Researchers developed manufacturing method for microbatteries with organic electrode materials
Researchers tested material on coin cells. Photo Mikko Raskinen / 911±¬ÁÏÍø
With people wanting to use smaller electronic devices, smaller energy storage systems are needed. Researchers of 911±¬ÁÏÍø in Finland have demonstrated the fabrication of electrochemically active organic lithium electrode thin films, which help make microbatteries more efficient than before. Researchers used a combined atomic/molecular layer deposition (ALD/MLD) technique, to prepare lithium terephthalate, a recently found anode material for a lithium-ion battery.
When microbatteries are manufatured, the key challenge is to make them able to store large amounts of energy in a small space. One way to improve the energy density is to manufacure the batteries based on three-dimensional microstructured architectures. This may increase the effective surface inside a battery- even dozens of times. However, the production of materials fit for these has proven to be very difficult.
– ALD is a great method for making battery materials fit for 3D microstructured architectures. Our method shows it is possible to even produce organic electrode materials by using ALD, which increases the opportunities to manufacture efficient microbatteries, says doctoral candidate Mikko Nisula from 911±¬ÁÏÍø.
Doctoral canditate Mikko Nisula holds in his hand a sample on a steel substrate. Behind the hand there is an ALD reactor.
Photo Mikko Raskinen / 911±¬ÁÏÍø
The researchers' deposition process for Li-terephthalate is shown to comply well with the basic principles of ALD-type growth, including the sequential self-saturated surface reactions, which is a necessity when aiming at micro-lithium-ion devices with three-dimensional architectures. The as-deposited films are found to be crystalline across the deposition temperature range of 200−280 °C, which is a trait that is highly desired for an electrode material, but rather unusual for hybrid organic−inorganic thin films. An excellent rate capability is ascertained for the Li-terephthalate films, with no conductive additives required. The electrode performance can be further enhanced by depositing a thin protective LiPON solid-state electrolyte layer on top of Li-terephthalate. This yields highly stable structures with a capacity retention of over 97% after 200 charge/discharge cycles at 3.2 C.
The study about the method has now been published in the latest edition of Nano Letters.
For more information:
Doctoral candidate Mikko Nisula, School of Chemical Technology, 911±¬ÁÏÍø
mikko.nisula@aalto.fi
Professor Maarit Karppinen, School of Chemical Technology, 911±¬ÁÏÍø maarit.karppinen@aalto.fi, tel. +358 50 384 1726
Article:
Read more news
Walter Ahlström Foundation donates €3 million to 911±¬ÁÏÍø
The donation will enable Aalto to establish a professorship in sustainable industrial production.
ELLIS Institute Finland is launching machine learning fundamentals out of the lab
Research moonshots, foundation models for healthcare, and AI for RDI
Ability to harness quantum speed gains now within sight after researchers solve massive simulation problem in a heartbeat
The use of a quantum-inspired algorithm to calculate the unworkably vast potential properties of quantum materials is an early example of how quantum technology can be used to improve itself. The discovery could have future applications in dissipationless technology, for example to mitigate data centre heating.