Energy Storage North America (ESNA), the most influential gathering of policy, technology and market leaders in energy storage, will be held October 13th-15th in San Diego, California. 

ESNA will feature site visits, workshops, presentations from industry leaders and regulators, and exhibitions showcasing the latest in advanced energy storage technology. 

Last year, ESNA more than doubled in size from its inaugural event in 2013, with over 1,500 attendees from 26 countries coming together to learn, strategize, and shape the market for storage in North America. Registration and exhibit space reservations for ESNA 2015 are now open. For more information, visit www.esnaexpo.com.

Don't forget: CNESA members receive discount tickets, so if you're planning on going, contact us! 

According to the CNESA database, half of energy storage deployments in China are applied in distributed generation and microgrids, making these applications the most common application of energy storage technology in China.

Within this, industrial and commercial use is greatest, followed by applications in remote and island communities, accounting for 54% and 39% respectively.

There are three reasons that applications in microgrids and distributed generation have become so popular.

1. Solar PV deployments in China are moving away from purely large-scale ground-based solar farms to a mix of large-scale deployments and distributed generation.
2. For isolated and island communities, renewable generation is becoming economically competitive when compared to the costs of burning diesel or building out transmission lines.
3. In the context of a growing interest in an “internet of energy,” results from demonstration projects shifted attention towards microgrids and distributed generation.

However, there are problems preventing the wider deployment of energy storage in this sector. In CNESA’s annual conference held in June, Energy Storage China 2015, experts discussed what is holding the industry back:

• Pricing – The price of residential-use electricity is too low. Demand charges are also not widespread, and where they exist, the difference isn’t big enough to support energy storage installation.
• Incentives – There are currently no subsidy programs specifically for energy storage technology. With feed-in tariffs for solar PV set at 0.42CNY/kWh (US$0.07/kWh), interest in installing energy storage to complement solar PV has been minimal.
• Management – Energy management systems for industrial installations are complex, which is hampering the expansion of rooftop PV and accompanying storage systems.
• Overlap – In some isolated communities where microgrids were built, grid companies built out transmission lines anyway, making the original microgrid installations largely extraneous.
• Technology – Technical problems have plagued existing demonstration projects, including inconsistencies resulting in diminished recharge capacity among lithium batteries, imprecise BMS systems, and a lack of technical and testing standards for PCS equipment resulting in long maintenance downtime.

Despite all this, the consensus is that distributed generation and microgrids are still going to take leading roles in commercializing energy storage in the near future. 

Since the announcement of the 2010 Nobel Prize in physics, graphene has received considerable attention from researchers worldwide. In 2004, Dr. Andre Geim at the University of Manchester successfully used micromechanical techniques to isolate single sheets of graphene from highly ordered pyrolytic graphene. Graphene’s unique properties have made it a highly attractive topic of research.

What is graphene, anyway?

Graphene is a hexagonal, two-dimensional allotrope of carbon. It can be formed into zero-dimensional fullerines, one-dimensional carbon nanotubes, and stacked to form three-dimensional graphite. As such, graphene is a basic component for other graphite materials. Graphene possesses many special properties. It has a tensile strength of 130GPa, 100 times stronger than steel. Its thermal conductivity is 500W·m-1K-1, three times that of diamond. Its electron mobility is 15000cm2·V-1s-1, over ten times greater than commercial silicon. At 2630m2·g-1, it has an extremely high specific surface area. It is conductive at room temperature, and functions much more quickly than present-day conductors.

Graphine itself is only one carbon atom wide. It is theorized to have a large specific surface area, high conductivity, and a honeycomb-like structure,  which is what gives it potential for use in lithium-ion batteries. The proposed applications include direct use as an anode; use in tin-based, silicon-based, or transition metal anode composites; use as a composite in lithium iron phosphate cathodes; or use as a conductive additive.

(1)   Use of graphene as an anode in lithium-ion batteries

Because graphene is composed of a single atomic layer of carbon, lithium ions can be placed between two layers of graphene to create Li2C6, a superior electrode material (with an energy density of 744mAh·g-1) compared to traditional carbon anodes. The lithium ions are stored in the spaces between the graphene sheets. It is this morphology and structure that determine the effectiveness of graphene as an anode material.

Because pure graphene has a low coulombic efficiency, a high charge-discharge platform, and low cycle stability, graphene in itself is unlikely to replace existing carbon-based commercial materials currently used in lithium-ion battery anodes. Moreover, graphene sheets stacked together lose the advantage of a large surface area to store lithium ions. However, graphene makes an excellent composite material for electrodes.

(2)   Graphene-composite anodes

Graphene is highly conductive, demonstrates high mechanical strength, flexibility, and stability, and possesses a high specific surface area. In particular, chemically transformed graphene has a high number of functional groups, making it useful as a substrate for composite electrodes.

Graphene composites with tin, silicon, and transition metals have already been researched in depth. Tin and silicon-based electrodes, when doped with graphene, can maximize synergies between the two materials. Graphene can reduce the size of the active material, prevent the agglomeration of nanoparticles, improve electrical and ionic transmission, and improve mechanical stability. These improvements lead to better capacity and rate performance, as well as longer lifecycles.

The preparation of graphene-composite electrode materials requires the uniform distribution of nanoparticles on one or multiple layers of graphene. The effectiveness of the composite is determined by the interaction between the two materials.  Presently, graphene composite manufacturing is developing to a stage where the morphology of composites can be well-controlled through in-situ and interfacial reactions. Nonetheless, easier and more effective preparation methods are crucial for the future application of graphene in lithium-ion batteries.

(3)   Applications of graphene as cathode material

Conductivity of cathodes is a major limit to the effectiveness of a battery. Many cathode materials – particularly in cases of large electrical discharge – demonstrate lower capacity than should theoretically be the case. As a result, researchers hope that graphene’s unique surface area and conductive properties will improve the conductivity of cathode materials and increase lithium ion transmission.  Adding graphene into the cathode mix reduces interfacial resistance between the electrolyte and active cathode material, and improves Li+ transmission. At the same time, graphene placed on the surface of the cathode prevents metal oxides from dissolving or transforming, thereby maintaining structural stability.

Graphene is used most commonly with lithium iron phosphate cathodes. In these composites, graphene functions as a current collector coating and conductive additive. Graphene’s two-dimensional conductive surface provides a highly active and conductive electrode, thereby improving the battery’s conductivity and rate performance.

(4)   Graphene as a conductive additive

In order to improve conductivity, conductive additives such as graphite, acetylene black, and Super P are added to battery electrodes. As a carbon material, graphene is also very effective as a conductive additive for lithium-ion batteries.

On carbon-based anodes, graphene provides more consistent conductivity throughout many discharge cycles regardless of the presence of active substances which would otherwise interrupt conduction, as compared to acetylene black. This allows for better cycling and rate performance.

On lithium iron phosphate cathodes, Super P uses small particles to fill gaps in the cathode, thereby improving conductivity. By comparison, graphene’s flexible surfaces achieve greater conductivity with fewer materials.

The biggest barrier to adoption of graphene conductive additives is that its high-rate performance is yet lacking. Current research has been limited to improving cycling and capacity under low rate conditions.

Summary

Since graphene was first isolated, it has shown usefulness in many applications –electrochemical batteries, optoelectronics, catalysts, and more. There is further potential for applications in hydrogen storage, supercapacitors, lithium-sulfur batteries, lithium-air batteries, and other technologies. Looking forward, graphene will benefit from increasing scale, lower costs, better manufacturing methods, and improved functionality. CNESA is keeping a close eye on further developments and future applications for graphene.