Volta pile like battery (Credit: Montclair State University)

A battery converts chemical energy directly into electrical energy. It consists of one or more voltaic cells, each of which is composed of two half cells. Each cell has a positive terminal and a negative terminal; these do not touch each other but are immersed in a solid or liquid electrolyte that contains ions that can react with chemicals in the electrode. Chemical energy is converted into electrical energy by chemical reactions that transfer charge between the electrode and the electrolyte at their interface. Such reactions are called faradaic and are responsible for current flow through the cell. Ordinary, non-charge-transferring (non-faradaic) reactions also occur at the electrode-electrolyte interfaces. Non-faradaic reactions are one reason that voltaic cells (particularly the lead-acid cell of ordinary car batteries) "run down" when sitting unused. 

Li-Ion battery

Dell laptop explodes in Japan (Credit: RescueHumor.com)

Three-dimensional Nanobatteries – The end to exploding batteries?

Schematic design of the 3D nanobattery

 The batteries developed by the team from Tel Aviv University (TAU) work in a different way than conventional batteries. Using a silicon or glass substrate, the team from TAU created a matrix of tiny holes each 50 microns in diameter and 500 micron deep. Each of these holes functions as an independent micro battery or microchannel with an output power of around 8-10 microW. The power of a 1 cm² 3D nanobattery is about 150-200mW. 

One of the most important aspects of this new technology compared to existing battery types is its safety. Since each nanobattery is comprised of thousands of small batteries, even if one of these small batteries has a short circuit and fails, the entire battery can keep functioning, lossing only a very small amount of power. Similar damage to a conventional Li-Ion battery could result in substantial loss of power or a complete malfunction and in extreme cases even fire or explosion. 

RFID chip

RFID batteries

2. MEMS batteries - Micro-Electro-Mechanical Systems or MEMS are electronic and mechanical devices several microns in size used in the medical and pharmaceutical industry (for example in implantable medial devices), automotive industry, as parts for projectors, optical switching, printers and various sensors.

Existing thin-film "microbatteries" that may be useful in MEMS systems include planar (2D) thin-film batteries, such as those developed at Oak Ridge National Laboratories by a group led by John Bates. Each planar thin-film battery is composed of successive sub-micron to several micron-thick layers of cathode (LiCoO₂ or LiMn₂O₄), lithium phosphorus oxynitride (LIPON) electrolyte and a lithium or silicon tin oxynitride anode. Planar batteries have cathodes with thicknesses of up to 5 micron, a capacity of 0.133 mAh/cm² and a "geometrical" energy density of 0.28 mAh/cm². These batteries require a large footprint, and therefore are limited in their usefulness for MEMS. The solution developed by the team from Tel Aviv University was to move to 3D thin-film configurations in which the reduction of the footprint area is compensated by an increase in area in the third (height) dimension. In this way the new nanobatteries were able to reach 20-30 times the capacity achieved by previous micro battery designs enabling a whole new range of future MEMS applications. Some 3D microbattery concepts, proposed by other research groups, involve preparation of complicated architectures based on carbon posts or a graphite mesh. This is a challenging task with poor reproducible structures.

Iglo white seismic sensor (Credit: Air Force Association)

Nanobattery interview

 To learn more about the new nanobattery technology developed at Tel Aviv University, TFOT interviewed Professor Diana Golodnitsky and Professor Emanuel Peled. 

Q: Your nanobatteries are described as 3D - what does it mean and what is its significance in comparison to existing batteries?
A: To power most on-chip MEMS devices and microelectronic circuits for extended periods of time the batteries need to contain sufficient active material. However, increasing of the amount of active materials leads to the increase of planar-2D (typical) battery dimensions, which, is inapplicable for microdevices. The higher is the surface area-to-volume ratio, the more energetically effective and powerful will be the battery. Three-dimensional  microbattery (3D-MB) architectures will overcome the size and energy-density deficiency of the conventional 2D designs.  

Schematic presentation of the 3D nanobattery

There were several Eureka moments during the development. These dealt with the first time we succeeded to get conformal coating of Ni onto the non-conductive surface of several thousand glass capillaries, preparation of composite cathodes by a simple electrodeposition, design of high energy semi-3D batteries, etc. 

A: Biomedical in vivo micromachines, integrated microoptoelectronic circuits and microelectromechanical system sensors, imagers, gyroscopes, spacecraft components. Microbatteries can be either integrated on IC (integrated circuit) components or otherwise distributed in important locations on the PCB (printed circuit board) to provide dedicated local power to critical portions of the circuit. 

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SEM micrographs of the MCP coated by layers of Ni (upper row), hybrid polymer electrolyte membrane (middle), and cathode (bottom raw)

Q: Is your battery more secure (i.e., less likely to spontaneously burn or explode) and why?
A: Planar lithium ion batteries are not safe enough (see for example this list of 120 fire / explosion incidents). Our 3D battery consists of over 20,000 holes/ cm². In each one there is a complete lithium ion micro-cell. All these “micro-cells” are connected in parallel.

It is projected that such a multi cell battery will be safer than traditional ones as there is a 10-20 micron insulating wall (coated by a 2 micron nickel film on both sides) between neighboring micro-cells (surrounding each one of them).