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A few days ago, the research team of Dunty University in the United Kingdom published a research result in the academic journal "Current Biology", using green fungi on moldy bread, fixing metal manganese and iron through the biomineralization process, and then carbonizing at a high temperature of 300 °C to obtain electrode materials
that can make lithium-ion batteries and capacitors.
This study is the first to apply the fungal biomineralization process to the manufacture of
electrode materials.
Compared with other manganese oxides in lithium-ion batteries, the manganese oxides of carbide fungi show good cycle stability, and can still maintain more than 90% of the battery capacity
after 200 charge-discharge cycles.
For a long time, the research team at Dundy University has been working on how to use fungi as a model organism commonly used in biological research
.
Manganese oxides of carbonized fungi produced by the biomineralization process are ideal materials
for the manufacture of lithium-ion batteries and capacitors.
Other research aimed at improving the performance of lithium-ion batteries and supercapacitors has focused on the use of alternative materials such as carbon nanotubes and other manganese oxides
.
But researchers at Dundy University have opened up a more sustainable electrode production path through the use of fungi
.
Lei Lixu, a professor of chemistry at Southeast University who has been engaged in battery research for a long time, said that the academic value of this research is greater than the practical value
.
The chemical reaction speed of this research is too slow, the time cost is too high, and there is still a considerable distance
from industrialization.
A few days ago, the research team of Dunty University in the United Kingdom published a research result in the academic journal "Current Biology", using green fungi on moldy bread, fixing metal manganese and iron through the biomineralization process, and then carbonizing at a high temperature of 300 °C to obtain electrode materials
that can make lithium-ion batteries and capacitors.
This study is the first to apply the fungal biomineralization process to the manufacture of
electrode materials.
Compared with other manganese oxides in lithium-ion batteries, the manganese oxides of carbide fungi show good cycle stability, and can still maintain more than 90% of the battery capacity
after 200 charge-discharge cycles.
For a long time, the research team at Dundy University has been working on how to use fungi as a model organism commonly used in biological research
.
Manganese oxides of carbonized fungi produced by the biomineralization process are ideal materials
for the manufacture of lithium-ion batteries and capacitors.
Other research aimed at improving the performance of lithium-ion batteries and supercapacitors has focused on the use of alternative materials such as carbon nanotubes and other manganese oxides
.
But researchers at Dundy University have opened up a more sustainable electrode production path through the use of fungi
.
Lei Lixu, a professor of chemistry at Southeast University who has been engaged in battery research for a long time, said that the academic value of this research is greater than the practical value
.
The chemical reaction speed of this research is too slow, the time cost is too high, and there is still a considerable distance
from industrialization.