PL206177B1 - Crystalline electric cell - Google Patents

Description

Description of the invention

The invention relates to a crystalline electric cell with two electrodes made of the same metal differing in a crystallographic texture, especially copper or silver, in the presence of a chemically inert environment, preferably NaCl, AgNO3 or CuSO4.

Commonly known electrochemical cells that are the source of the EMF are:

• chemical cells (formation), in which the SEM is formed thanks to a chemical reaction taking place in a system of two different electrodes (eg Cu-Zn, Pb-PbO2) immersed in an electrolyte solution.

• concentration cells, where the source of electricity is work related to the equalization of the chemical composition of the electrolyte at the electrodes, resulting from the difference in concentration of the solution. Cells of this type are made of two identical electrodes made of the same metal (e.g. Cu) immersed in solutions containing a different concentration of the depolarizer (e.g. diluted and concentrated CuSO4 solution or solutions with the same concentration of CuSO4, but with different concentrations of dissolved in oxygen).

• differential temperature cells made of electrodes made of the same metal but different in temperature, immersed in an electrolyte solution with a homogeneous chemical composition.

From a practical point of view, these links can be divided as follows:

1. primary cells called batteries, in which the source of electricity are irreversible chemical reactions taking place on the electrodes.

2. secondary cells called batteries, in which, thanks to reversible chemical reactions, it is possible to repeatedly convert chemical energy into electricity (current consumption process), and then electrical energy - supplied from outside the system - into chemical energy (battery charging process).

3. Fuel cells, which are a variant of the primary cell, which function by replenishing the concentration of reactants (i.e. the chemical that acts as fuel and the oxidant) as they wear out due to the current consumption of the cell.

Typical representatives of primary type cells are:

- Daniel's cell made of a zinc (Zn) electrode - immersed in a ZnSO ₄ solution and copper (Cu) - immersed in a CuSO ₄ solution, separated by a porous barrier called an electrolytic key (-Zn / ZnSO4 // CuSO4 / Cu +).

- Lecklanche cell in acidic or basic version, constructed according to the scheme (-Zn / NH ₄ CI / MnO ₂ / C +) or (-Zn / KOH / MnO ₂ / C +). This cell has found practical application in typical consumer electronic devices and is commonly known in the form of a battery

R6, R14 or R20.

The latest generation of the above-mentioned primary cells are based on the Li / I2-PVP electrode system, where iodine is present in the form of a complex with polyvinylpyridine (PVP). These cells have been used in medicine, e.g. to power pacemakers. Among high-energy non-water lithium cells, the cells using lithium perchlorate in propylene carbonate as the electrolyte and lithium-thionyl cells (Li / LiAICI4 + SOCI2 / SOCI2) used to power space probe devices as well as submarines have found the widest application.

The most famous secondary cells include the following batteries:

- lead (Plantego), built according to the scheme: Pb / PbSO ₄ / H ₂ SOyPbO ₂ / Pb, - iron-nickel (Edison): Fe / Fe (OH) ₂ / KOH / Ni ₂ O ₃ / Ni, - nickel- cadmium: Cd / Cd (OH) ₂ / KOH, H ₂ O / NiOH / Ni, - silver-zinc: Zn / KOH / Ag ₂ O ₃ / Ag.

Reversible cells built according to the scheme: MHn / KOH / NiO (OH) have found wide application in cordless telephones, where the MHn anode material uses stable hydrides of non-stoichiometric intermetallic compounds (e.g. LaNi5H6, TiFeH2, Zr2PdH2, etc.), as well as batteries lithium-ion working in the system LiC6 / non-aqueous electrolyte solution / Li1xMn2O4. The principle of operation of the above-mentioned NiMH cells are based on the storage of hydrogen gas in a rare earth alloy during battery charging, and then desorption of hydrogen in the anode process during battery operation.

The operation scheme of a fuel cell is based on the simultaneous course of two electrode reactions: fuel oxidation (e.g. hydrogen H2, methane CH4 or methanol CH3OH) taking place on the negative electrode and reduction of the oxidant taking place on the positive electrode. An example of this type of solution can be a cell built according to the scheme: (-Ni, H2 / NaOH, O2 / NiO, Ni +).

It is also known in electrochemistry that the divergence of the potentials of the same half of the cell with metal electrodes prepared by different methods can reach values of 1-100 mV.

However, in the cell according to the invention, the potential does not come from the difference in the surface preparation technology, but from the differences in the crystallographic structure of the two electrodes.

There have been no known or used electric cells made of two electrodes made of the same metal, but with a different crystallographic texture.

Surprisingly, it turned out that it is possible to construct an electric cell containing two electrodes made of the same metal, differing in their crystallographic texture.

The crystalline electric cell according to the invention is characterized in that it comprises two electrodes made of the same metal differing in their crystallographic texture, especially copper or silver, in the presence of a known chemically inert environment, especially NaCl, AgNO3 or CuSO4.

The crystalline electric cell according to the invention is preferably characterized in that it comprises as electrodes two copper electrodes, in particular with a CU (111) -CU (001) texture, or silver with an Ag (111) -Ag (001) texture.

The crystalline electric cell according to the invention is preferably characterized in that it comprises, as a chemically inert medium, preferably NaCl, AgNO3 or CuSO4, optionally in the presence of hydrogen peroxide.

Surprisingly, it was found that between two electrodes made of the same metal but with different crystallographic texture, in the presence of a chemically inert environment, there is a difference in electric potentials (voltage V). The value of this voltage depends on the type of electrode material, their crystallographic texture, chemical properties of the environment and temperature. The crystallographic orientations of the electrodes, which in the extreme case may be single crystals, should be selected in such a way that the difference of their individual corrosion potentials generates the electromotive force of the cell between them. It was found that the measured electric potential of the electrode in the presence of a chemically active environment significantly depends on the crystallographic orientation of its surface.

The electric cell based on the described discovery was called the Crystalline Electric Cell (Bo-Gus'), and its schematic diagram is shown in the attached drawing. The Bo-Gus' cell can have various configurations, both in terms of electrodes (also formed of different materials) and in terms of the chemical composition of the environment.

Below are examples of the configuration of the Bo-Gus cell according to the invention.

P r z x l a d I.

A link was constructed in which:

- The electrode I was a single crystal of Cu, the active surface of which has a crystallographic orientation (111), - The electrode II was a polycrystalline Cu with an orientation close to random, - Environment: an aqueous solution of 0.5 N NaCI + 0.1N H ₂ O ₂ , - Temperature: 20 ° C

A voltage of about 300 mV was obtained from a cell constructed in this way (electrode area approx. 1 cm ^2). The short-circuit current was in the range of 50 - 150 μA

P r z x l a d II

A link was constructed in which:

- The electrode I was a single crystal of Cu, the active surface of which has a crystallographic orientation (111), - The electrode II was a polycrystalline Cu with an orientation close to random, - Environment: 10% aqueous solution of CuSO ₄ - Temperature: 20 ° C

A voltage of about 70 mV was obtained from a cell constructed in this way (electrode area approx. 1 cm ^2). The short-circuit current was in the range of 215-240 μA

P r x l a d III.

A link was constructed in which:

- The I electrode was a single Ag crystal, the active surface of which has a crystallographic orientation (111),

PL 206 177 B1 - The electrode II was a single crystal of Cu, the active surface of which has a crystallographic orientation (111), - Environment: 0.5 N NaCI + 0.1N H ₂ O ₂ , - Temperature: 20 ° C

A voltage of about 150 mV was obtained from a cell constructed in this way (electrode area approx. 0.8 cm ^2). Short-circuit current approx. 250 μΛ.

Crystallographic texture is a statistical feature of a material having a crystalline structure, manifesting itself in the spatial orientation of individual crystallites (grains, sub-areas, particles). The highest degree of such ordering is shown by single crystals, while the lowest can be attributed to unformed powder formulations.

The stationary mixed (resultant) potential of the electrode, which corresponds to the equality of the anode and cathode currents, is called the corrosive current.

It is known in electrochemistry that the potential discrepancy of the same half-cell with a metal electrode prepared by different methods can reach values of 1-100 mV. However, the effect observed by the authors of the application does not come from the difference in surface preparation technology, but from the difference in the crystallographic orientation of the two electrodes. A voltage of approx. 300 mV was obtained from a relatively small cell (electrode area of approx. 1 cm ² ), which is so high that the observed effect prompts for further research in order to obtain optimal parameters of the Bo-Guś cell. The described cells based on Cu and Ag electrodes become a specific model on the basis of which similar systems can be built using the same observed effect.

Possible applications of Bo-Guś type cells

Various areas of potential application of the cells according to the invention can be indicated, due to the environmental properties similar to solutions found in nature. The most promising is the use of the Bo-Gś cell in medical diagnostics, environmental protection and control of technological processes in the field of food technology.

Claims (3)

Patent claims Crystalline electric cell, characterized in that it comprises two electrodes made of the same metal differing in their crystallographic texture, especially copper or silver, in the presence of a chemically inert environment, preferably NaCl, AgNO3 or CuSO4. 2. Cell according to claim 2. The electrode according to claim 1, characterized in that it comprises as electrodes two copper electrodes, in particular with a CU (111) -CU (001) texture or silver, with an Ag (111) -Ag (001) texture. 3. The electric cell according to claim The process of claim 1, characterized in that the chemically inert medium is NaCl, AgNO3 or CuSO4 with the optional addition of hydrogen peroxide.