Chapter 239 The hearts of capitalists are indeed dark
The key to solving the problem of lithium dendrites lies in a common additive in the electrolyte.
This answer is somewhat unexpected.
After all, the industrial and battery industries have always focused on solving the problem of lithium dendrites on artificial SEI films or lithium salts in electrolytes.
In the opinion of most experts or researchers, these two materials are the key.
If Xu Chuan had not come back with twenty years of vision and experience, Xu Chuan would not have directly set his sights on the electrolyte.
As the saying goes, the more easily neglected a place is, the more likely it is that the most deadly things will breed.
Ethylene carbonate, a material added to almost all lithium-ion batteries, has greatly improved lithium batteries.
However, it may also be the culprit of the lithium dendrite problem.
After replacing the additives in the electrolyte, Xu Chuan conducted a variety of tests on the new batteries in his hands, and also manufactured several new batteries at the same time, using different additive materials to verify his previous judgment.
The final experimental and testing results show that different types of additives will indeed affect the working performance of the new artificial SEI film.
Among them, materials such as ethylene carbonate and alkyl phosphates are particularly serious.
Organic phosphorus and organic fluoride additives are relatively light, and the best-performing fluoroalkyl phosphate can even achieve a Coulombic efficiency of 99.98%.
This data is enough to increase the number of charge and discharge cycles of lithium batteries to four digits and thousands of times.
This is more than double the current standard lithium battery's 500 charge and discharge times.
But at the same time, after replacing ethylene carbonate, the performance of the lithium battery, from battery capacity to charging and discharging speed to the activation performance of the electrolyte, has been significantly reduced.
Among them, the fluoroalkyl phosphate with the best Coulombic efficiency directly reduces the charge and discharge efficiency by about 25%.
And the lower the external temperature, the greater the interference with charging and discharging efficiency. But when the temperature is too high, the instability of the electrolyte will increase.
If the temperature is too high, the battery will bulge and expand.
Although there have been no problems such as spontaneous combustion or explosion in the current tests, Xu Chuan knows that as time and the number of tests increase, these problems will occur if fluoroalkyl phosphate is used instead of ethylene carbonate.
He didn't want the battery he developed to be comparable to a certain star company.
A battery that can explode and spontaneously ignite at any time is of no use no matter how high its capacity is, and its safety performance simply cannot pass the test.
Finding an additive that can replace ethyl carbonate has become the current focus of the Chuanhai Materials Research Institute.
Yu Zhen and Ye Zan's research and development of artificial SEI films and electrolytes temporarily stopped and entered into this work.
In the laboratory, including those doctoral students and master's students who are capable of conducting battery experiments alone, Xu Chuan also arranged experiments in pairs.
Compared with formal researchers, these people still lack a lot of abilities.
But if you can get to the doctoral level, it's basically not too bad.
These people can be trained as the team of Chuanhai Materials Research Institute, and Xu Chuan will not be stingy with his own resources and money.
And for these doctoral and master's students, there is nothing more gratifying than this.
After all, only with experiments can we have data, achieve results, graduate, and have qualifications.
"Boss, these are the experimental results of various groups these days."
In the laboratory, Fan Pengyue handed the information in his hand to Xu Chuan and made some brief statements: "As per your request, seven groups of people in the laboratory conducted experiments on a total of fourteen different ethylene carbonate substitutes. ”
"In the experimental results, the two best materials are fluoroethylene carbonate and trimethylsilyl sulfite."
"These two materials can match the current artificial SEI film to a large extent, and the calculated Coulombic efficiencies after replacement are 99.645% and 99.721% respectively."
“But correspondingly, these two materials also have their own shortcomings after being replaced.”
"For example, after the replacement of fluorinated ethylene carbonate, problems such as reduced charge and discharge efficiency occurred."
"The amount of experimental data is relatively small and can only be used as a preliminary reference. After all, we do not have enough time to conduct complete experiments and tests."
"In addition, some safety tests have not been done."
In the laboratory, Xu Chuan took over the experimental data from Fan Pengyue over the past few days. While listening to his brief description, he looked through the information in his hand.
Since it was discovered in early November that ethylene carbonate is the main cause of lithium dendrites and lithium precipitation problems, the Sichuan and Sea Materials Research Institute has been conducting experiments on it.
Although the time was short, only about twenty days, it was enough for them to experiment with a lot of new materials as long as they had a goal and sufficient manpower and equipment.
Of course, the experiments and testing these days are not perfect and not very formal.
Issues such as the compatibility between materials and battery safety performance testing are not considered.
However, compared to these problems, it is more important to find an additive that can replace ethylene carbonate. As for other things, they can be slowly improved later.
Xu Chuan wants to resolve this issue before going to Sweden to receive the award on December 10th.
After finishing it, I went to receive a Nobel Prize. After returning from Europe, the testing of two protective materials in the nuclear beta radiation energy concentration and conversion into electrical energy project was almost completed.
In this way, he can devote his main energy to nuclear energy projects after the Nobel Prize.
But judging from the current progress, this wish may be difficult to realize.
Among the dozens of additives tested, none of them are very suitable so far, and basically all have problems of one kind or another.
If you put aside the problems of lithium dendrites and lithium evolution, ethylene carbonate is really the best performing additive among all additives.
"Perhaps you can try diluting the concentration of ethylene carbonate? Or find a material to neutralize it?"
Looking at the test report in his hand, another way to solve the problem came to Xu Chuan's mind.
Ethylene carbonate will still be active in future lithium batteries in the future, and it must have its role.
"If a solution can be found to solve the problem of lithium evolution caused by ethylene carbonate, maybe ethylene carbonate has another role."
Suddenly, another term appeared in Xu Chuan's mind.
"Planned scrapping!"
The so-called planned obsolescence refers to a strategy in industry.
That is, the product supplier intentionally designs a limited service life for the product so that the product will be scrapped after a certain period of time.
First appeared on light bulbs. During the Christmas period of 1924, companies such as Osram, Philips, and General Electric gathered in Geneva to form a monopoly group called "phoebus" with the purpose of controlling the life of light bulbs to about 1,000 hours (at that time, the life of light bulbs could reach 2500 hours)
In 1942, the U.S. government took the "phoebus" group to court, accusing the other party of its behavior. In the end, although the agreement was nominally terminated, these companies did not pay any compensation.
More importantly, this alliance proposed life control for ordinary light bulbs, which has continued. To date, the lifespan of most light bulbs is only 1,000 hours.
This was the plan to scrap it at that time.
Then, as time went by, this agreement gradually spread to other products.
For example, batteries and chips in mobile phones and computers; ink cartridges in printers; key buttons in various electrical equipment, etc.
This thing now has the ability to be planned for scrap, even if it is used for a period of time, it will be damaged due to various reasons.
For manufacturers of these things, if a product can be used for a long time in the hands of users, then fewer people will buy a new product after it is launched.
Therefore, in order to introduce new products and expand their own interests, manufacturers will inevitably choose to eliminate old products on the market, because new products face competition from old products to a certain extent.
In lithium-ion batteries, the presence of ethylene carbonate can improve the performance of the lithium battery on the one hand. On the other hand, as the number of charge and discharge cycles increases, the lithium precipitation in the negative electrode will become more serious, which will naturally lead to battery damage.
As long as the impact of ethylene carbonate on lithium-ion batteries needs to be controlled, it can be said that the natural plan is scrapped.
This may be the reason why ethylene carbonate will cause lithium precipitation problems, but it will still exist in future lithium batteries, right?
Xu Chuan has probably figured out where to start to solve the problem of lithium precipitation.
If his guess just now is correct, then the solution to this problem is nothing more than controlling the content of ethylene carbonate or using another additive.
After confirming his suspicion, Xu Chuan immediately started to conduct the experiment again.
To simply verify the method in mind, the method used is very simple, just directly reduce the content of ethylene carbonate in the electrolyte.
In the first experiment, he reduced the ethylene carbonate content in the electrolyte by 20%, made a new lithium-ion battery, and retested it.
One-fifth of the amount is enough to ensure that if the content of ethylene carbonate really affects the lithium evolution of the negative electrode, it will definitely be reflected in the data, and it will be in a larger arc.
The test results were as he had guessed. After reducing the ethylene carbonate content in the electrolyte by 20%, the problem of lithium precipitation in the negative electrode of lithium batteries was greatly improved. The Coulombic efficiency of the battery increased from about 99.91% to the previous one. Improved to 99.95%.
The Coulombic efficiency of 99.95% is enough to ensure that a battery can still maintain more than 80% of its capacity after completing 500 charge and discharge cycles.
This has reached the standard of lithium-ion batteries used on the market today.
"The hearts of capitalists are indeed dark."
Looking at the preliminary test results, Xu Chuan shook his head.
Although it was just a simple test, it was enough for him to confirm that the problem was here.
No wonder ethylene carbonate is one of the causes of lithium dendrites and lithium precipitation problems in lithium-ion batteries. This additive is still widely used in lithium batteries.
It’s not that a more suitable material can’t be found, it’s that it’s the most suitable.
Ethylene carbonate at a certain content can not only increase the performance of lithium batteries, but also automatically execute planned scrapping work to make way for the next generation of products, earning a lot of extra money.
Take mobile phones as an example. The lifespan of a mobile phone battery is about one to three years.
The average selling price of a battery is between 150 and 300 yuan. After excluding all costs, it can bring at least 50 to 150 yuan in net profit.
If one billion people use mobile phones, that is a net profit of 50 billion to 150 billion.
In fact, the consumption of batteries in various countries around the world is much greater than the corresponding number of people. After all, one person can own mobile phones, computers, electric cars, and other electrical appliances that require batteries at the same time.
No wonder that after the lithium dendrite problem is solved in the future, ethylene carbonate will still be widely used in mobile phone batteries.
This huge profit will tempt everyone.
Of course, the performance of ethylene carbonate itself is also excellent enough. Compared with other additives, it is more suitable for this new type of artificial SEI film and can bring greater performance improvements.
The better the battery, the more people will buy it, even if it is more expensive.
And no battery manufacturer would not love such an ‘almost perfect’ additive.
But for consumers, this is a very frustrating thing.
After all, the increase in consumer spending is real, but it can all be avoided.
After determining that reducing the ethylene carbonate content could improve the Coulombic efficiency of the battery, Xu Chuan began to arrange for other researchers in the laboratory to conduct more detailed tests on the batteries in hand according to the standard testing of lithium batteries.
Battery testing is a rather tedious and lengthy process.
It takes a lot of time to go from electrical tests such as overcharge, over-discharge, external short circuit, forced discharge, etc. to mechanical tests such as squeeze, acupuncture, shock, vibration, and drop.
Not to mention anything else, the charge and discharge test alone needs to be done at least 500 times.
IEC stipulates that the standard cycle life test of lithium batteries is: after the battery is discharged to 3.0V/unit at 0.2C, charge it to 4.2V at 1C constant current and constant voltage, with a cut-off current of 20MA. After leaving it aside for 1 hour, it is then discharged to 3.0V at 0.2C ( One cycle) After repeated cycles 500 times, the capacity should be more than 60% of the initial capacity.
In other words, even if the charge and discharge test is performed for twenty hours around the clock, it will take at least twenty days to a month.
However, these are nothing compared to the huge benefits that lithium batteries can bring.
As for himself, he had other plans.
He needed to find a material that could reduce the lithium evolution effect of ethylene carbonate.
Judging from previous experimental results, the content of ethylene carbonate is directly related to the lithium evolution of the negative electrode. Experiments show that the more ethylene carbonate added to the electrolyte, the faster the lithium evolution rate produced by the negative electrode will be.
Reducing the content of ethylene carbonate can indeed weaken the rate of lithium evolution, but it will also cause the overall performance of the battery to decline to a certain extent.
This is what Xu Chuan doesn't want to see.
Therefore, it is also important to find another additive and control it.
Xu Chuan did not give this job to Sichuan-Hai Materials Research Institute.
Perhaps the Chuanhai Institute of Materials can experiment with the required additives bit by bit, but it may take several months or one or two years. For Xu Chuan, this is too slow.
He is going to use his mathematical skills to complete the calculation of this additive!
I haven’t studied mathematics for a while, and I don’t know if my mathematics ability has deteriorated.
(End of chapter)