The richest man starts with black technology

The display shows: using power 2.5W, real-time voltage: 4V, real-time current: 1.6A.

Seeing such data, seeing a small light bulb on.

The laboratory fell silent.

Success comes too suddenly, happiness comes too suddenly.

This experiment proved the success of ionizing bacteria in one fell swoop, and also proved that ionizing bacteria can form small batteries under certain conditions.

What does this experiment mean!

It means that mankind will have a major breakthrough in the field of batteries, which means that more convenient electrical appliances will appear soon.

There are many application prospects for bio-battery, which even the laboratory cannot predict now.

Mo Li asked the members of the team to record this historic moment.

Zhou Xiao was rather calm, the results of the experiment were within his own expectations.

The experiment continued, because the team had to determine what the capacity of the bio-battery was under a standard special test tube.

There are two standards that determine battery performance, one is voltage and the other is capacity.

Everyone looked at Zhou Xiao and waited for the boss to speak.

Zhou Xiao looked at the big screen carefully and said: "There are two issues you should pay attention to, one is the stability of the battery, the other is the application scenario."

"I also stayed up for a few all night, and went to bed, you guys study it hard."

Zhou Xiao glanced at the system. There has been no change in the monopoly value and the disgust value, but he firmly believes that this ionizing bacteria will give the world a huge surprise and even affect human industrial products.

In the next few months, the laboratory conducted detailed research on ionizing bacteria.

The first item is to completely differentiate ionized bacteria and cultivate and propagate them.

Fortunately, the growth environment of ionizing bacteria is not particularly harsh, and they can survive at room temperature in nature. Even if the temperature is relatively low, the heat emitted by ionizing bacteria during metabolism can keep the colony at a suitable temperature.

The second item is to test the electrical capacity of the standard test tube when the ionizing bacteria has no light source and does not decompose any organic matter.

The final data is that in this extreme case, the capacity of the ionized bacteria in a standard test tube can reach 4000mAh.

This capacity is equivalent to the battery capacity of many smart large-screen mobile phones, and even higher than that of Apple mobile phones.

The third item is to test how much electric energy the ionizing bacteria can have, and how much voltage can be provided in a special container.

It is more energy efficient to use a large number of ionized bacteria in a large container to form a single bio-battery, or to use a small bio-battery formed from a piece of special test tube.

The results are quite gratifying.

Under the same number of colonies, the two have similar electrical energy.

However, the stability of the small bio-battery formed by using small special test tubes is higher.

The voltage of a large number of ionized bacteria in a large container to form a giant bio-battery is very unstable and is easily affected by temperature and local concentration of cultured bacteria.

The fourth experiment, the stability of ionized bacteria in different states.

This experiment is very important.

Because the colonies in the special test tube still exist in the culture medium, if it is fine under the fixed condition, the colonies are basically in a stable state in the solution.

But if the test tube is moving or bumping, the colonies in the solution will bump.

When the colony is bumpy, the potential difference in the special test tube will change and the voltage will become unstable.

The voltage is unstable. Even if the bio-battery has 4000mAh, it cannot be used under unstable voltage conditions.

The battery is used far more in a mobile environment than in a stable time, so the unstable voltage causes great distress to the laboratory.

The fifth experiment is to test the survival status of ionizing bacteria.

The so-called survival state is the ability of ionizing bacteria to survive and multiply when the culture medium is sufficient.

The test results found that when the existing ionized bacteria are in sufficient culture medium, they can survive and reproduce better from minus ten degrees to sixty degrees. The life span of ionized bacteria is similar to that of digestive bacteria, about one month.

This test is closely in line with the future use of ionizing bacteria.

The future application scope of ionizing bacteria is certainly not only at homes with constant temperature, but also in the north and south, it may be the cold northeast, or the hot south.

The strong adaptability of ionizing bacteria ensures that its application environment will be very extensive in the future.

The sixth experiment, the continuous power supply capability of ionizing bacteria.

In the previous experiment, I tested the ionizing bacteria under extreme conditions (no sunlight, no organic matter), and the battery capacity of the standard test tube was about 4000mAh.

But in fact, ionizing bacteria is absolutely impossible to never see the sun and never decompose organic matter.

As the progeny heteromorphic bacteria of Chlorobacillus, ionizing bacteria are actually the "relatives" of digestive bacteria. Therefore, ionizing bacteria have the corresponding ability of Chlorothiobacteria and digestive bacteria.

The first ability is to absorb sunlight for photosynthesis. Under the conditions of photosynthesis, ionizing bacteria will supplement their own energy to continuously produce ionization, which is somewhat similar to solar cells.

But there is a question, what is the conversion rate of ionizing bacteria to solar energy?

Currently, most solar cells on the market are divided into two types, monocrystalline silicon and polycrystalline silicon.

The conversion rate of solar energy is about 10%-20%, which constitutes solar panels with a power of about 15-20mWc㎡.

Is this power high?

It's definitely not high.

Take 10 square centimeter solar panels as an example, the power is only 0.15W to 0.2W.

The power of the mobile phone during the call is above 5W.

That is to say, if we ignore the power storage function of the mobile phone battery, and directly supply power to the mobile phone from the solar panel, even if your mobile phone is covered with solar panels, your mobile phone still cannot be turned on.

And what about plants?

The utilization rate of plants to the sun is less than 5%, most of which are around 1%, which is less efficient.

What is the utilization rate of ionizing bacteria to the sun?

After laboratory tests, the utilization rate of ionizing bacteria for solar energy per unit area is much higher than that of existing solar panels, reaching about 30%.

But this does not work either.

If you convert the success rate, spread the ionized bacteria on thin paper, the power of one square centimeter is about 0.04W, and charging 0.00004 degrees in one hour is obviously not enough.

Although ionizing bacteria are more efficient in photosynthesis, they still cannot rely on sunlight alone to power mobile phones and other devices.

The second ability of ionizing bacteria is the ability to decompose organic matter and obtain energy from it.

In the laboratory, it is found that when ionizing bacteria decompose organic matter, it not only decomposes quickly and efficiently, but also absorbs high energy, which can absorb up to 50% of energy.

For example, 10 grams of ordinary biscuit has 45 calories, or 188.36 kJ, which is converted into electricity, which is 0.0523 degrees.

Ionizing bacteria can absorb 50% of the energy, which is 0.026 degrees.

The power consumption of the mobile phone for continuous calls is 5W, and it consumes 0.005 degrees per hour.

10 grams of cookies can be used for continuous phone calls for 5.2 hours.