dr Liang’s exciting research fields, with a selection available to read for free for a limited period.

Reviews

FREE: Na-ion batteries, recent advances and present challenges to become low cost energy storage systems
Verónica Palomares, Paula Serras, Irune Villaluenga, Karina B. Hueso, Javier Carretero-González and Teófilo Rojo
DOI: 10.1039/C2EE02781J

FREE: Mg rechargeable batteries: an on-going challenge
Hyun Deog Yoo, Ivgeni Shterenberg, Yosef Gofer, Gregory Gershinsky, Nir Pour and Doron Aurbach
DOI: 10.1039/C3EE40871J

FREE: The pursuit of rechargeable solid-state Li–air batteries
Fujun Li, Hirokazu Kitaura and Haoshen Zhou
DOI: 10.1039/C3EE40702K

FREE: Update on Na-based battery materials. A growing research path
Verónica Palomares, Montse Casas-Cabanas, Elizabeth Castillo-Martínez, Man H. Han and Teófilo Rojo
DOI: 10.1039/C3EE41031E

FREE: Room-temperature stationary sodium-ion batteries for large-scale electric energy storage
Huilin Pan, Yong-Sheng Hu and Liquan Chen
DOI: 10.1039/C3EE40847G

FREE: Challenges of non-aqueous Li–O2 batteries: electrolytes, catalysts, and anodes
Fujun Li, Tao Zhang and Haoshen Zhou
DOI: 10.1039/C3EE00053B

FREE: High temperature sodium batteries: status, challenges and future trends
Karina B. Hueso, Michel Armand and Teófilo Rojo
DOI: 10.1039/C3EE24086J

FREE: Electrical energy storage for transportation—approaching the limits of, and going beyond, lithium-ion batteries
Michael M. Thackeray, Christopher Wolverton and Eric D. Isaacs
DOI: 10.1039/C2EE21892E

FREE: Ti-based compounds as anode materials for Li-ion batteries
Guan-Nan Zhu, Yong-Gang Wang and Yong-Yao Xia
DOI: 10.1039/C2EE03410G

FREE: Lithium-ion batteries. A look into the future
Bruno Scrosati, Jusef Hassoun and Yang-Kook Sun
DOI: 10.1039/C1EE01388B

FREE: Challenges in the development of advanced Li-ion batteries: a review
Vinodkumar Etacheri, Rotem Marom, Ran Elazari, Gregory Salitra and Doron Aurbach
DOI: 10.1039/C1EE01598B

Original research

Controlled synthesis of hierarchical CoxMn3−xO4 array micro-/nanostructures with tunable morphology and composition as integrated electrodes for lithium-ion batteries
Le Yu, Lei Zhang, Hao Bin Wu, Genqiang Zhang and Xiong Wen (David) Lou
DOI: 10.1039/C3EE41181H

CuO/PVDF nanocomposite anode for a piezo-driven self-charging lithium battery
Xinyu Xue, Ping Deng, Shuang Yuan, Yuxin Nie, Bin He, Lili Xing and Yan Zhang
DOI: 10.1039/C3EE41648H

Synthesis of Mo2N nanolayer coated MoO2 hollow nanostructures as high-performance anode materials for lithium-ion batteries
Jun Liu, Shasha Tang, Yakun Lu, Gemei Cai, Shuquan Liang, Wenjun Wang and Xiaolong Chen
DOI: 10.1039/C3EE41006D

Charge transport in lithium peroxide: relevance for rechargeable metal–air batteries
Maxwell D. Radin and Donald J. Siegel
DOI: 10.1039/C3EE41632A

Towards high energy density sodium ion batteries through electrolyte optimization
Alexandre Ponrouch, Rémi Dedryvère, Damien Monti, Atif E. Demet, Jean Marcel Ateba Mba, Laurence Croguennec, Christian Masquelier, Patrik Johansson and M. Rosa Palacín
DOI: 10.1039/C3EE41379A

A membrane-free lithium/polysulfide semi-liquid battery for large-scale energy storage
Yuan Yang, Guangyuan Zheng and Yi Cui
DOI: 10.1039/C3EE00072A

Lithium metal fluorosulfate polymorphs as positive electrodes for Li-ion batteries: synthetic strategies and effect of cation ordering
Rajesh Tripathi, Guerman Popov, Brian L. Ellis, Ashfia Huq and L. F. Nazar
DOI: 10.1039/C2EE03222H

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Solar Energy for Afterhours

Sr- and Mn-doped LaAlO3−δ for solar thermochemical H2 and CO productionA major drawback to solar energy is the fact that it places us at the mercy of nature’s schedule. To get around this we need some method of storing it such as converting it into fuel. Whereas electric storage requires batteries, fuel storage only needs barrels and tanks. In a paper recently published in EES, researchers at Sandia National Labs demonstrated an improved method of converting solar energy directly into fuel.

The researchers identified an improved catalyst that splits water (or carbon dioxide) after heating by concentrating solar: using mirrors or lenses to shine lots of sunlight on one spot to get it really hot. At high temperatures (traditionally above 1500°C), oxygen is liberated from the catalyst. The catalyst is then cooled (traditionally to 800°C) and exposed to water vapor (or carbon dioxide gas). Starved for oxygen, the catalyst steals it from the water (or carbon dioxide) to leave hydrogen (or carbon monoxide). These products may either be directly used as fuel or for synthesis of more traditional fuels such as gasoline.

The improved catalyst is from a class of materials called “perovskite oxides” and contains a mix of strontium, lanthanum, manganese, aluminum and oxygen. Compared to traditional catalysts that use cerium or iron, this improved catalyst performs over a smaller range of temperatures: 1350°C for oxygen liberation and 1000°C for hydrogen (or carbon monoxide) production. This decrease in temperature range is important to ensuring the life of the catalyst, which (cycled every 5 minutes for 8 hours per day, 300 days per year over 10 years) must be sturdy enough to withstand 300-thousand cycles. It is anticipated that further exploration into this class of catalysts will yield further improvements.

Read the article in EES today:

Sr- and Mn-doped LaAlO3−δ for solar thermochemical H2 and CO production
Anthony H. McDaniel, Elizabeth C. Miller, Darwin Arifin, Andrea Ambrosini, Eric N. Coker, Ryan O’Hayre, William C. Chueh and Jianhua Tong
DOI: 10.1039/C3EE41372A

Robert Coolman EES guest web-writerBy Robert Coolman

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Hydrogen from the sun: the feasibility of industrial-scale photocatalytic H2 production

Chemists and chemical engineers from Cal-Tech, Stanford, and the US Department of Energy collaborated to investigate four methods of industrial-scale hydrogen gas generation directly from sunlight, via photocatalysis.

The lowest-tech solution, giant ‘baggies’ containing water and a photocatalytic slurry that co-generate hydrogen and oxygen, is the least expensive option, but in terms of land use is surprisingly as efficient as higher-tech panel-based options. Though this is a technical report, anyone interested in renewable energy and the hydrogen economy on a larger scale would find this interesting.

Technical and economic feasibility of centralized facilities for solar hydrogen production via photocatalysis and photoelectrochemistry

Hydrogen is the single most promising fuel for the future economy. Although >95% of it is presently made by steam reforming, it can be generated independently from fossil fuels. Thermal reforming of biofuels, renewably powered electrolysis, and photolytic generation together represent the possibilities for renewable H2 generation, and this paper investigates the viability of the last, modelling the scale-up of present technologies for H2 generation to ten tonnes per day. The US Department of Energy (DoE) guidelines set $2-4/kg H2 as a reasonable threshold for viability; based on an ideal location for gathering solar energy, the authors found that two of the four designs viably meet this goal.

Photocatalysis couples the hydrogen evolution reaction (HER) to the oxygen evolutio
lving the proposed overall efficiency. The first design predominates, and is proposed to produce H2 at $1.60/kg.n reaction (ORR). Two designs are based on slurries of photocatalytically active particles in water-filled HDPE bags. The single-bed system evolves H2 and O2 simultaneously, posing an explosive risk and requiring separation, but is simple and cost-effective. The dual-bed system evolves the two gases separately, but requires both the redox reaction of an efficiently redox-cycling ‘mediator’ (e.g. Fe2+/Fe3+) to be coupled to the OER and HER reactions and porous bridges between half-cells to transport the mediator between the cells, significantly complicating the design and halving the efficiency.

The other two designs are based on panels composed of two photocatalytically active layers between a transparent anode exposed to the sun where the HER occurs and a metal cathode where the OER occurs. The third design involves flat panels. The fourth design uses cylindrical parabolas for a 10:1 light concentration to increase efficiency. In both designs, the two reactions are inherently separated, and although panels are more efficient for the area collecting sunlight, panel spacing makes their footprint larger. Of these, the parabolic design predominates, producing at $3.20/kg.

Thus, both the giant baggie and concentrator panel options are economically viable – the baggies are cheaper, but the panels have fewer unknowns in terms of their safety, lifetime, and mass production. Compare these efficiencies with those of electrolyzer apparatuses paired to solar electrical generation, a further study the authors recommend, and we’ll have a good picture of the future of renewable fuel generation.

Read the article in EES:

Technical and economic feasibility of centralized facilities for solar hydrogen production via photocatalysis and photoelectrochemistry
Blaise A. Pinaud, Jesse D. Benck, Linsey C. Seitz, Arnold J. Forman, Zhebo Chen, Todd G. Deutsch, Brian D. James, Kevin N. Baum, George N. Baum, Shane Ardo, Heli Wang, Eric Miller and Thomas F. Jaramillo
DOI: 10.1039/C3EE40831K, Analysis

Benjamin Britton new EES guest web writerBy Benjamin Britton

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A Symphony of Components: Hierarchical CoxMn3-xO4 Electrodes

While the idea of micro/ nanostructured electrode materials has been very effective for developing high-performance lithium-ion batteries, integrated 3D electrodes with hierarchical arrays are the boutique avenues going forward. A recent Energy and Environmental Science paper by Yu et al presents morphology-controlled tunable CoxMn3-xO4 structures that exhibit interesting electrochemical performance.

Controlled synthesis of hierarchical CoxMn3−xO4 array micro-/nanostructures with tunable morphology and composition as integrated electrodes for lithium-ion batteries

The strategy of growing electroactive nanostructures on conductive substrates to form integrated 3D electrodes is interesting not only from a device-design standpoint but also for efficient electron transport, as noted by the authors. The synthesis strategy used is robust and well controlled. I find their approach and implementation of direct growth of free-standing and tailored CoxMn3-xO4 structures on current-collecting substrates to be an important and logical step towards integrated electrodes for high performance energy storage devices.

Electrode materials for lithium-ion batteries are the poster child for structure-performance relationships. The interplay between electrochemical performance and morphology of the assembled structure is intriguing and for me makes a strong case for studying these materials in-operation. How does each of the components alter during charging-recharging, what is their role and could the entire framework look like a symphony?

Intrigued by this symphony? Read the paper!

Controlled synthesis of hierarchical CoxMn3−xO4 array micro-/nanostructures with tunable morphology and composition as integrated electrodes for lithium-ion batteries
Le Yu, Lei Zhang, Hao Bin Wu, Genqiang Zhang and Xiong Wen (David) Lou
DOI: 10.1039/C3EE41181H

Prineha Narang EES guest web writer

By Prineha Narang

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Reengineering Photosynthesis

In a recent paper in Energy & Environmental Science, UCLA Parsons Foundation Professor James C. Liao and his lab report the metabolic engineering of cyanobacteria to efficiently produce photosynthetic n-butanol.

Oxygen-tolerant coenzyme A-acylating aldehyde dehydrogenase facilitates efficient photosynthetic n-butanol biosynthesis in cyanobacteriaThe production of sustainable energy and fuels is one of the great challenges facing chemistry today.  There are many approaches to this immense task, including the engineering of photosynthetic organisms to directly produce chemical fuels.

Ethanol is great for many reasons, but n-butanol is a better target for renewable fuel systems, as it can be blended seamlessly into the current fossil fuel infrastructure.  Unfortunately for synthetic biologists, the microbe that best produces n-butanol is a strict anaerobe, while the cyanobacterial photosynthetic machinery is responsible for the better part of the molecular oxygen in Earth’s atmosphere (For the record, this blogger is in favor of cyanobacterial oxygen evolution).

The authors of this paper find a clever way around this fundamental incompatability by using a different, air-tolerant enzyme for a key step in the biosynthetic pathway.  A propionaldehyde oxidation catalyst (PduP) demonstrated catalytic reduction of butyryl-CoA to n-butyraldehyde, which could subsequently be converted to n-butanol.  This is just one of 7 enzymes from 7 different organisms functioning in concert to produce the photosynthetic butanol.  Much of this process has been previously been reported by the Liao group.

The challenges in stitching together these genomes are enormous.  After all, no enzyme works in a vacuum (no offense, computationalists), and getting the right cocktail of expressed enzymes and complementary cofactors requires well-engineered organisms.   Even the best systems have yields discussed in milligrams per liter per day.  And even then, the butanol produced is toxic to the cells that make it.

Using synthetic biology to properly engineer these organisms will render them hardly recognizable.  The challenges are daunting, but the possibilities seem limitless.  By combining enzymes from many different organisms, each evolved over billions of years for efficient catalysis, or even human-designed enzymes tailored to exotic new schemes, metabolic engineers could produce stripped-down microbial factories to fuel our transportation and synthesize fine chemicals.  Perhaps, given the diversity of life and biochemistry on Earth, microbial engineering could one day be used to bioterraform the solar system for human colonization!  Well, I can dream, right?

Read Liao and co-workers’ article in EES:

Oxygen-tolerant coenzyme A-acylating aldehyde dehydrogenase facilitates efficient photosynthetic n-butanol biosynthesis in cyanobacteria
Ethan I. Lan, Soo Y. Ro and James C. Liao
DOI: 10.1039/C3EE41405A

EES guest web writer Michael Doud By Michael Doud

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Meet Dan Wang: Energy & Environmental Science’s newest Advisory Board member

Energy & Environmental Science (EES) is delighted to welcome Professor Dan Wang as an Advisory Board member.

Dan Wang is a professor at the Institute of Process Engineering, Chinese Academy of Sciences. His research focuses on the design and synthesis of porous, layered and nano-structured materials and their applications in energy storage and generation and environmentally friendly catalysts. His interests include dye sensitized solar cells, photocatalysts, lithium ion batteries, and other energy applications.

On behalf of Dan Wang and the Editor-in-Chief Nathan Lewis (Caltech) we invite you to submit your best research to Energy & Environmental Science.

EES publishes outstanding, community-spanning, agenda-setting research covering all aspects of energy and environmental research. With an Impact Factor of 11.65, which is rising fast, it the ideal place to publish your work.

So you can see for yourself the quality of work in EES, we have collected together some recent articles in Prof. Wang’s exciting research fields, with a selection available to read for free for a limited period

Reviews

FREE: Recent advances in micro-/nano-structured hollow spheres for energy applications: From simple to complex systems
Xiaoyong Lai, Jonathan E. Halpert and Dan Wang
Energy Environ. Sci., 2012,5, 5604-5618
DOI: 10.1039/C1EE02426D

FREE: 3D carbon based nanostructures for advanced supercapacitors
Hao Jiang, Pooi See Lee and Chunzhong Li
Energy Environ. Sci., 2013, 6, 41-53
DOI: 10.1039/C2EE23284G

FREE: Semiconductor nanowires: a platform for exploring limits and concepts for nano-enabled solar cells
Thomas J. Kempa, Robert W. Day, Sun-Kyung Kim, Hong-Gyu Park and Charles M. Lieber
Energy Environ. Sci., 2013, 6, 719-733
DOI: 10.1039/C3EE24182C

FREE: Highly efficient dye-sensitized solar cells: progress and future challenges
Shufang Zhang, Xudong Yang, Youhei Numata and Liyuan Han
DOI: 10.1039/C3EE24453A

Original research

One dimensional CuInS2–ZnS heterostructured nanomaterials as low-cost and high-performance counter electrodes of dye-sensitized solar cells
Luoxin Yi, Yuanyuan Liu, Nailiang Yang, Zhiyong Tang, Huijun Zhao, Guanghui Ma, Zhiguo Su and Dan Wang
DOI: 10.1039/C3EE24176A

Uniform V2O5 nanosheet-assembled hollow microflowers with excellent lithium storage properties
An Qiang Pan, Hao Bin Wu, Lei Zhang and Xiong Wen (David) Lou
DOI: 10.1039/C3EE40260F

Facile synthesis of Au@TiO2 core–shell hollow spheres for dye-sensitized solar cells with remarkably improved efficiency
Jiang Du, Jian Qi, Dan Wang and Zhiyong Tang
DOI: 10.1039/C2EE21264A

Low-temperature processed meso-superstructured to thin-film perovskite solar cells
James M. Ball, Michael M. Lee, Andrew Hey and Henry J. Snaith
DOI: 10.1039/C3EE40810H

Controlled synthesis of hierarchical CoxMn3−xO4 array micro-/nanostructures with tunable morphology and composition as integrated electrodes for lithium-ion batteries
Le Yu, Lei Zhang, Hao Bin Wu, Genqiang Zhang and Xiong Wen (David) Lou
DOI: 10.1039/C3EE41181H

New materials based on a layered sodium titanate for dual electrochemical Na and Li intercalation systems
Mona Shirpour, Jordi Cabana and Marca Doeff
DOI: 10.1039/C3EE41037D

Hierarchical hollow spheres composed of ultrathin Fe2O3 nanosheets for lithium storage and photocatalytic water oxidation
Jixin Zhu, Zongyou Yin, Dan Yang, Ting Sun, Hong Yu, Harry E. Hoster, Huey Hoon Hng, Hua Zhang and Qingyu Yan
DOI: 10.1039/C2EE24148J

Controlled fabrication of ultrathin-shell BN hollow spheres with excellent performance in hydrogen storage and wastewater treatment
Gang Lian, Xiao Zhang, Shunjie Zhang, Duo Liu, Deliang Cui and Qilong Wang
DOI: 10.1039/C2EE03240F

Control of the nanoscale crystallinity in mesoporous TiO2 shells for enhanced photocatalytic activity
Ji Bong Joo, Qiao Zhang, Michael Dahl, Ilkeun Lee, James Goebl, Francisco Zaera and Yadong Yin
DOI: 10.1039/C1EE02533C

Shape-tailored TiO2 nanocrystals with synergic peculiarities as building blocks for highly efficient multi-stack dye solar cells
Luisa De Marco, Michele Manca, Roberto Giannuzzi, Maria R. Belviso, P. Davide Cozzoli and Giuseppe Gigli
DOI: 10.1039/C3EE24345A

A facile approach for the synthesis of monolithic hierarchical porous carbons – high performance materials for amine based CO2 capture and supercapacitor electrode
Luis Estevez, Rubal Dua, Nidhi Bhandari, Anirudh Ramanujapuram, Peng Wang and Emmanuel P. Giannelis
DOI: 10.1039/C3EE40549D

Optimized porous rutile TiO2 nanorod arrays for enhancing the efficiency of dye-sensitized solar cells
Miaoqiang Lv, Dajiang Zheng, Meidan Ye, Jing Xiao, Wenxi Guo, Yuekun Lai, Lan Sun, Changjian Lin and Juan Zuo
DOI: 10.1039/C3EE24125D

Improved hydrogen storage performance of Ca(BH4)2: a synergetic effect of porous morphology and in situ formed TiO2
Jian Gu, Mingxia Gao, Hongge Pan, Yongfeng Liu, Bo Li, Yanjing Yang, Chu Liang, Hongliang Fu and Zhengxiao Guo
DOI: 10.1039/C2EE24121H

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Will Abundant Sodium Replace Rare Lithium in Future Batteries?

Alexandre Ponrouch and coworkers made significant progress in the optimization of the electrolyte system for sodium-ion batteries. They demonstrate a working sodium-ion battery with an energy density comparable to that of state-of-the-art lithium-ion batteries.

Sodium is both cheaper and more abundant than lithium, and thus sodium-ion batteries are an appealing alternative to lithium-ion batteries for a broad range of energy storage applications. Previous work on Na-ion batteries has demonstrated that hard carbon (HC) electrodes are well suited for the anode of a battery that uses an electrolyte based on a mixture of ethylene carbonate (EC) and propylene carbonate (PC).  However, the addition of a third co-solvent can decrease electrolyte viscosity and thus increase its ionic conductivity.  Dimethyl carbonate (DMC) was found to be a viable third co-solvent, combining decreased viscosity, increased ionic conductivity and a stable solid electrolyte interphase (SEI) layer (as demonstrated by XPS).

A full battery, utilizing a hard carbon anode, a Na3V2(PO4)2F3 (NVPF) cathode, and an EC/PC/DMC electrolyte was assembled. The battery had an operation voltage of 3.65 V, 110 mA h g-1 specific capacity for the cathode and 300 mA h g-1 specific capacity for the anode.  This yields an overall specific energy of 78 Wh kg-1, a figure that compares favorably with that of current Li-ion batteries.

For more information on this exciting advancement in Na-ion batteries, read the full article here:

Towards high energy density sodium ion batteries through electrolyte optimization
Alexandre Ponrouch, Remi Dedryvere, Damien Monti, Atif E. Demet, Jean Marcel Ateba Mba, Laurence Croguennec, Christian Masquelier, Patrik Johansson and M. Rosa Palacin
DOI: 10.1039/c3ee41379a

Heather Audesirk guest web-writerby Heather Audesirk

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Hybrid Energy Harvesters for Hydrogen Production

Researchers in Atlanta, GA have developed a device that produces hydrogen gas from waste heat, solar, and/or mechanical energies.

A hybrid energy cell for self-powered water splitting

Recent research conducted at Georgia Institute of Technology by Yang and coworkers have developed a new hybrid energy harvesting device to aid in the effort of hydrogen fuel production. Currently, hydrogen gas for use in industry is predominantly generated by steam reformation of methane or natural gas. This method produces greenhouse gas, requires high temperatures, and utilizes non-renewable resources.

Electrolytic production of hydrogen from water is one popular contender, due to its simplicity and abundance of reactants, however it is currently a more expensive process than through steam reformation. By developing a hybrid device that can take advantage of multiple modes of otherwise wasted energy, an “ambient” fuel generator can be realized.

The novelty in the present work is the combination of solar, thermal, and mechanical energies in the electrolysis of water. By matching a Si-pyramid solar cell with a Bi2Te3 based thermoelectric cell, along with a polyamide-perfluoroalkoxy based triboelectric nanogenerator, simultaneous energy harvesting can occur under a variety of environmental conditions. The group has reported H2 gas production at a rate of 4 x10-4 mL/s under hybrid generation mode. The technology can also be made to charge a Li-ion battery for on-demand hydrogen production, to compensate for environmental fluctuations.

With optimization, technology such as this can one day exist as a remote platform on the open ocean, passively generating hydrogen gas to be either pipelined to land, or used immediately for fuel cell powered ships.

David Novitski EES guest web-writer

by David Novitski

Interested? Read the full communication in Energy and Environmental Science here:

A hybrid energy cell for self-powered water splitting
Ya Yang, Hulin Zhang, Zong-Hong Lin, Yan Liu, Jun Chen, Ziyin Lin, Yu Sheng Zhou, Ching Ping Wonga and Zhong Lin Wang
Energy Environ. Sci., 2013, Advance Article
DOI: 10.1039/C3EE41485J

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Towards the 3rd breakthrough of Mg rechargeable batteries

If I say rechargeable batteries, most people think immediately about Li-ion batteries as the most successful achievement in this field. However, some issues related to safety, energy density and price are now forcing Li-ion battery research through big challenges, highlighting Mg batteries as a promising alternative technology for energy storage and conversion.

In their recent PCCP Perspective, Doron Aurbach and co-authors provide a closer look at Mg rechargeable batteries and guide the reader through 23 years of research since the first breakthrough in 1990 by Gregory et al. Gregory’s group demonstrated that Mg organo-borate moieties in solution, such as Mg(BBu2Ph2)2 in THF, allow magnesium to be deposited/dissolved successfully in a reversible process, despite the absence of highly reducing Grignard reagents.

This work led to a 2nd breakthrough in 2000 by Aurbach et al. who developed new electrolyte solutions comprised of ethereal solvents and complexes of the Mg(AlCl4-nRn)2 type (R = alkyl or aryl groups), with 100% reversibility of Mg deposition and anodic stability of 2.1 V vs. Mg.

Some companies, including Sony, LG and Toyota, already have prototypes of high energy density Mg rechargeable batteries with 2-3 V anodic stability. Compatibility needs to be enhanced in order to allow further developments of efficient rechargeable batteries.

by Martina Congiu

Interested in a better understanding about this field? Read more from the Perspective article:

Mg rechargeable batteries: an on-going challenge
Hyun Deog Yoo, Ivgeni Shterenberg, Yosef Gofer, Gregory Gershinsky, Nir Pour and Doron Aurbach
DOI: 10.1039/C3EE40871J

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UPDATE – Challenges in Chemical Renewable Energy (ISACS12)

Early Bird Deadline – 12 July 2013

Don’t forget that early bird registration for Challenges in Chemical Renewable Energy (ISACS12) closes this Friday. Make sure you register for this significant conference before 12 July 2013 to guarantee your place at the reduced fee.

For full details including themes and speaker details, please visit the dedicated website.

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