KR20210132804A - Single crystal organic radical monomer having electric conductivity and ion conductivity and method for fabricating the same - Google Patents

Abstract

The present invention provides a method for preparing a single crystal of an organic radical monomer having electrical conductivity and ion conductivity, which is capable of producing a single crystal of an organic radical monomer having excellent electrical conductivity and ionic conductivity through a cotton candy process. The method for preparing a single crystal of an organic radical monomer having electrical conductivity and ion conductivity includes the steps of: providing an organic radical monomer powder at a lower end of a reaction vessel having a predetermined height; heating the lower end of the reaction vessel to vaporize the organic radical monomer powder; and moving the vaporized organic radical monomer to an upper end of the reaction vessel, and sublimating the vaporized organic radical monomer into the single crystal of the organic radical monomer.

Description

Single crystal organic radical monomer having electric conductivity and ion conductivity and method for fabricating the same

The present invention relates to a single crystal of an organic radical monomer having electrical conductivity and ionic conductivity and a method for producing the same, and more particularly, excellent electrical and ionic conductivity through the so-called cotton candy process as presented in the present invention. It relates to a single crystal of an organic radical monomer having electrical conductivity and ionic conductivity capable of producing a single crystal of an organic radical monomer having the same, and a method for producing the same.

Recently, research has been conducted to apply a polymer containing neutral radical active groups such as nitroxide (N-O) to energy storage, batteries, and solid-state electronics.

When the concentration of a neutral radical group such as nitroxide (N-O) in the polymer is high, intermolecular or intramolecular charge transfer is actively performed while the chemical structure of the polymer is maintained. Such intermolecular charge transfer or intramolecular charge transfer is a self exchange reduction-oxidation reaction, that is, a reduction reaction and an oxidation reaction cross themselves. The distance between the neutral radicals must be short enough for physical interaction to occur. As is known, when the distance between neutral radicals is within 0.5 nm, the self-exchange oxidation-reduction reaction proceeds smoothly.

Charge transfer due to self-exchange oxidation-reduction reaction imparts electrical conductivity to the polymer. Based on this electrical conductivity property, it can be applied to energy storage, batteries, and solid-state electronics. However, the polymer-based conductive material as described above has a disadvantage in that the process for preparing the polymer is complicated.

Meanwhile, a technique for manufacturing nano- or micro-sized organic crystals is known. Typically, organic crystals can be prepared through a solution process or a gas phase process (see Non-Patent Document 7 and Non-Patent Document 8). The solution process has advantages in that the process is very simple and low-cost, but has disadvantages in that the quality of single crystals is low and the types of organic molecules that can be applied are limited as solubility must be considered. In the case of the vapor phase process, high-quality single crystals can be obtained as they are strongly fixed to the substrate, but the yield is low and a complex process is required.

In addition, although this solution process or vapor phase process is applicable to the crystallization of organic molecules, there is no research result indicating that the solution process or vapor phase process described above is useful for crystallization of an organic radical monomer. There have been no reports of single crystallization of

(Non-Patent Document 1) Joo, Y.; Agarkar, V.; Sung, S. H.; Savoie, B. M.; Boudouris, B. W., A nonconjugated radical polymer glass with high electrical conductivity. Science 2018, 359 (6382), 1391-1395. (Non-Patent Document 2) Reese, C.; Bao, Z., Organic single-crystal field-effect transistors. Materials Today 2007, 10 (3), 20-27. (Non-Patent Document 3) Li, R.; Hu, W.; Liu, Y.; Zhu, D., Micro-and nanocrystals of organic semiconductors. Accounts of chemical research 2010, 43 (4), 529-540. (Non-Patent Document 4) Ji, H.-X.; Hu, J.-S.; Wan, L.-J.; Tang, Q.-X.; Hu, W.-P., Controllable crystalline structure of fullerene nanorods and transport properties of an individual nanorod. Journal of Materials Chemistry 2008, 18 (3), 328-332. (Non-Patent Document 5) Kloc, C.; Simpkins, P.; Siegrist, T.; Laudise, R., Physical vapor growth of centimeter-sized crystals of α-hexathiophene. Journal of crystal growth 1997, 182 (3-4), 416-427. (Non-Patent Document 6) Jiang, H.; Kloc, C., Single-crystal growth of organic semiconductors. MRS bulletin 2013, 38 (1), 28-33. (Non-Patent Document 7) Ye, X.; Liu, Y.; Han, Q.; Ge, C.; Cui, S.; Zhang, L.; Zheng, X.; Liu, G.; Liu, J.; Liu, D., Microspacing in-air sublimation growth of organic crystals. Chemistry of Materials 2018, 30 (2), 412-420 (Non-Patent Document 8) Briseno, A. L.; Mannsfeld, S. C.; Ling, M. M.; Liu, S.; Tseng, R. J.; Reese, C.; Roberts, M. E.; Yang, Y.; Wudl, F.; Bao, Z., Patterning organic single-crystal transistor arrays. Nature 2006, 444 (7121), 913

The present invention has been devised to solve the above problems, and as presented in the present invention, a single crystal of an organic radical monomer having excellent electrical and ionic conductivity through a cotton candy process and a method for producing the same but it has a purpose.

In the single crystal of the organic radical monomer having electrical conductivity and ion conductivity according to the present invention for achieving the above object, two dimers are mirror images, and a head to head dimer or a tail to tail dimer dimer) structure, and dimers are repeatedly stacked (Lamella structure), electrostatic interaction between nitroxide (NO˙) groups and hydrophobic interaction between epoxide groups ) to form a double packing structure.

As the organic radical monomer, gTEMPO may be applied.

The electrical conductivity of the organic radical monomer single crystal is -2.1 x 10 ^-8 S cm ^-1 , and the ionic conductivity of the organic radical monomer single crystal is -5.1 x 10 ^-3 S cm ^-1 .

The method for producing a single crystal of an organic radical monomer having electrical conductivity and ionic conductivity according to the present invention comprises the steps of providing an organic radical monomer powder at the lower end of a reaction vessel having a predetermined height; heating the lower end of the reaction vessel to vaporize the organic radical monomer powder; and moving the vaporized organic radical monomer to the upper end of the reaction vessel, and sublimating the vaporized organic radical monomer into a single crystal of the organic radical monomer.

The lower end of the reaction vessel is maintained at a temperature at which the organic radical monomer is vaporized, and the upper end of the reaction vessel is maintained at a temperature at which the organic radical monomer is sublimed.

The organic radical monomer powder is an organic radical monomer having an epoxide ring.

As the organic radical monomer, gTEMPO may be used.

In the step of heating the lower end of the reaction vessel to vaporize the organic radical monomer powder; in, a reaction vessel is provided so that the lower end of the reaction vessel is immersed in an oil bath, and the oil bath is heated to a temperature at which the organic radical monomer is vaporized. can be heated.

In the step of heating the lower end of the reaction vessel to vaporize the organic radical monomer powder; in the lower end of the reaction vessel is further provided with a stirring device for stirring the organic radical monomer powder, the organic radical monomer powder by rotation of the stirring device can be stirred.

heating the lower end of the reaction vessel to vaporize the organic radical monomer powder; and wherein the vaporized organic radical monomer is moved to the upper end of the reaction vessel, and the vaporized organic radical monomer is sublimed into a single crystal of the organic radical monomer; in the reaction vessel is maintained in a vacuum, an inert gas can be supplied into the reaction vessel have.

By supplying an inert gas into the reaction vessel, the upper end of the reaction vessel can be adjusted to a temperature at which the organic radical monomer is sublimed.

The radical concentration of the organic radical monomer single crystal is maintained up to 92% compared to the radical concentration of the organic radical monomer powder.

A single crystal of an organic radical monomer having electrical conductivity and ionic conductivity according to the present invention and a method for producing the same have the following effects.

An organic radical monomer single crystal having electrical conductivity and ionic conductivity can be prepared. In addition, in preparing the organic radical monomer single crystal, a substrate is not required, and the use of a specific solvent is not required. In addition, it is possible to produce a single crystal of an organic radical monomer under a low temperature condition.

1a is a reference diagram schematically illustrating an apparatus for manufacturing a single crystal of an organic radical monomer and a manufacturing process of a single crystal of an organic radical monomer;
Figure 1b is a photograph showing the gTEMPO single crystal produced over the course of the reaction time.
Figure 1c is an experimental result showing the size and number distribution of gTEMPO single crystals produced over the course of the reaction time.
1d and 1e are X-ray diffraction results for gTEMPO powder and gTEMPO single crystal, respectively.
Figure 1f is a schematic diagram of the gTEMPO single crystal prepared in Experimental Example 1.
Figure 2a is a TGA result showing the change in the weight loss of gTEMPO single crystal according to the temperature.
Figure 2b is an EPR (electron paramagnetic resonance) analysis result showing the radical concentration change between gTEMPO powder and gTEMPO single crystal.
Figure 2c is a UV-VIS analysis result showing the change in the concentration of nitroside radicals between gTEMPO powder and gTEMPO single crystal.
2d is an X-ray photoelectron spectroscopy (XPS) analysis result of a gTEMPO single crystal.
3a and 3b are schematic views of an apparatus for measuring the electrical conductivity and ionic conductivity of a gTEMPO single crystal.
Figure 3c is a comparison result of electrical conductivity before and after a single crystal of gTEMPO monomer.
Figure 3d is a comparison result of conductivity after the addition of gTEMPO single crystal and ions.
3e is a result of resistance change according to temperature after addition of gTEMPO single crystal and ions.
4 is a flowchart for explaining a method for preparing a single crystal of an organic radical monomer having electrical conductivity and ion conductivity according to an embodiment of the present invention.

The present invention provides a technique for a method for preparing a single crystal of an organic radical monomer.

In the present invention, the organic radical monomer single crystal means that an organic radical monomer is single crystallized, and the organic radical monomer single crystal according to the present invention has electrical conductivity and ion conductivity.

Previously, in 'Technology behind the Invention', I have mentioned about the polymer-based conductive material and the technology for manufacturing organic crystals through a solution process or a gas phase process. A polymer-based conductive material can produce a polymer having electrical conductivity, but the use of the polymer leads to complexity in the process. A method of single crystallizing an organic radical monomer through a solution process or a gas phase process may be considered, but there has been no report on a single crystallization method of an organic radical monomer through a solution process or a gas phase process, and the solution process or gas phase process is as described above. As such, it is difficult to secure electrical conductivity, and there are problems in quality, yield, and manufacturing process.

The present invention shows that single crystallization of organic radical monomers is possible.

The present invention proposes a technology for single crystallization of an organic radical monomer through a so-called cotton candy process, and the organic radical monomer single crystal prepared through the cotton candy process has excellent electrical and ionic conductivity.

The reason why the method for producing a single crystal of an organic radical monomer according to the present invention is called a cotton candy process is because the production method is similar to that of cotton candy. As is well known, cotton candy is obtained through a process in which sugar is melted, a process in which molten sugar is vaporized, and a process in which the vaporized sugar is cooled and changed into cotton candy in the form of yarn.

The present invention relates to a process of melting an organic radical monomer, a process of vaporizing the molten organic radical monomer, and sublimation of the vaporized organic radical monomer to obtain a rod-shaped single crystal organic radical monomer. A technique for producing a single crystal of an organic radical monomer through the formation process is presented, and such a manufacturing method has similarities in process to the cotton candy process as described above.

The method for preparing a single crystal of an organic radical monomer according to the present invention has a simple process and a very low manufacturing cost. In terms of the process, a substrate for growing a single crystal is not required in preparation for a solution process and a gas phase process used for manufacturing an organic single crystal, and the use of a specific solvent is not required. In addition, it is possible to produce a single crystal of an organic radical monomer under a relatively low temperature of about 80° C. or less.

The organic radical monomer single crystal prepared by the cotton candy process of the present invention has the following structure.

Two dimers are mirror images, and based on a head-to-head dimer or tail-to-tail dimer structure, these dimers are repeated in a laminated form (Lamella structure) (Fig. see 1f). That is, an electrostatic interaction between nitroxide (N-O˙) groups and a hydrophobic interaction between epoxide groups exist to form a double packing structure.

Hereinafter, a single crystal of an organic radical monomer having electrical conductivity and ionic conductivity according to an embodiment of the present invention and a method for manufacturing the same will be described in detail with reference to the drawings.

Referring to FIG. 4 , a sealed reaction vessel is prepared, and a predetermined amount of organic radical monomer powder is added into the reaction vessel (S401). Then, while maintaining the reaction vessel in a vacuum, an inert gas is injected into the reaction vessel. Here, the vacuum of the reaction vessel and the injection of an inert gas are for controlling the instability of the organic radical monomer and do not necessarily have to be set. In this state, the lower end of the reaction vessel in which the organic radical monomer powder is located is heated to a predetermined temperature.

The present invention prepares a single crystal organic radical monomer having electrical conductivity and ionic conductivity, and the organic radical monomer powder input to the reaction vessel must satisfy two conditions. First, single crystallization must be possible by the cotton candy process of the present invention, and secondly, when forming a single crystal structure, electrical conductivity must be maintained. The organic radical monomer satisfying these conditions has an epoxide ring, and specifically gTEMPO (4-glycidyloxy-2,2,6,6-tetramethylpiperidine-1-oxyl) can be used.

The epoxy ring group of the organic radical monomer plays an important role in single crystallization of the organic radical monomer and imparting conductivity to the organic radical monomer. The epoxide ring regularly arranges the molecules constituting the organic radical monomer in the process of melting, vaporization, and sublimation of the organic radical monomer. It acts to weaken the Van der Walls interaction. The role of the epoxy ring group enables single crystallization of the organic radical monomer and the retention of conductivity of the organic radical monomer single crystal.

Meanwhile, various methods can be used to heat the lower end of the reaction vessel, and in one embodiment, the lower end of the reaction vessel can be heated by heating the oil bath in a state where the lower end of the reaction vessel is immersed in an oil bath. have. As only the lower end of the reaction vessel is selectively heated, the lower end and the upper end of the reaction vessel achieve different temperature states. That is, based on the temperature, the lower end of the reaction vessel is divided into a heating unit, and the upper end of the reaction vessel is divided into a cooling unit.

In the present invention, the reason for setting the temperature conditions at the upper end and the lower end of the reaction vessel differently is to induce sublimation of the organic radical monomer. This will be described later in detail. In addition, the heating temperature of the lower end of the reaction vessel corresponds to the temperature at which the organic radical monomer is vaporized. That is, the lower end of the reaction vessel is preferably heated to a temperature at which the organic radical monomer is vaporized.

As the lower end of the reaction vessel is heated, the organic radical monomer provided at the lower end of the reaction vessel is slowly melted and then vaporized (S402). In order to smoothly progress the melting and vaporization of the organic radical monomer, a stirring device may be further provided inside the lower end of the reaction vessel. In one embodiment, a stirring device rotating in the horizontal direction may be provided inside the lower end of the reaction vessel, and heat transfer may be accelerated by the stirring device to promote melting and vaporization of the organic radical monomer.

The vaporized organic radical monomer is moved toward the upper end of the reaction vessel. As described above, as only the lower end of the reaction vessel is selectively heated, the lower end of the reaction vessel forms a heating unit, whereas the upper end of the reaction vessel forms a cooling unit.

As described above, as the upper end of the reaction vessel forms a cooling unit, the organic radical monomer vaporized and moved to the upper end of the reaction vessel is sublimated to a solid state (S403). In this sublimation process, the vaporized organic radical monomer is changed to a single crystal organic radical monomer.

For the sublimation of the vaporized organic radical monomer, the upper end of the reaction vessel needs to be adjusted to a temperature at which the organic radical monomer is sublimed. In an embodiment of the present invention, when gTEMPO is used as the organic radical monomer powder, the vaporization temperature of gTEMPO is about 80°C and the sublimation temperature of gTEMPO is about 30°C. Therefore, when using gTEMPO as the organic radical monomer powder, the heating temperature of the lower portion of the reaction vessel is adjusted to about 80 ℃, the upper end of the reaction vessel needs to be adjusted to about 30 ℃.

As described above, the organic radical monomer powder having an amorphous structure is changed into a single crystal structure having a regular arrangement through melting, vaporization and sublimation processes. In the case where the organic radical monomer having an amorphous structure is changed to an organic radical monomer having a single crystal structure through melting, vaporization and sublimation processes, the epoxy ring group plays an important role as described above. The epoxide ring regularly arranges the molecules constituting the organic radical monomer in the process of melting, vaporization, and sublimation of the organic radical monomer.

In addition, when the organic radical monomer of an amorphous structure is changed to an organic radical monomer single crystal through melting, vaporization and sublimation processes, the radical concentration of the organic radical monomer single crystal is maintained at a high concentration of about 92% compared to the organic radical monomer of an amorphous structure. . The fact that the concentration of radicals is maintained at a high concentration even after single crystallization together with the single crystallization of the organic radical monomer contributes to the high electrical and ionic conductivity characteristics of the single crystal of the organic radical monomer. The radical concentration of the organic radical monomer single crystal can be confirmed through an experimental example to be described later.

In addition, the organic radical monomer single crystal formed by sublimation has excellent electrical conductivity ^{of about 2.1 x 10 -8} S cm ^-1 and high ionic conductivity of ^{5.1 x 10 -3} S cm ^-1. can be checked through

Above, a method for preparing a single crystal of an organic radical monomer having electrical conductivity and ionic conductivity according to an embodiment of the present invention has been described. Hereinafter, the present invention will be described in more detail through experimental examples.

<Experimental Example 1: Preparation of single crystal of organic radical monomer>

After putting 0.5g gTEMPO powder in a 20mL glass container, it was sealed. After immersing the glass container in the oil bath, the oil bath was heated to 80 ℃. At this time, the gTEMPO powder in the glass container was stirred at 400rpm. The gTEMPO powder used in this experiment was 'Joo, Y.; Agarkar, V.; Sung, S. H.; Savoie, B. M.; Boudouris, B. W., A nonconjugated radical polymer glass with high electrical conductivity. Science 2018, 359 (6382), was prepared using the method described in 1391-1395'.

1A schematically illustrates an apparatus for producing a single crystal of an organic radical monomer and a process for producing a single crystal of an organic radical monomer. By heating the glass container, gTEMPO powder (radical powder) is evaporated and moved to the upper part of the glass container, and the vaporized gTEMPO powder is sublimated and crystallized.

Figure 1b is a photograph showing the gTEMPO single crystal produced over the course of the reaction time. It can be seen that the gTEMPO powder is vaporized when 5 minutes have elapsed, and it can be confirmed that the gTEMPO powder is sublimated at the time point of 60 minutes to form a gTEMPO single crystal. It can be seen that the amount of gTEMPO single crystals generated at the time of 300 minutes is increased. Referring to FIG. 1c , it can be seen that the number and size of gTEMPO single crystals increase as the reaction time increases from 5 minutes to 300 minutes.

1d and 1e are X-ray diffraction results for gTEMPO powder and gTEMPO single crystal, respectively. Referring to FIG. 1e, it can be confirmed that a gTEMPO single crystal is produced through the manufacturing method of Experimental Example 1, and when the reaction time of 60 minutes and 300 minutes is applied, it can be seen that the crystallinity of the gTEMPO single crystal is clear.

1f is a schematic diagram of the gTEMPO single crystal prepared in Experimental Example 1, and schematically illustrates that gTEMPO is arranged in a layered single crystal form. Specifically, the gTEMPO single crystal prepared in Experimental Example 1 has the following structure. Two dimers are mirror images, and are based on a head-to-head dimer or tail-to-tail dimer structure, and these dimers are repeated in a stacked form (Lamella structure). That is, an electrostatic interaction between nitroxide (N-O˙) groups and a hydrophobic interaction between epoxide groups exist to form a double packing structure.

<Experimental Example 2: Deterioration characteristics of gTEMPO single crystal>

In order to examine the deterioration characteristics of the gTEMPO single crystal according to the temperature, the temperature of the oil bath was gradually increased under the conditions of Experimental Example 1, and the change in the weight loss of the gTEMPO single crystal was examined. Referring to the TGA test results shown in FIG. 2A , it can be confirmed that the weight of the gTEMPO single crystal is rapidly reduced from the point in time when the temperature of the oil bath exceeds about 81°C.

In addition, the characteristics of the radical concentration change according to the reaction time were examined. As a result of confirming the change in the radical concentration between the gTEMPO powder and the gTEMPO single crystal through EPR (electron paramagnetic resonance) analysis, it can be seen that a concentration change of up to about 8% occurs when the reaction time is 300 minutes as shown in FIG. 2b. In other words, even when a reaction time of 300 minutes is applied, the radical concentration of the gTEMPO single crystal is maintained up to about 92% compared to the radical concentration of the gTEMPO powder. The fact that the radical concentration of the gTEMPO single crystal is maintained at a high value of about 92% compared to the initial value means that the gTEMPO single crystal has excellent electrical and ionic conductivity.

This radical concentration change characteristic is ^{consistent with the nitroxide radical (-NO *} ) concentration change characteristic. ^{Figure 2c shows the change in nitroxide radical (-NO *} ) concentration between gTEMPO powder and gTEMPO single crystal through UV-VIS analysis, and it can be confirmed that the result is similar to the result shown in Figure 2b.

In addition, X-ray photoelectron spectroscopy (XPS) analysis was performed to analyze detailed chemical species of the gTEMPO single crystal. Referring to the XPS analysis result shown in FIG. 2D , the gTEMPO single crystal has three types of nitrogen functional groups: N-O˙ (402.1 eV), +N=O (397.9 eV), and N-OH (403.9 eV). In general, as the oxidation state increases, the binding energy of the oxidized species tends to increase. Therefore, +N=O (397.9 eV), which has a low oxidation state, has the lowest binding energy, followed by N-O˙ (402.1 eV) and N-OH (403.9 eV) in order of binding energy.

<Experimental Example 3: Ion conductivity of gTEMPO single crystal>

The ionic conductivity characteristics of gTEMPO single crystals were investigated. For the experiment, an apparatus as shown in FIGS. 3A and 3B was fabricated. Using a thermal deposition process on a glass substrate, Au electrodes with a thickness of 100 nm are placed 1.5 mm apart, and provided in a gTEMPO single crystal between two Au electrodes (FIG. 3a), and an ion gel on top of the gTEMPO single crystal. injected. In addition, Ag paste was coated between the Au electrode and the gTEMPO single crystal for conductivity. The ion gel is a mixture of triblock copolymer poly(styrene-block methylmethacrylate-block-styrene), ionic liquid 1-ethyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide, and acetonitrile in a weight ratio of 0.7 : 9.3 : 90.0. will be.

Figure 3c is a comparison result of the electrical conductivity of the gTEMPO monomer before and after the single crystal, it can be confirmed that the ^{gTEMPO single crystal has excellent electrical conductivity of about 2.1 x 10 -8} S cm ^-1.

Figure 3d shows the conductivity after implanting ions into the upper gTEMPO single crystal according to Experimental Example 3, and it can be confirmed that the high ionic conductivity of ^{5.1 x 10 -3} S cm ^{-1 is shown.} In addition, FIG. 3e shows the resistance change according to the temperature of the gTEMPO single crystal and the ion-implanted gTEMPO single crystal, and the activation energy after ion addition was 0.22 eV.

Claims (13)

Two dimers form a mirror image, and form a head-to-head dimer or tail-to-tail dimer structure, and the dimers form a laminated structure (Lamella structure).
Electrostatic interaction between nitroxide (NO˙) groups and hydrophobic interaction between epoxide groups exist to form a double packing structure. A single crystal of an organic radical monomer.
The single crystal of claim 1, wherein the organic radical monomer is gTEMPO.
The organic radical monomer single crystal ^{having electrical conductivity and ionic conductivity according to claim 1} , characterized in that the electrical conductivity of the organic radical monomer single crystal ^{is -2.1 x 10 -8} S cm -1.
The organic radical monomer single crystal having electrical conductivity and ionic conductivity according to claim 1, wherein the ionic conductivity of the organic radical monomer single crystal is -5.1 x 10 ^-3 S cm ^-1.
providing an organic radical monomer powder at the lower end of the reaction vessel having a predetermined height;
heating the lower end of the reaction vessel to vaporize the organic radical monomer powder; and
The vaporized organic radical monomer is moved to the upper end of the reaction vessel, and the vaporized organic radical monomer is sublimated into an organic radical monomer single crystal; Way.
According to claim 1, wherein the lower end of the reaction vessel is maintained at a temperature at which the organic radical monomer is vaporized, and the upper end of the reaction vessel is maintained at a temperature at which the organic radical monomer is sublimed. A method for preparing a single crystal of a radical monomer.
The method according to claim 1, wherein the organic radical monomer powder is an organic radical monomer having an epoxide ring.
The method of claim 1, wherein the organic radical monomer is gTEMPO.
The method of claim 1, wherein heating the lower end of the reaction vessel to vaporize the organic radical monomer powder;
Preparation of a single crystal of an organic radical monomer having electrical conductivity and ion conductivity, characterized in that a reaction vessel is provided so that the lower end of the reaction vessel is immersed in an oil bath, and the oil bath is heated to a temperature at which the organic radical monomer is vaporized Way.
The method of claim 1, wherein heating the lower end of the reaction vessel to vaporize the organic radical monomer powder;
A stirring device for stirring the organic radical monomer powder is further provided inside the lower end of the reaction vessel, and the organic radical monomer powder is stirred by the rotation of the stirring device. Way.
The method of claim 1, further comprising: heating the lower end of the reaction vessel to vaporize the organic radical monomer powder; and the vaporized organic radical monomer is moved to the upper end of the reaction vessel, and the vaporized organic radical monomer is sublimed into a single crystal of the organic radical monomer; in,
The reaction vessel is maintained in a vacuum, and an inert gas is supplied into the reaction vessel. Method for producing a single crystal of an organic radical monomer having electrical conductivity and ion conductivity.
The method of claim 11, wherein the upper end of the reaction vessel is controlled to a temperature at which the organic radical monomer is sublimed by supplying an inert gas into the reaction vessel.
The method of claim 1, wherein the radical concentration of the organic radical monomer single crystal is maintained up to 92% compared to the radical concentration of the organic radical monomer powder.

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