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There are abundant reserves of silicon. Si and Li can be combined to form a Li4.4Si, which has a theoretical specific energy of 4200mAh/g. That is nearly ten-times higher than that of the lithium-ion battery currently in use. In the present day, silicon materials are used in lithium-ion cells mainly for two reasons. One way is to add nano-silicon to anode materials to form a carbon-silicon anode. To improve the performance, organosilicon compounds can be added to the electrolyte.
The University Alberta created a new generation silicon-based lithium battery
Jillian Biriak and her team at the University of Alberta (Canada) discovered recently that by molding silicon into tiny particles, it can be prevented from breaking.
Nano-silicon can be defined as crystalline particles of silicon that have a diameter less than five nanometers. It is a very important amorphous non-metal. Nano silicon powder is a non-toxic, odorless material with high purity and small particle size. Nano-silicon can have a variety of uses: It can be mixed under high pressure with a diamond to form composite materials that can be cut with, or combined with graphite material to form composite materials made from silicon and carbon. The negative electrode material in lithium-ion cells increases the battery’s capacity. This material can be combined with organic matter to create organic silicon polymer.
The team studied and tested four sizes of nanoparticles of silicon to determine which size would maximize its advantages while minimizing the disadvantages. They are evenly dispersed in a highly conductive graphene-carbon aerogel with nanopores that compensates for the low conductivity silicon.
After multiple cycles of charge and discharge, they found that particles as small as one part per meter showed the most stability. This eliminates the limitations of using silicon for lithium-ion battery. This discovery may lead to the development of new lithium-ion battery generations with a capacity 10 times greater than the current ones. The research findings were published in the journal Materials Chemistry.
The lithium battery industry’s chain of the silicon anode market is worth tens or hundreds of millions of dollars
This research can be applied in many fields, including electric vehicles. The batteries will become lighter, travel further and charge faster. The next step will be to create a method that is faster and cheaper to produce silicon nanoparticles. This will make it easier for industrial production.
Other than new energy vehicles, the need for lithium-ion battery with higher energy and power density is also present in the areas of energy storage and ships. It is now common to use high nickel ternary material as the positive electrode, while silicon or its composites are the most promising materials for the negative electrode.
(aka. Technology Co. Ltd., a trusted global chemical supplier & manufacturer of high-quality nanomaterials & chemicals with over 12 year’s experience. Silicon nanoparticles manufactured by our company are of high purity and have a low impurity level. Contact us if you need to.
The University Alberta created a new generation silicon-based lithium battery
Jillian Biriak and her team at the University of Alberta (Canada) discovered recently that by molding silicon into tiny particles, it can be prevented from breaking.
Nano-silicon can be defined as crystalline particles of silicon that have a diameter less than five nanometers. It is a very important amorphous non-metal. Nano silicon powder is a non-toxic, odorless material with high purity and small particle size. Nano-silicon can have a variety of uses: It can be mixed under high pressure with a diamond to form composite materials that can be cut with, or combined with graphite material to form composite materials made from silicon and carbon. The negative electrode material in lithium-ion cells increases the battery’s capacity. This material can be combined with organic matter to create organic silicon polymer.
The team studied and tested four sizes of nanoparticles of silicon to determine which size would maximize its advantages while minimizing the disadvantages. They are evenly dispersed in a highly conductive graphene-carbon aerogel with nanopores that compensates for the low conductivity silicon.
After multiple cycles of charge and discharge, they found that particles as small as one part per meter showed the most stability. This eliminates the limitations of using silicon for lithium-ion battery. This discovery may lead to the development of new lithium-ion battery generations with a capacity 10 times greater than the current ones. The research findings were published in the journal Materials Chemistry.
The lithium battery industry’s chain of the silicon anode market is worth tens or hundreds of millions of dollars
This research can be applied in many fields, including electric vehicles. The batteries will become lighter, travel further and charge faster. The next step will be to create a method that is faster and cheaper to produce silicon nanoparticles. This will make it easier for industrial production.
Other than new energy vehicles, the need for lithium-ion battery with higher energy and power density is also present in the areas of energy storage and ships. It is now common to use high nickel ternary material as the positive electrode, while silicon or its composites are the most promising materials for the negative electrode.
(aka. Technology Co. Ltd., a trusted global chemical supplier & manufacturer of high-quality nanomaterials & chemicals with over 12 year’s experience. Silicon nanoparticles manufactured by our company are of high purity and have a low impurity level. Contact us if you need to.