KR20140071993A - Mesoporous nanohybrid, preparing method of the same, and photocatalyst including the same - Google Patents

Abstract

The present invention relates to a layered mesoporous nanohybrid, a preparation method thereof, and a photocatalyst including the same. The layered mesoporous nanohybrid of the photocatalyst is formed by self-assembling a metal layered double hydroxide (LDH) nanosheet and a metal nanocluster.

Description

Technical Field [0001] The present invention relates to a mesoporous nanohybrid, a mesoporous nanohybrid, a method for producing the mesoporous nanohybrid, and a photocatalyst comprising the mesoporous nanohybrid,

The present invention relates to a mesoporous layered nanohybrid, a method for producing the mesoporous layered nanohybrid, and a photocatalyst comprising the mesoporous layered nanohybrid.

Solar energy is one of the promising renewable energy sources and can replace fossil fuels and meet the growing global demand for sustainable energy. One of the most effective approaches to harvesting the solar energy is the mineral oil production of H ₂ and O ₂ molecules by semiconductor photocatalysts. Despite much research on this, many of the inorganic photocatalysts developed so far have been found to be highly viscous-inducible because of their large bandgap energy, low light stability, and inadequate bandwidth position for the reduction of protons and the oxidation of oxide ions Not suitable for water splitting.

In order to overcome the drawbacks of these materials, attempts have been made to hybridize the two types of photocatalysts. In one example, a CdS-TiO ₂ hybrid system can harvest visible light using a narrow bandgap CdS component and photo-induced electrons in CdS migrate into a broad bandgap TiO ₂ component . Such electron transfer leads to reduction of electron-hole recombination and improvement of photocatalytic activity of CdS.

As well as hybridization, the formation of nanostructures can provide an alternative way to enhance the photocatalytic activity of semiconductor materials. Many low-dimensional nanostructured semiconductor materials have been designed and studied as photocatalysts for the production of H ₂ or O ₂ gases. Research interest in nanostructured semiconductors has expanded into 2D nanostructured inorganic solids.

As an inorganic analogue to graphene, some exfoliated, laminated metal oxide nanosheets are applicable as photocatalysts for photo-oxidation of organic contaminant molecules and for the optical generation of H ₂ gas. Compared to laminated metal oxides, laminated metal hydroxides such as layered double hydroxides (LDH) have not yet been studied as photocatalysts. For example, there have been studies on polymer electrolytes using layered double hydroxides in a study such as "Nanocomposite polymer electrolyte and its manufacturing method " (Korean Published Patent Application No. 2008-0105587). However, there have been few reports on the use of LDH as a photocatalyst.

On the other hand, improvement of chemical stability and improvement of O ₂ molecule production efficiency are very important in expanding the application field on the LDH. Although Zn-Cr-LDH itself has photocatalytic activity, there is a need to further increase the catalytic activity and improve the chemical stability in order to put the O ₂ molecules into practical use in the light-oil production.

The present invention relates to a mesoporous layered nanohybrid formed by self-assembly by electrostatic attraction between a metal 2D nanosheet and a metal nano-cluster, and a method for producing the mesoporous layered nanohybrid, And a photocatalyst comprising a mesoporous layered nanohybrid.

However, the problems to be solved by the present invention are not limited to the above-mentioned problems, and other matters not mentioned can be clearly understood by those skilled in the art from the following description.

The first aspect of the present invention relates to a nanoclust formed by self-assembling a metal layered double hydroxide (LDH) nanosheet and a metal nanocluster having mutually opposite surface charges, It is possible to provide a mesoporous layered nanohybrid containing a mesopore formed between nanoclusters.

The second aspect of the present invention can provide a photocatalyst comprising the mesoporous layered nanohybrid according to the first aspect of the present invention.

The third aspect of the present invention can provide a method for producing a mesoporous layered nanohybrid, which comprises layer-aligning metal nano-clusters and metal nano-clusters each having a surface charge opposite to each other by self-assembly.

The mesoporous layered nanohybrid formed by the self-assembly of metal layered double hydroxide nanosheets and metal nanoclusters having surface charges opposite to each other has excellent chemical stability and is obtained by O ₂ Lt; RTI ID = 0.0 > photocatalytic activity. ≪ / RTI > The mesoporous layered nanohybrid according to the present invention exhibits a strong absorption of visible light and a significantly reduced photoluminescence signal, showing effective electron coupling between 2D metal layered double hydroxide nanosheets and 0D metal nanoclusters. Self-assembly between the 2D metal nanosheets and the 0D metal nanoclusters leads to the formation of a highly porous laminate structure, which can be controlled by changing the ratio of the laminated metal layered double hydroxide nanosheets to the metal nanoclusters.

The mesoporous layered nanohybrid according to the present invention has excellent photocatalytic activity as compared with pure metal layered double hydroxides, and has excellent activity as a photocatalyst for oxygen generation through water decomposition under visible light irradiation.

In the present invention, the self-assembly of the metal 2D nanosheets in a layered manner not only improves the photocatalytic activity of semiconductors included in the nanohybrid, but also enhances chemical stability and is very effective in the synthesis of novel LDH-based hybrid materials.

1 shows powder X-ray diffraction (XRD) analysis (FIG. 1A) and high resolution transmission electron microscopy (FIG. 1B) results of a nanohybrid according to one embodiment of the present invention.
FIG. 2 shows the result of powder X-ray diffraction analysis after heat treatment of the nanohybrid according to one embodiment of the present invention.
FIG. 3 shows the surface morphology of a nanohybrid according to an embodiment of the present invention, which is analyzed by field emission-scanning electron microscopy (FE-SEM).
FIG. 4 shows a result of analysis of the nanohybrid according to an embodiment of the present invention through an energy-dispersion spectroscopy (EDS) element mapping study.
FIGS. 5A through 5D show results of analysis of a nanohybrid according to an embodiment of the present invention using XANES spectroscopy.
FIG. 6 illustrates the N ₂ adsorption-desorption isotherm (FIG. 6A) and pore size distribution (FIG. 6B) according to the Barrett-Joyner-Halenda (BJH) equation of a nanohybrid according to one embodiment of the present application.
Figures 7A and 7B graphically depict the diffuse reflectance UV-vis spectra of a nanohybrid according to one embodiment of the invention.
Figures 8A and 8B graphically depict the diffuse reflectance UV-vis spectra of a nanohybrid according to one embodiment of the invention.
Figure 9 graphically illustrates time-dependent oxygen production by photocatalytic activity of a nanohybrid according to one embodiment of the present invention.
FIGS. 10A and 10B are graphs illustrating time-dependent oxygen production by photocatalytic activity of the nanohybrid according to one embodiment of the present invention.
FIGS. 11A and 11B are graphs repeatedly measuring time-dependent oxygen production by photocatalytic activity of the nanohybrid according to an embodiment of the present invention.
12 shows results of powder X-ray diffraction (FIG. 12A), field emission-scanning electron microscopy, energy-dispersive spectroscopic element mapping analysis (FIGS. 12B and 12C) of a nanohybrid according to one embodiment of the present invention.

Hereinafter, embodiments and examples of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

It should be understood, however, that the present invention may be embodied in many different forms and is not limited to the embodiments and examples described herein. In the drawings, the same reference numbers are used throughout the specification to refer to the same or like parts.

Throughout this specification, when an element is referred to as "including " an element, it is understood that the element may include other elements as well, without departing from the other elements unless specifically stated otherwise. The terms "about "," substantially ", etc. used to the extent that they are used throughout the specification are intended to be taken to mean the approximation of the manufacturing and material tolerances inherent in the stated sense, Accurate or absolute numbers are used to help prevent unauthorized exploitation by unauthorized intruders of the referenced disclosure. The word " step (or step) "or" step "used to the extent that it is used throughout the specification does not mean" step for.

As used herein, the expression "nanosheet" means a state in which each layer of a metal layered double hydroxide having a layered structure, a metal having a laminated structure, or a metal oxide is dispersed in a single state in a solvent.

As used herein, the term "mesoporous layered nanohybrid" refers to a two-dimensional or three-dimensional mesoporous layer formed by re-layering a metal layered double hydroxide nanosheet and a metal nanocluster through a self- Dimensional porous hybrid body.

The term "house-of-card form" as used herein means an average of 0.1 to 1,000 nm, 0.1 to 500 nm, 1 to 100 nm, or 2 Dimensional structure having a structure including mesopores in the range of 50 nm to 50 nm.

According to a first aspect of the present invention, there is provided a method of fabricating a self-assembled metal layered double hydroxide (LDH) nanotube, which is formed by self-assembling a metal layered double hydroxide (LDH) nanosheet and a metal nanocluster A mesoporous layered nanohybrid comprising a nanosheet and mesopores formed between the metal nanoclusters can be provided.

For example, the metal LDH nanosheets can be easily obtained by chemical peeling of the pure metal LDH material, but are not limited thereto. The resulting metal LDH nanosheets have a sufficient surface charge so they can be a useful material for synthesizing new hierarchical superstructures with many voids.

The formation of the mesoporous layered nanohybrid allows the pores to be maximized because the interlayer pores are formed in the resulting columnar structure by the self-assembly of the 0D nanoclusters inserted between the 2D nanosheets. In particular, since the metal LDH material has a positive charge, metal nanoclusters having negative ions may be more effective in hybridization by electrostatic induction self-assembly, but the present invention is not limited thereto.

For example, the mesoporous layered nanohybrid may include a card cluster structure formed by hybridization of the metal LDH nanosheets and metal nano clusters by self-assembly, but the present invention is not limited thereto. Since the range of the heat induction diffusion is reduced by the edge-to-face interaction due to the card housing structure, the mesoporous layered nanohybrid can exhibit further improved thermal stability and its chemical stability is also improved. For example, the mesoporous layered nanohybrid may include, but is not limited to, having a parallel aligned fringe pattern whose cross-sections are evenly spaced.

The laminated self-assembly has the flexibility of chemical composition without significant change in the crystal structure. This flexibility of the chemical composition without changing the crystal structure is one of the very important properties in controlling the synergistic functionality of the physico-chemical properties and the self-assembled nanohybrid.

According to one embodiment of the present invention, the metal layered double hydroxide nanosheet may include, but is not limited to, a metal layered double hydroxide represented by the following general formula (1).

* [Formula 1]

[M ^II _(1-x) M ^III _x (OH) ₂ ] [A ^{n -} ] _{x /} n .zH ₂ O;

In the general formula 1,

M < ^{II >} is a +2 valent metal cation,

M ^III is a +3 metal cation,

A ^{n -} is an anion selected from the group consisting of hydroxide ions (OH ^- ), nitrate ions (NO ₃ ^- ), PO ₄ ^{3 -} , HPO ₄ ^{2 -} , H ₂ PO ₄ ^-

0 < x < 1,

z is a number of from 0.1 to 15;

The metal layered double hydroxide has a layered structure composed of metal ions of +2 and +3, where +2 is substituted for the metal ion and part of the metal ion is substituted for the +3 -valent ion, so that the metal double hydroxide is positively charged. Therefore, the negative ions (A ^{n -} ) are stabilized in the space between the layers in order to maintain the charge of the whole material as neutral. Such a layered metal double hydroxide can be generally synthesized by a precipitation reaction in an aqueous solution or a precipitation-ion exchange reaction.

According to one embodiment of the invention, wherein the M ^II is comprised of a ^{Ca 2 +, Mg 2 +,} Zn 2 +, Ni 2 +, Mn 2 +, Co 2 +, Fe 2+, Cu 2 + , and combinations thereof comprises a metal cation selected from the group, wherein M ^III is from the group consisting of ^{Fe 3 +, Al 3 +,} Cr 3 +, Mn 3 +, Ga 3 +, Co 3 +, Ni 3 + , and combinations thereof But it is not limited thereto. In one embodiment, the metal layered double hydroxide nanosheets can include (Zn-Cr-LDH) wherein M ^II is Zn and M ^III is Cr, but is not limited thereto.

According to one embodiment of the present invention, the metal layered double hydroxide nanosheet may absorb visible light, but is not limited thereto.

According to an embodiment of the present invention, the metal nanoclusters may be semiconducting, but are not limited thereto.

According to an embodiment of the present invention, the metal nanoclusters may include polyoxometalate (POM) having a surface negative charge, but the present invention is not limited thereto. In particular, the nanoclusters of the polyoxometallates have anions and may be suitable for hybridization with metal LDH nanosheets because of their obvious molecular size and various physicochemical properties. Also, the POM nanoclusters have semiconducting properties and useful catalytic activities, and thus the functionality of the mesoporous layered nanohybrid can be controlled through the hybridization process inserted between the metal LDH nanosheets, but the present invention is not limited thereto.

According to one embodiment of the present invention, the polyoxometallate is at least one selected from the group consisting of Ti, Ni, Cu, Zr, Sr, Zn, In, Yr, La, V, Mo, W, Sn, Nb, Mg, Sm, Pd, Ga, and combinations thereof. However, the present invention is not limited thereto.

For example, the polyoxometallate may comprise isopolyoxovanadate (V ₁₀ O ₂₈ ⁶ -) or isopolyoxotungstate (W ₇ O ₂₄ ^6- ), but is limited thereto It is not.

For example, mesoporous layered nanohybrid (ZCW) of Zn-Cr-LDH and isopolyoxotungstate (ZCW) and mesoporous layered nanohybrid of Zn-Cr-LDH and isopolyoxovanadate ) Can exhibit significantly improved visible light-induced O ₂ generating activity at a maximum of about 2.40 mmol / hg and about 1.54 mmol / hg, respectively, but are not limited thereto. For example, mesoporous layered nanohybrid (ZCW) of Zn-Cr-LDH and isopolyoxotungstate (ZCW) and mesoporous layered nanohybrid of Zn-Cr-LDH and isopolyoxovanadate ) when the calcination at 200 ℃ may exhibit improved visible light induced O ₂ generated by each active up to about 2.74 mmol / hg, and about 1.76 mmol / hg. However, without being limited thereto. For example, the mesoporous layered nanohybrid (ZCW) of the Zn-Cr-LDH and isopolyoxotungstate may have an extended gallery height of about 1.06 nm, and the Zn-Cr- The mesoporous layered nanohybrid (ZCV) of LDH and isopolyoxovanadate may have an extended gallery height of about 1.19 nm, but is not limited thereto.

According to one embodiment of the present invention, the mesoporous layered nanohybrid may have a structure of a porous two-dimensional layer structure or a house-of-card form, but the present invention is not limited thereto.

According to one embodiment of the present invention, the mesoporous layered nanohybrid may have photocatalytic activity under visible light irradiation, but the present invention is not limited thereto.

According to one embodiment of the present invention, the mesoporous layered nanohybrid may include, but is not limited to, calcination at about 100 ° C to about 300 ° C. For example, the mesoporous layered nanohybrid may include, but is not limited to, calcination at about 100 ° C to about 300 ° C, at about 100 ° C to about 200 ° C, or at about 200 ° C to about 300 ° C. According to one embodiment, even when the mesoporous layered nanohybrid is calcined at about 200 ° C, the laminated structure of the metal layered double hydroxide nanosheets and the metal nanoclusters is maintained, and even when calcined at about 300 ° C, phase separation does not occur But is not limited thereto.

According to one embodiment of the present invention, the mesoporous layered nanohybrid may include, but is not limited to, those having a thickness of about 1 nm to about 50 nm. For example, the mesoporous layered nanohybrid may have a thickness of from about 1 mm to about 50 mm, from about 1 nm to about 30 nm, from about 1 nm to about 20 nm, from about 1 nm to about 10 nm, from about 2 mm to about 50 mm , About 5 nm to about 50 nm, about 10 nm to about 50 nm, about 20 nm to about 50 nm, or about 30 nm to about 50 nm.

According to one embodiment of the present invention, the molar ratio of the metal nanoclusters to the metal layered double hydroxide (LDH) nanosheets may be about 1: 0.1 to about 1: 100, but is not limited thereto. For example, the molar ratio of the metal nanoclusters to the metal LDH nanosheets may be about 1: 0.1 to 100, about 1: 0.1 to 50, about 1: 0.1 to 20, or about 1: 0.1 to 10, But is not limited to. In one embodiment, the molar ratio of the metal nanoclusters to the metal LDH nanosheets may be, for example, the charge balance ratio (POM: Zn-Cr-LDH = 1) between the isopolyoxotungstate and the Zn- : 2.57) or 3-fold polyoxometalate (POM) excess ratio (POM: Zn-Cr-LDH = 1: 7.71) It is not. In another embodiment, the molar ratio of the metal nanoclusters to the metal LDH nanosheets may be, for example, the charge balance ratio (POM: Zn-Cr-LDH = 1) between the isopolyoxovanadate and the Zn- : 1.81) or a triple polyoxometalate (POM) excess ratio (POM: Zn-Cr-LDH = 1: 5.64) It is not.

The second aspect of the present application can provide a photocatalyst comprising a mesoporous layered nanohybrid according to the first aspect of the present application.

The photocatalyst can be usefully used for decomposing organic matters which are a cause of environmental pollution or hydrogen gas or oxygen gas through water decomposition, but the present invention is not limited thereto. The photocatalyst is chemically stable, has a large specific surface area, and has a photocatalytic activity and a visible light activity.

Strong electronic coupling between the metal LDH nanosheets and the metal nanoclusters and formation of a porous structure by self-assembly significantly improve the photocatalytic activity of the mesoporous layered nanohybrid. Particularly, the photocatalytic activity can be improved by increasing the surface area of the reaction site where the photocatalytic reaction can occur by the porous structure, but the present invention is not limited thereto.

According to one embodiment of the present invention, the photocatalyst may absorb visible light, but is not limited thereto.

In one embodiment of the present invention, the photocatalyst may have catalytic activity for water decomposition under visible light irradiation, but is not limited thereto. In another embodiment of the present invention, the photocatalyst may be one which decomposes water under visible light irradiation to generate oxygen, but the present invention is not limited thereto.

The photocatalyst can be used to generate hydrogen gas through decomposition of water or to decompose organic matters causing environmental pollution. The photocatalyst is chemically stable, has a large specific surface area, and has photocatalytic activity and visible light activity.

According to a third aspect of the present invention, there is provided a method for producing a metal-on-insulator semiconductor device, comprising: preparing a metal layered double hydroxide nanosheet dispersion containing a metal layered double hydroxide nanosheet having surface charge; Preparing a metal nanocluster dispersion containing metal nanoclusters having a surface charge opposite to that of the metal layered double hydroxide nanosheets; And forming a mesoporous layered nanohybrid by self-assembling the metal layered double hydroxide nanosheets and the metal nanoclusters by mixing the metal layered double hydroxide nanosheet dispersion and the metal nanocluster dispersion to form a mesoporous layered nanohybrid It is possible to provide a method for producing a nanohybrid.

According to one embodiment of the present invention, the metal layered double hydroxide nanosheet may include a metal layered double hydroxide represented by the following general formula 1, It is not.

[Formula 1]

[M ^II _(1-x) M ^III _x (OH) ₂ ] [A ^{n -} ] _{x /} n .zH ₂ O;

In the general formula 1,

M < ^{II >} is a +2 valent metal cation,

M ^III is a +3 metal cation,

A ^{n -} is an anion selected from the group consisting of hydroxide ions (OH ^- ), nitrate ions (NO ₃ ^- ), PO ₄ ^{3 -} , HPO ₄ ^{2 -} , H ₂ PO ₄ ^-

0 < x < 1,

z is a number of from 0.1 to 15;

The metal layered double hydroxide has a layered structure composed of metal ions of +2 and +3, where +2 is substituted for the metal ion and part of the metal ion is substituted for the +3 -valent ion, so that the metal double hydroxide is positively charged. Therefore, the negative ions (A ^{n -} ) are stabilized in the space between the layers in order to maintain the charge of the whole material as neutral. Such a layered metal double hydroxide can be generally synthesized by a precipitation reaction in an aqueous solution or a precipitation-ion exchange reaction.

For example, the metal layered double hydroxide represented by the general formula 1 may be prepared by: i) coprecipitating an M ^II metal precursor and an M ^III metal precursor in a polar solvent to obtain a compound represented by the general formula [M ^II _(1-x) M ^III _x (OH ) ₂ ] [A ⁿ ] _{x /} n zH ₂ O; And ii) the layered metal double hydroxide salt is reacted with 1-butanol, 1-hexanol, 1-octanol, 1-decanol, CCl _4, xylene (xylene), and formamide; is reacted with at least one member selected from the group consisting of (HCONH ₂ formamide) solvent comprises dissolving in the form of a layered metal double hydroxyl flame having a cationic surface charge .

The coprecipitation step is usually carried out by adding a +2 valent metal salt such as calcium nitrate (Ca (NO ₃ ) ₂ .4H ₂ O) and a +3 valent metal salt such as iron nitrate (Fe (NO ₃ ) ₃ .9H ₂ O) Dissolved in distilled water and adjusted to a pH of 12 ± 0.2 and then stirred at room temperature for 6 hours to 7 days, preferably 1 day to 4 days, to form a layered structure Thereby forming a metal double hydroxide. The remaining unreacted elements can be removed by centrifugation, washing and drying.

The metal layered double hydroxide represented by the general formula (1) can be prepared by subjecting the layered metal double hydroxide salt to 1-butanol, 1-hexanol, (1-octanol), 1- decanol _{(1-decanol), CCl 4} , xylene (xylene), and formamide; is reacted with at least one member selected from the group consisting of (formamide HCONH ₂₎ a solvent having a cationic surface charge And then dissolving in the form of a layered metal double hydroxide (exfoliation). Examples of the solvent include 1-butanol, 1-hexanol, 1-octanol, and the like, as long as they can dissolve the layered metal double hydroxide. , 1-decanol _{(1-decanol), CCl 4} , xylene (xylene), and formamide (HCONH _2; formamide) at least one member selected from the group consisting of a screen can be effectively peeled off and, of which, especially formamide Is most preferable.

According to one embodiment of the invention, wherein the M ^II is comprised of a ^{Ca 2 +, Mg 2 +,} Zn 2 +, Ni 2 +, Mn 2 +, Co 2 +, Fe 2+, Cu 2 + , and combinations thereof comprises a metal cation selected from the group, wherein M ^III is from the group consisting of ^{Fe 3 +, Al 3 +,} Cr 3 +, Mn 3 +, Ga 3 +, Co 3 +, Ni 3 + , and combinations thereof But it is not limited thereto. In one embodiment, the metal layered double hydroxide nanosheets can include (Zn-Cr-LDH) wherein M ^II is Zn and M ^III is Cr, but is not limited thereto.

According to an embodiment of the present invention, the metal nanoclusters may be semiconducting, but are not limited thereto.

According to an embodiment of the present invention, the metal nanoclusters may include polyoxometalate (POM) having a surface negative charge, but the present invention is not limited thereto. In particular, the nanoclusters of the polyoxometallates have anions and may be suitable for hybridization with metal LDH nanosheets because of their obvious molecular size and various physicochemical properties. Also, the POM nanoclusters have semiconducting properties and useful catalytic activities, and thus the functionality of the mesoporous layered nanohybrid can be controlled through the hybridization process inserted between the metal LDH nanosheets, but the present invention is not limited thereto.

According to one embodiment of the present invention, the polyoxometallate is at least one selected from the group consisting of Ti, Ni, Cu, Zr, Sr, Zn, In, Yr, La, V, Mo, W, Sn, Nb, Mg, Sm, Pd, Ga, and combinations thereof. However, the present invention is not limited thereto.

According to one embodiment of the present disclosure, the polyoxometallate may be one comprising isopolyoxovanadate (V ₁₀ O ₂₈ ^6- ) or isopolyoxotungstate (W ₇ O ₂₄ ^{6 -} ). But is not limited thereto.

For example, mesoporous layered nanohybrid (ZCW) of Zn-Cr-LDH and isopolyoxotungstate (ZCW) and mesoporous layered nanohybrid of Zn-Cr-LDH and isopolyoxovanadate ) Can exhibit significantly improved visible light-induced O ₂ generating activity at a maximum of about 2.40 mmol / hg and about 1.54 mmol / hg, respectively, but are not limited thereto. For example, mesoporous layered nanohybrid (ZCW) of Zn-Cr-LDH and isopolyoxotungstate (ZCW) and mesoporous layered nanohybrid of Zn-Cr-LDH and isopolyoxovanadate ) when the calcination at 200 ℃ may exhibit improved visible light induced O ₂ generated by each active up to about 2.74 mmol / hg, and about 1.76 mmol / hg. However, without being limited thereto. For example, the mesoporous layered nanohybrid (ZCW) of the Zn-Cr-LDH and isopolyoxotungstate may have an extended gallery height of about 1.06 nm, and the Zn-Cr- The mesoporous layered nanohybrid (ZCV) of LDH and isopolyoxovanadate may have an extended gallery height of about 1.19 nm, but is not limited thereto.

According to an embodiment of the present invention, the molar ratio of the metal layered double hydroxide to the metal nanocluster may be about 1: about 0.1: about 1: about 100, but is not limited thereto. For example, the molar ratio of the metal nanoclusters to the metal LDH nanosheets may be about 1: 0.1 to 100, about 1: 0.1 to 50, about 1: 0.1 to 20, or about 1: 0.1 to 10, But is not limited to. In one embodiment, the molar ratio of the metal nanoclusters to the metal LDH nanosheets may be, for example, a charge balance ratio between the isopolyoxotungstate and the Zn-Cr-LDH (POM: Zn-Cr-LDH = 1: 2.57), or three times a poly-metal oxo rate (POM) excess ratio (POM: Zn-Cr-LDH -W 7 O 24 6- = 1: 7.71) on the basis of the adjustment of the metal layer to the registered LDH nanosheets But is not limited thereto. In another embodiment, the molar ratio of the metal nano-clusters to the metal LDH nanosheets may be, for example, a charge balance ratio (POM: Zn-Cr-LDH) between the isopolyoxovanadate and the Zn- 1: 1.81), or three times the poly-oxo-metal rate (POM) excess ratio (POM: Zn-Cr-LDH -V 10 O 28 6 - = 1: 5.64) on the basis of to the registered floor adjustment of the metal LDH nanosheets But is not limited thereto.

According to one embodiment of the present invention, the mesoporous layered nanohybrid may include, but is not limited to, calcination at about 100 ° C to about 300 ° C. For example, the mesoporous layered nanohybrid may include, but is not limited to, calcination at about 100 ° C to about 300 ° C, at about 100 ° C to about 200 ° C, or at about 200 ° C to about 300 ° C. According to one embodiment, even when the mesoporous layered nanohybrid is calcined at about 200 DEG C, the laminated structure of the metal LDH nanosheets and the metal nanoclusters is maintained, and even when calcined at about 300 DEG C, phase separation may not occur , But is not limited thereto.

Hereinafter, the present invention will be described in detail with reference to embodiments and drawings. However, the present invention is not limited to these embodiments and drawings.

[ Example ]

[ Manufacturing example ]

Mesoporous  Synthesis of layered nanohybrid

The nitrate form of Zn-Cr-LDH was synthesized by co-precipitation method by methods known in the art. The Zn-Cr-LDH powder was dispersed in formamide to obtain a colloidal suspension of the peeled Zn-Cr-LDH nanosheet. Self-assembled nanohybrid was prepared by dropwise addition of an aqueous solution of POM anions (W ₇ O ₂₄ ^{6 -} and V ₁₀ O ₂₈ ^{6 -} ) to a formamide suspension of Zn-Cr-LDH nanosheets at room temperature. The resultant nanohybrid material was separated by centrifugation, washed with formamide and absolute ethanol, and finally dried at 65 ° C for 24 hours. In order to prevent contamination of the metal LDH material by the carbonate ion, all the manufacturing process in this operation is CO ₂ Lt; / RTI _{> in} an N2 atmosphere. To investigate the effect of the chemical formula on the physicochemical properties of the resulting nanohybrid materials, we used POM / Zn-Cr-LDH hybridized by self-assembly of polyoxometalate (POM) and Zn- Different molar ratios were applied for each nanohybrid. The molar ratio was the charge-balance ratio and the 3-fold excess POM ratio. Obtained self-assembled Zn-Cr-LDH-W _{7 having a} charge-balance ratio (POM: Zn-Cr-LDH = 1: 2.57) and a triple POM excess ratio (POM: Zn-Cr-LDH = 1: O ₂₄ ^{6 -} nanohybrid was represented by a single bar of ZCW-1 and ZCW-2. Self-assembled Zn-Cr-LDH-W ₇ with similar charge-balance ratios (POM: Zn-Cr-LDH = 1: 1.81) and triple POM excess ratio (POM: Zn-Cr-LDH = 1: O ₂₄ ^{6 -} nanohybrid each ZCV -1 and ZCV - was shown by two.

[ Example  One]

Character analysis

The crystal structure of the pure Zn-Cr-LDH and the self-assembled nanohybrid of ZCW and ZCV can be determined by X-ray diffraction (XRD) using Ni-filtered Cu Kα radiation with a Rigaku diffractometer. XRD). The c-axis stacking structure between Zn-Cr-LDH and POM is characterized by high resolution-transmission electron microscopy (HR-TEM) / selected area-electron diffraction (SAED) (JEM 2100F) microscope at a voltage of 200 kV using analytical (HR-TEM / SAED) analysis. For HR-TEM measurements, powder nanohybrid samples were fixed in epoxy resin and cut by ultramicrotome. The surface morphology and elemental distribution of the nanohybrid were investigated by field emission-scanning electron microscopy (FE-SEM, Jeol JSM-6700F) equipped with energy-dispersive spectrometry (EDS) . The X-ray absorption near edge structure (XANES) analysis was performed at beamline 7C of the Pohang Accelerator Laboratory (PAL) in Korea. The XANES data herein was collected at room temperature in a transmission mode using gas-ionization detectors. Here, the spectra at Zn K-edge, Cr K-edge, WL ₃ -edge and V K-edge were calibrated by simultaneously measuring the spectra of Zn, Cr, W, or V metal. The pore structure and surface area of the nanohybrid of the present application were measured using a gas sorption analyzer (ASAP 2020) at N ₂ Adsorption-desorption isotherms (N ₂ adsorption-desorption isotherms) were measured to determine volumetrically. Prior to adsorption measurements, all samples were degassed at 150 ° C for 4 hours in a vacuum of less than 10 ^-3 Torr. The optical properties of the nanohybrid were investigated using a diffuse reflectance UV-vis spectrometer (Sinco S-4100 with an integrator with a spectroscopic diameter of 60 mm). BaSO ₄ was used as a reference for diffuse reflection UV-vis spectra. The photoluminescence (PL) spectrum was measured using a Perkin-Elmer LS55 fluorescence spectrometer. The chemical composition of these nanohybrids was analyzed using inductive coupled plasma (ICP, Shimazu ICPS-5000) and elemental CHNS analysis (CE-Instruments-EA-1110). 10 mg of the nanohybrid powder was dispersed in 20 ml of water in a Pyrex reaction cell using a magnetic stirrer and then 0.01 M AgNO ₃ was added as a sacrificial reagent to measure the oxygen gas produced by the photocatalyst . The head space of the reactor was sealed with a sealed silicon stopper and the photocatalyst suspensions were completely degassed using argon gas for 0.5 hour. A 450 W Xe arc lamp (Newport) was used as the light source. Light was passed through a 10 cm IR water filter and a cut-off filter (?> 420 nm for visible-light illumination) and then aimed at the reactor. The light intensity of the oxygen generating reaction was uniform up to 8 × 8 inches, and a Si solar cell (Mono-SiCKG filter; Certificate No. C-ISE269) was used up to about 1.5 SIL Adjusted. During O ₂ evolution, the reactor and the entire assembly were maintained in an environment where argon flowed. The amount of O ₂ generated was measured after every hour by injecting 100 μl of the reactor headspace gas into on-line gas chromatography (GC, Shimadzu GC-2014).

[ Example  2]

powder XRD  And HR - TEM  analysis

FIG. 1A shows the powder XRD pattern of self-assembled ZCW and ZCV nanohybrids compared to the powder XRD pattern of pure Zn-Cr-LDH. (A) is a pure Zn-Cr-LDH, (b) is a ZCV-1 nanohybrid, -2 nano hybrid. Formation of the nitrate form on the beating Zn-Cr-LDH lattice parameters with a = 0.308 and c = 0.890 nm was confirmed by XRD results according to the present invention. Like the pure Zn-Cr-LDH, all of the nanohybrids according to the present invention exhibited a series of well-defined ( 001 ) Bragg reflections at low 2 &thetas; without any impurity peak. This represents the formation of single-layered ordered nanofibers of Zn-Cr-LDH nanosheets and POM nanoclusters. These results suggest flexibility in the columnar structure of the LDH nanosheets with POM and the chemical composition of the hybrid material according to the present invention. According to the least-squares fitting analysis, the prepared ZCV and ZCW nanohybrid had an extended gallery height of 1.19 nm and 1.06 nm, respectively, which is the sum of the Zn-Cr-LDH nanosheet thickness and the size of the POM Well agreed. The gallery height of 1.19 nm coincided with the isopolyoxovanadate (V ₁₀ O ₂₈ ^{6 -} ) orientation with the C2 axis parallel to the brucite layer (Fig. 1a (a) and (b)). In the case of isopolyoxotungstate (W ₇ O ₂₄ ^6- ), the gallery height was determined by a method similar to the structure reported previously by anion exchange: W ₇ O ₂₄ ^6- nano whose C2 axis is oriented perpendicular to the brucite layer (1.06 nm) corresponding to the cluster ((c) and (d) in FIG. 1A).

CHNS elemental analysis and ICP spectroscopy clearly demonstrated the carbonate free composition of the self-assembled nanohybrids of ZCV and ZCW, which demonstrated that ZCW-1, ZCW-2, ZCV-1, and ZCV- _{Zn 0 .67 Cr 0 .32 (OH} ) 2 · 0.053 (W 7 O 39) · H 2 O, Zn 0.63 Cr 0.36 (OH) 2 · 0.060 (W 7 O 39) · 0.6H 2 O, Zn 0. ₆₆ Cr _{0 .33} (OH) to _{2 · 0.056 (V 10 O 28} ) · 0.9H 2 O, and _{Zn 0 .63 Cr 0 .36 (OH} ) 2 · 0.061 (V 10 O 28) · 0.5H 2 O Respectively. Among the nanohybrids according to the present invention, the ZCV nanohybrids exhibited stronger and sharper ( 001 ) XRD peaks ((b) and (c) in FIG. 1a), which showed excellent c-axis alignment in these nanohybrids. In contrast, broader and more diffused ( 001 ) XRD peaks ((c) and (d) in FIG. 1a) were observed for the ZCW nanohybrid, indicating a short range c-axis alignment of the Zn- Respectively. Such a short range laminate structure of ZCW was shown to be due to the weak stability of the W ₇ O ₂₄ ^{6 -} POM nanoclusters in the chemical environment used for the synthesis of the ZCW nanohybrid. According to the ( 001 ) basal diffraction peaks, all nanohybrids have a hexagonal Zn-Cr-LDH structure surface An XRD peak appeared at a high 2 ? = 60 占 corresponding to the Bragg reflection 110 , and a large diffracted hump at 2 ? = ~ 32-42 degrees appeared, which leads to a disordered laminate structure of the nanosheets It was reflected. 2 θ = 60 ° plane reflection shows clearly the intactness of the inherent in-plane structure of Zn-Cr-LDH nanosheets after hybridization with POM. Column-shaped self-assembly and house-of-card structure formation due to lamination in the ZCW (Figure 1b) and ZCV (Figure 1b (g)) nanohybrid Respectively. As shown in FIG. 1 b (f), the cross-sectional view of the ZCW-1 nanohybrid exhibits a fringe pattern of evenly spaced parallel-aligned dark lines. These lattice fringes corresponded to Zn-Cr-LDH nanosheets with a distance between two consecutive fringes of ~ 1.0 nm. A similar fringe image was observed for a ZCV nanohybrid with a slightly larger basal spacing of 1.11 nm (Figure 1 (f)). The interlayer spacing of 1.00 nm and 1.11 nm agreed well with the c-axis lattice parameters of the ZCW and ZCV nanohybrid determined by the XRD analysis, respectively. The fringe pattern observed in the HR-TEM showed the formation of the columnar structure of the Zn-Cr-LDH nanosheet containing the corresponding isopolyoxometallate. The observed fringe pattern is common in layered metal oxide nanosheets re-deposited with other nanoparticles. The lower image of FIG. 1B shows an enlarged view of the corresponding HR-TEM fringe image of ZCW and ZCV nanohybrid and their schematic views. No difference was observed in the d-value of columnar self-assembly in chemical composition, which was due to the expulsion of excess POM nanoclusters from the interlayer space of Zn-Cr-LDH during the self-assembly process.

As shown in FIG. 2, the structural change after heat treatment was measured using powder X-ray diffraction (XRD). (a) is a powder XRD pattern after calcining the ZCW-1 nanohybrid at 200 ° C, (c) is a ZCV-1, ZCV-1, (f) is ZCV-2, (g) is ZCW-1, and (h) is a powder XRD pattern after calcination of ZCW-1 nanohybrid at 300 ° C. The XRD pattern (FIG. 2 (a) - (d)) of all the nanohybrids calcined at 200 ° C. shows a signature peak at high 2 θ = 60 ° with the (001) peak, Columnar laminate structure and the in-plane structure of the Zn-Cr-LDH nanosheet were maintained. The XRD patterns (Figs. 2 (e) to 2 (h)) of all the nanohybrids calcined at 300 DEG C showed that one broad hump at 2? = 30-40 DEG and 60-63 DEG Lt; RTI ID = 0.0 > of oxide phase. ≪ / RTI > Subsequent Cr-K edge XANES spectral analysis clearly indicated the start of the oxide phase at 300 < 0 > C. These results clearly showed that the improved structural stability of the nanohybrids and annealed derivatives thereof according to the present invention is due to the allocation of numerous POM nanoclusters during the pillaring process.

[ Example  3]

FE - SEM  And EDS /element Mapping  analysis

Surface morphology studies of the columnar self-assembled nanohybrid were investigated using FE-SEM analysis. Figure 3 is an FE-SEM image of ZCW-1 (a1-a3), ZCW-2 (b1-b3), ZCV-1 (c1-c3), and ZCV- And shows the common surface form of the sheet. Index Nos. 1, 2, and 3 represent the nanohybrid produced, the nano hybrid calcined at 200 캜, and the nano hybrid calcined at 300 캜. These micrographs demonstrate a sheet-like crystalline porous card stock type laminate, indicating that the materials have a characteristic of high porosity. Careful observation of each microscope photograph showed that the ZCV-1 and ZCW-1 Of the nanohybrid The approximate thicknesses were ~ 6-10 nm and ~ 8-13 nm, respectively. 6-13 layers of the Zn-Cr-LDH nanosheets are re-laminated together with the POM nanoclusters to form a pillar-shaped Zn-Cr-LDH nanosheet bundle together with isopolyoxometallate Suggesting that it would bring it. Bundles of layers 6-13 of the Zn-Cr-LDH nanosheets arbitrarily interacted with each other by edge-to-face stacking with a mesoporous card structure.

Recoated edge-to-face interaction could be understood from the relatively small lateral dimension of Zn-Cr-LDH (~ 100 nm) nanosheets, as shown in the HR-TEM analysis. This observation strongly supported that the high surface area of the porous laminate structure of the self-assembled nanohybrid is composed of the card housing structure. Similar origins of the porous card structure have been reported for other types of exfoliated nanosheet aggregates. The heat-treated derivatives of the LDH-POM nanohybrids produced retained a card-type laminate structure, which exhibited the high thermal stability of the nanohybrid according to the present invention. It can be understood that the improved thermal stability of the card housing structure is due to the reduced range of heat-induced diffusion due to the maximized edge-to-face interaction.

The specific and uniform distribution of metals and oxygen elements in the ZCV and ZCW nanohybrids and their calcined derivatives was investigated using EDS and element mapping studies. Figure 4 shows the EDS element mapping and FE-SEM image of ZCW-1 (a1-a3), ZCW-2 (b1-b3), ZCV-1 (c1- (Middle). Index Nos. 1, 2, and 3 represent the nanohybrid produced, the nano hybrid calcined at 200 캜, and the nano hybrid calcined at 300 캜. The uniform distribution of zinc, chromium, tungsten, vanadium and oxygen appears in all of the nanohybrids produced, indicating that different kinds of POM nanoclusters in the interlayer gallery space of Zn-Cr-LDH are uniformly distributed without any spatial separation Respectively. All calcined derivatives of similarly prepared nanohybrids exhibited a uniform distribution of zinc, chromium, tungsten, vanadium, and oxygen (Index Nos. 2 and 3) in common, with no phase separation even under heat treatment at 300 < . The possibility of the presence of other cations and anions in repacked self-assembly was investigated by elemental analysis. A negligible amount of nitrate was observed in CHNS analysis of the material according to the present invention for compensate charge neutrality. These experimental results show that the columnar self-assembled nanohybrids of Zn-Cr-LDH using isopolyoxometallate on a microscopic scale and the strong homogeneous distribution of the elements in their heat-treated derivatives and the absence of phase separation Evidence is presented.

[ Example  4]

XANES  Spectroscopy

The oxidation state and symmetry of the zinc, chromium, tungsten, and vanadium ions in the ZCW, ZCV nanohybrid and calcined derivatives thereof are determined by Zn K-edge, Cr K-edge, WL _III -edge, and V K- Edge using XANES analysis. The Zn K-edge XANES spectra of the ZCW, ZCV nanohybrid and calcined derivatives thereof are shown in comparison with pure Zn-Cr-LDH and bulk ZnO in FIGS. 5A to 5D. 5A and 5B are graphs showing the results of a comparison between the prepared nanohybrid (i) ZCV-1, (ii) ZCV-2, (iii) ZCW- -200, (vi) ZCV-2-200, (vii) ZCV-1-300, (viii) ZCV-2-300 calcined at 300 ° C, (ix) ZCW- (xi) ZCW-2-300 and (xii) ZCW-2-300, (xiii) Zn-Cr-LDH, (xiv) ZnO / Cr ₂ (A) Zn K-edge XANES spectrum and (b) Cr K-edge XANES spectrum, which are compared with the reference spectra of CrO ₃ , O ₃ , and (xv) CrO ₃ . (Iii) ZCW-1-200 / ZCV-1, which is calcined at 200 ° C .; (b) ZCW-1 / ZCV- -200, (iv) ZCW-2-300 / ZCV-2-200, (v) ZCW-1-300 / ZCV- (C) WL of the polyoxotungstate, (vii) WO ₂ / VO ₄ , (viii) Na ₂ WO ₄ / V ₂ O ₅ , (ix) WO ₃ / V ₂ O ₃ , _III -edge XANES spectrum and (d) VK-edge XANES spectrum. The Zn K-edge XANES spectrum shows that the position of the edge of this material in the pure Zn-Cr-LDH and the ZCW and ZCV nanohybrid is similar to the position of the edge of the reference ZnO, Respectively. In contrast to the reference ZnO, the ZCW and ZCV nanohybrid exhibited a XANES property that was not well decomposed in the energy range of 9660 eV to 9670 eV, which was identical to that of the pure Zn-Cr-LDH compound. These same XANES characteristics clearly showed that the Zn-Cr-LDH lattice is retained even after hybridization.

Cr K-edge XANES spectral characteristics of Zn-Cr-LDH-POM nanohybrids and calcined derivatives thereof were compared with several reference spectra of FIGS. 5 (b) and 5 (b '). Reference CrO ₃ All of the Zn-Cr-LDH-POM nanohybrid as well as the pure Zn-Cr-LDH are dipole-forbidden 1s → 3d (in contrast to the compounds showing intense pre-edge peaks P) Showed only weak intensity against the free-edge peak corresponding to the transition. This indicates that the Cr ^{3 +} ions in the nanohybrid material are stabilized by octahedral symmetry. There was no significant difference in the spectral characteristics between the pure Zn-Cr-LDH and the prepared Zn-Cr-LDH-POM nanohybrid spectrum, indicating that the LDH lattice was retained after hybridization. Similar spectral characteristics were observed for the Zn-Cr-LDH-POM nanohybrid calcined at 200 ° C, indicating that the Zn-Cr-LDH-POM nanosheets stacked up to 200 ° C were retained. However, after calcination at 300 캜, the pre-edge peak P 'and the main-edge property A became similar to the reference Cr ₂ O ₃ , which indicated the start of oxide phase formation at 300 ° C. Their total spectral characteristic of the probe of the edge spectrum is a Zn-Cr-LDH-POM nano hybrid calcination at 300 ℃ a standard Cr ₂ O ₃ - FIG. 5 (b) and (b '), as shown in landscape , Demonstrating that the local structure near the chromium is different for all compounds, even after calcination at 300 ° C.

Similarly, the WL _III -edge XANES spectra of the ZCW nanohybrid are shown in FIG. 5c with the spectra of reference WO ₂ , Na ₂ WO _3, WO ₃ , and ammonium polyoxotungstate. The entire material according to the present invention showed broad and strong white-line peaks near the 10210 eV corresponding to the 5d unoccupied state from the dipole-allowed level 2s level. Considering the fact that the W 5d orbitals are separated into t _2g (or e) and e _g (or t ₂ ) orbits under the octahedral (or tetrahedral) crystal field, the broad peak A observed for the tungsten compound according to the present invention is 2s → 5dt _2g (or 5d _e ) and 2s → 5d _eg (or 5d _t2 ) transition. Since the crystal field of tetrahedron symmetry is weaker than that of the octahedron, the tetrahedron WO ₄ Standard Na ₂ WO ₄ .H ₂ O showed a narrower full-width-at-half-maximum (FWHM) for peak A than reference WO ₃ with WO ₆ octahedral units. ZCW all nanohybrid the sides is eotneunde indicate a wider half-value width than the _{Na 2 WO 4 · H 2 O} (FWHM), which W ₇ O ₂₄ ⁶ in ZCW ^- shows the octahedral symmetry of the nanoclusters is maintained. The strong white-line peak near 10210 eV, slightly shifted toward lower photon energy after calcination, clearly showed the valence state of the tungsten ion after calcination at 300 ° C.

The V K-edge XANES spectrum for the ZCV nanohybrid is shown in Figure 5d with the spectra of baseline V ₂ O ₄ , V ₂ O ₅ , and V ₂ O ₃ . The edge energy is slightly higher than the reference V ₂ O ₃ for the ZCV nanohybrid but similar to the baseline V ₂ O ₅ and V ₂ O ₄ . However, the baseline V ₂ O ₄ and V ₂ O ₅ showed significant differences in the transition and morphology of the main-edge characteristics A, B, and C corresponding to the 1s → 4p transition.

A close inspection of the XANES data in accordance with the present invention showed that the overall spectral characteristics of the ZCV nanohybrid were similar to that of the reference V ₂ O ₅ , which was compared to the reference V ₂ O ₄ spectrum. This observation provided important evidence for the stabilization of decavanadate (penta coordination geometry) nanoclusters in columnar self assembled ZCV nanohybrids. Each material according to the present invention exhibited a pre-edge peak P associated with a 1s to 3d transition that was not allowed by the dipole selection rule. Such pre-edge peaks P could be improved because of the variation of V local symmetry from a centrosymmetric octahedron to a non-centrosymmetric tetrahedron by mixing between P and d orbital (distortion). At the same time, one weak pre-edge peak P appears for a reference V ₂ O ₃ having a corundum structure, which is in good agreement with the fact that the vanadium ion is present in the octahedral geometry in this structure. Thus, the intensity of these peaks could provide a sensitive means of investigating the local structure that absorbs vanadium ions. Basal spacing and XANES analysis of the ZCV nanohybrid strongly demonstrated that decanabanate (V ₁₀ O ₂₈ ^{6 -} ) POM nanoclusters were retained within the interlayer gallery space of the ZCV nanohybrid. A similar stabilization of the decavanadate ion has been reported for the case of [Co _0.61 Cr _0.39 (OH) ₂ ] (V ₁₀ O ₂₈ ) _0.065揃 1.35H ₂ O, which is an n -hexylammonium decabanadate [(nC ₆ H ₁₃ NH ₃ ) ₆ (V ₁₀ O ₂₈ ) .2H ₂ O].

[ Example  5]

N ₂  Adsorption / desorption isotherm analysis

The porous aspect of the self-assembled nanohybrid is N ₂ Adsorption-desorption isotherm measurements. Figure 6 (a) ZCV-2, ( b) ZCV-1, (c) ZCW-2, and (d) ZCW-1 N ₂ for the nanohybrid (FIG. 6A) and a pore size distribution curve (FIG. 6B) calculated on the basis of the Barrett-Joyner-Halenda (BJH) equation. All of the nano-hybrids have distinct hysteresis at pp ₀ ^-1 > 0.45 and negligible N ₂ at pp ₀ ^-1 <0.4 Adsorption, indicating that it is a mesoporous nanocluster. Observed data could be classified into Brunauer-Deming-Deming-Teller (BDDT) -type-IV type and H2 type hysteresis loop in IUPAC classification, . This combination of Type IV isotherms and H2 type hysteresis exhibited the characterization of the presence of highly energetic porous materials of adsorption and well aligned pores with narrow and wide zones and connected channels. This provided strong evidence for the presence of an open slit-shaped capillary with a very wide body and narrow and short necks. Formation of the card structure was also observed from FE-SEM and HR-TEM electron micrographs. Heat treatment at 200 ℃ and 300 ℃ reduced the surface area of the entire nanohybrid. The reduction of the surface area of the ZCW-1 and ZCV-1 nanohybrids with lower POM / LDH ratios within the charge balance composition was significantly greater than that of the ZCW-2 and ZCV-2 samples heat treated at elevated temperatures. The relatively smaller surface area reduction of the ZCW-2 and ZCV-2 nanohybrids is due to the surplus amount of POM nanoclusters that are expelled from more columns and stacked assemblies within the LDH gallery. In this nanohybrid, the surplus amount of POM nanoclusters deposited on the surface and deposited in the cavity of the card housing structure provides some additional stability to the card housing structure of the nanohybrid. This provided a better interpretation of ZCW-2 and ZCV-2 compared to ZCW-1 and ZCV-1 nanohybrids, with relatively small surface area and high thermal / mechanical stability.

According to the BET fitting analysis, the self-assembled nanohybrid has an extended surface area of 167, 92, 86, and 74 m ² / g for the ZCV-1, ZCV-2, ZCW-1, and ZCW- appear. These values were larger than those of pure Zn-Cr-LDH (~ 25 m ² / g). The self-assembled nanohybrids of ZCV-1 and ZCW-1 exhibited higher surface area compared to ZCV-2 and ZCW-2, respectively. This finding can be understood as follows. Sample ZCV-1 and ZCW-1 were synthesized so that the charge balance form between the LDH and POM nanoclusters was well-aligned self-assembly. However, for other self-assemblies with higher POM / LDH reactant ratios, excess POM nanoclusters were ejected out of the laminated self-assembly and deposited on the edges and / or surfaces of self-assembly. This leads to shielding and filling of the mesopore / micropore opening. As shown in FIG. 6B, the pore size distribution was measured using the Barrett-Joyner-Halenda (BJH) method. All of the nanohybrids according to the present invention had mesopores having an average diameter of ~ 3-4 nm. Judging from the interlayer spacing of these materials, the formation of mesopores is not due to the intercalation structure, but to the card stacking structure of the nanohybrid crystallites. However, the pore size of all nanohybrids after heat treatment was measured to be about 3 to 3.5 nm.

[ Example  6]

Diffuse reflection Diffuse Reflectance ) UV - vis  And PL  Spectroscopy

In terms of photocatalyst, high stability and efficiency are important for practical application of self-assembled Zn-Cr-LDH-POM nanohybrid as a photocatalyst, so that the electronic structure and optical characteristics of Zn- UV-vis spectroscopy and changes in PL signal. FIG. 7A is a graph showing the relationship between a ZnCr-LDH (solid line), ZCW-1 (dot-dash line), ZCW-2 (point-dot-dash line), ZCV- The diffuse reflection UV-vis spectrum of the hybrid (shown as Kubelka-Munk function (P) of reflection). The pure Zn-Cr-LDH material showed two strong absorption peaks at 2.2 eV and 3.0 eV, corresponding to the d-d transition of trivalent chromium ions. After hybridization with POM nanoclusters, the ZCV nanohybrid showed a change in the optical profile from pure Zn-Cr-LDH, and the absorption edge at 2.3 eV was clearly attributed to vanadate POM nanoclusters. However, the ZCW nanohybrid exhibited strong absorption of visible light with two absorption characteristics similar to pure Zn-Cr-LDH, indicating effective electron coupling between Zn-Cr-LDH nanosheets and POM nanoclusters. The strong absorption of visible light suggests that porous ZCW and ZCV nanohybrids are potential candidates as visible light activated photocatalysts.

The PL signals of ZCV and ZCW nanohybrids such as pure Zn-Cr-LDH are shown in FIG. 7b (Zn-Cr-LDH (solid line), ZCW-1 (dot-dash line), ZCW- Dash line), ZCV-1 (short dash line) and ZCV-2 (dotted line). The PL signal of Zn-Cr-LDH extensively disappeared after hybridization with POM nanoclusters, indicating a significant depression of electron-hole recombination. In both the ZCV and ZCW nanohybrids, the PL intensity was found to be much weaker than that of pure Zn-Cr-LDH, which is responsible for the electron transfer between Zn-Cr-LDH and POM nanoclusters and the spatial separation of electrons and holes This is clearly shown. As a result, inhibition of electron-hole recombination in hybridization was advantageous for improvement of photocatalytic activity. The change in the PL signal was investigated for the heat-treated sample and showed the disappearance of the PL signal with the heat treatment temperature. The change in the PL signal of the calcined nanohybrid was attributed to the formation of oxides. Moreover, the formation of the oxide phase contributes to O ₂ production of the photocatalyst. The effect of heat-treatment on the optical properties of the prepared LDH-POM nanohybrid was investigated using diffuse reflection UV-vis spectroscopy. FIG. 8A is a graph showing the ZCV-1 (dashed line) calcined at 300 DEG C and ZCV-1 (dashed line) calcined at 200 DEG C, (Shown as the Kubelka-Munk function of the reflection (R)) of the diffraction reflected UV-vis spectrum of -2 (point-dot-dash line) ), Diffused Reflection UV for ZCW-2 (dotted line) calcined at 200 占 폚, ZCW-1 (dashed-dotted line) calcined at 300 占 폚, and ZCW-2 -vis spectra (shown as the Kubelka-Munk function of reflection (R) above). As shown in FIGS. 8A and 8B, the ZCV and ZCW nanohybrids heat-treated at 200 ° C exhibited improved optical absorption. The absorption edge of all ZCV nanohybrids appeared in the energy range of ~ 2.4-2.7 eV.

[ Example  7]

Photocatalyst  Active test

The improvement of the photocatalytic activity of the Zn-Cr-LDH-POM nanohybrid was observed in a time-dependent O ₂ By monitoring the production. Comparison of photocatalytic performance between pure Zn-Cr-LDH and nanohybrid showed clearly the advantages of Zn-Cr-LDH-POM self-assembled nanohybrid as an efficient photocatalyst.

As shown in Fig. 9, the O ₂ production of the photocatalyst by the pure Zn-Cr-LDH material is as recently known for this phase. Compared to pure Zn-Cr-LDH, better photocatalytic activity was obtained for all of the nanohybrids according to the present invention. This finding underscores the advantage of the hybridization method of improving the photocatalytic activity of pure Zn-Cr-LDH. The observed activity enhancement in photocatalytic activity can be attributed to effective electron coupling and the expansion of the surface area between the two semiconductors (Zn-Cr-LDH and POM nanoclusters). As evidenced by the results of the PL study, the disappearance of the PL signal after hybridization clearly demonstrated the spatial separation of photoinduced holes and electrons, which resulted in the inhibition of electron-hole recombination. Also, the expansion of the surface area by hybridization contributes to the improvement of photocatalytic activity through the provision of many reactive sites. The remarkable differences between the experimental conditions adopted in the study and the previous literature make it difficult to directly compare the photocatalytic activity of the self-assembled nanohybrid according to the present invention with the previously reported effectiveness of different efficient photocatalysts.

Among the two ZCV nanohybrids, the ZCV-1 nanohybrid has a better (better) quality compared to ZCV-2 (0.8 mmol / hg) due to the higher content of Zn-Cr-LDH constituents and higher surface area than that of ZCV- Performance (1.54 mmol / hg). Furthermore, ZCW-1 nanohybrid the Zn-Cr-LDH and W ₁₂ O ₃₉ ^{6 -} due to the photocatalytic activity synchronization in both nanoclusters showed a better performance of the 2.4 mmol / hg than other nano hybrid material. Among the ZCV and ZCW nanohybrids, the ZCW-1 nanohybrid showed the highest photocatalytic performance of 2.4 mmol / hg. The ZCV-2 and ZCW-2 (2.15 mmol / hg) nanohybrid showed lower photocatalytic performance than their respective other nanohybrid due to the low content of Zn-Cr-LDH constituents and the high content of POM nanoclusters. The surplus amount of the POM nanoclusters will be released from self-assembly and will be deposited on the active sites of the nanohybrid to cause blockage of the pore. The photocatalytic activity of the LDH-POM nanohybrid after heat treatment at 200 ° C and 300 ° C was measured to determine whether the photocatalytic activity remained after the heat treatment. The calcination temperature of 300 ° C was chosen to avoid the formation of ZnCr ₂ O ₄ spines and to separate the ZnO phase above 400 ° C.

9 is a graph showing the emission spectra of visible light (? 420 nm) by (a) pure Zn-Cr-LDH, (b) ZCV-1, (c) ZCV-2, (d) ZCW- ) Is a graph of time-dependent photoproduction of oxygen gas. As shown in FIG. 9, the amount of oxygen produced per hour was increased as compared with POM and Zn-Cr-LDH, which is a raw material after hybridization. The rates of increase in oxygen production were in the order of ZCW-1, ZCW-2, ZCV-1, and ZCV-2.

(A) calcined ZCW-1 at 200 ° C, (b) calcined ZCW-1 at 300 ° C, (c) calcined ZCW-2 at 200 ° C, d) Time-dependent optical generation of oxygen by calcined nanohybrid under visible light emission (?> 420 nm) of calcined ZCW-2 (diamond) at 300 ° C. (B) calcined ZCV-1 (square) at 300 ° C, (c) calcined ZCV-2 at 200 ° C, and (d) calcined ZCV-2 Time-dependent optical generation of oxygen by a calcined nanohybrid under visible light emission (?> 420 nm) of diamond (diamond). According to Fig. 10, the ZCV and ZCW nanohybrid exhibited improved photoactivity after heat treatment at 200 &lt; 0 &gt; C. The heat-treated nanohybrid Among the ZCW-1 and ZCV-1, the nanohybrids heat-treated at 200 占 폚 had the highest O of 2.74 and 1.76 mmol / hg, respectively₂ Generation performance. The improved performance of the ZCV-1 and ZCW-1 nanohybrid after heat treatment at 200 ° C as compared to the nanohydrides annealed at 300 ° C is due to the maintenance of stacked filler assemblies and the opening of micropores, . (B) and (d), respectively, of the nanocomposite when the heat treatment temperature was raised to 300 ° C (Fig. 10a and Fig. 10b, respectively), showed that the columnar self- And the surface area of the nanohybrid is reduced. In careful observation of all photocatalytic activity, O₂ In the first time zone of generation O₂ It was observed that the rate of formation was above average, due to decomposition of water by photocatalytic chemical reaction at the initial time zone and decomposition of water in the intermediate layer.

In order to demonstrate the photocatalytic stability of ZCV and ZCW nanohybrids, O ₂ (ZCV-1 and ZCW-1) photocatalysts of highly active nanohybrid The generation performance was repeatedly measured for successive third order photoreaction cycles. AgNO ₃ was added after each run to compensate for the consumption of the sacrificial reagent. 11 shows that both ZCV-1 and ZCW-1 nanohybrids exhibit only a slight activity reduction during the continuous tertiary cycling and can maintain their photocatalytic activity, and thus the very stable The photocatalytic activity was clearly demonstrated. The observed reduction in photocatalytic activity was consistent with previous reports on its hybrids with pure Zn-Cr-LDH and titanate nanosheets. The fine reduction in photocatalytic activity is interpreted as a result of the reduction / photodeposition of Ag on the catalytic sites of the photocatalyst.

The effect of Ag photoprocessing, the effect of photoreaction on the crystal structure, the morphology of the crystal, and the chemical composition of the ZCV-1 and ZCW-1 nanohybrids were measured using ZCV-1 and ZCW-1 recovered from the photoreactor after the third- Nanohybrid was investigated using structural and microscopic analysis. As shown in Figure 10, X- ray diffraction pattern of ZCW-1 (Fig. 11a) and ZCV-1 (Fig. 11b) is (00l) from the bottom surface 2 θ = 60˚ as the original one Bragg reflection having the peak within the ( basal) reflection peak. The X-ray diffraction pattern of both nanohybrids newly revealed an apparent peak of the Ag metal, which, after repeated photoreaction, retained the original columnar self-assembly and silver (Ag) on the surface of the nanohybrid photocatalyst The photovoltaic Zn-Cr-LDH nanosheets were not damaged. These results clearly emphasize the high light stability of columnar self-assembly.

For the high photocatalytic performance of nanohybrid, the porous card-shaped structure is important. In order to examine the maintenance of the porous card housing structure and the deposition of the Ag metal on the surface catalyst area, the change in morphology and the composition for the photoreaction were confirmed using FE-SEM and EDS mapping analysis (Figs. 12A to 12C). FIG. 12A is a powder XRD pattern of the ZCW-1 (a) and ZCV-1 (b) nanohybrid recovered after the third consecutive photocatalytic activity test, and FIG. 12B shows the ZCW-1 nanohybrid FIG. 12C is an FE-SEM image and EDS element mapping data of the ZCV-1 nanohybrid recovered after the third consecutive photocatalytic activity test. FIG. As shown in FIG. 12, FE-SEM micrographs clearly showed the sheet-like morphology randomly oriented in both the ZCV-1 and ZCW-1 nanohybrids after photoreaction. As shown in Figure 12, the EDS mapping data of the ZCV-1 and ZCW-1 nanohybrid recovered from the photoreactor maintained the hybridized chemical composition of the ZCV-1 and ZCW-1 nanohybrid without specific separation after the photoreaction (Ag) deposition on the surface of both photocatalysts.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments and the exemplary embodiments, and various changes and modifications may be made without departing from the scope of the present invention. It is evident that many variations are possible by those skilled in the art.

Claims (14)

As a visible light-activated photocatalyst containing a mesoporous layered nanohybrid,
The photocatalyst decomposes water under visible light irradiation to generate oxygen,
The mesoporous layered nanohybrid may include,
A step of forming a layered double hydroxide (LDH) nanosheet having surface charges opposite to each other and self-assembling a metal nanocluster and calcining at 100 ° C to 300 ° C,
Wherein the molar ratio of the metal layered double hydroxide nanosheets to the metal nanoclusters includes a charge balance ratio,
And a mesopore formed between the self-assembled metal layered double hydroxide nanosheets and the metal nanoclusters,
Wherein the metal nanoclusters comprise polyoxometalate (POM) having a surface negative charge.
Visible light active photocatalyst.
The method according to claim 1,
Wherein the metal layered double hydroxide nanosheet comprises a metal layered double hydroxide represented by the following general formula 1:
[Formula 1]
[M ^II _(1-x) M ^III _x (OH) ₂ ] [A ^{n -} ] _{x /} n .zH ₂ O;
In the general formula 1,
M &lt; ^{II &gt;} is a +2 valent metal cation,
M ^III is a +3 metal cation,
A ^{n -} is an anion selected from the group consisting of hydroxide ions (OH ^- ), nitrate ions (NO ₃ ^- ), PO ₄ ^{3 -} , HPO ₄ ^{2 -} , H ₂ PO ₄ ^-
0 &lt; x &lt; 1,
z is a number of from 0.1 to 15;
3. The method of claim 2,
Wherein M ^II comprises a metal cation selected from the group consisting of ^{Ca 2 +, Mg 2 +,} Zn 2 +, Ni 2 +, Mn 2 +, Co 2 +, Fe 2 +, Cu 2 + , and combinations thereof , wherein M ^III is ^{+ 3} Fe, Al ^{3 +,} Cr ^3+, Mn ^{+ 3,} Ga ^{+ 3,} Co ^{+ 3,} Ni ^{+ 3,} and comprises a metal cation selected from the group consisting of a combination of Phosphorus, visible light activated photocatalyst.
The method according to claim 1,
Wherein the metal nanocluster has a semiconducting property.
The method according to claim 1,
The polyoxometallate may be at least one selected from the group consisting of Ti, Ni, Cu, Zr, Sr, Zn, In, Yr, La, V, Mo, W, Sn, Nb, Mg, Al, Y, Sc, Sm, Pd, &Lt; / RTI &gt; and combinations thereof.
The method according to claim 1,
Wherein the polyoxometallate comprises isopolyoxovanadate (V ₁₀ O ₂₈ ^6- ) or isopolyoxotungstate (W ₇ O ₂₄ ^{6 -} ).
The method according to claim 1,
Wherein the mesoporous layered nanohybrid has a structure of a porous two-dimensional layer structure or a house-of-card form.
The method according to claim 1,
Wherein the mesoporous layered nanohybrid has a thickness of 1 nm to 50 nm.
Preparing a metal layered double hydroxide nanosheet dispersion containing a metal layered double hydroxide nanosheet having a surface charge;
Preparing a metal nanocluster dispersion containing metal nanoclusters having a surface charge opposite to that of the metal layered double hydroxide nanosheets;
Forming a mesoporous layered nanohybrid by mixing the metal layered double hydroxide nanosheet dispersion and the metal nanocluster dispersion to self-assemble the metal layered double hydroxide nanosheets and the metal nanoclusters; And
And calcining the mesoporous layered nanohybrid at 100 DEG C to 300 DEG C,
The metal nanocluster includes polyoxometalate (POM) having a surface negative charge,
Wherein the molar ratio of the metal layered double hydroxide nanosheets to the metal nanoclusters comprises a charge balance ratio.
(Preparation method of mesoporous layered nanohybrid).
10. The method of claim 9,
Wherein the metal layered double hydroxide nanosheet comprises a metal layered double hydroxide represented by the following general formula (1): &lt; EMI ID =
[Formula 1]
[M ^II _(1-x) M ^III _x (OH) ₂ ] [A ^{n -} ] _{x /} n .zH ₂ O;
In the general formula 1,
M &lt; ^{II &gt;} is a +2 valent metal cation,
M ^III is a +3 metal cation,
A ^{n -} is an anion selected from the group consisting of hydroxide ions (OH ^- ), nitrate ions (NO ₃ ^- ), PO ₄ ^{3 -} , HPO ₄ ^{2 -} , H ₂ PO ₄ ^-
0 &lt; x &lt; 1,
z is a number of from 0.1 to 15;
11. The method of claim 10,
Wherein M ^II comprises a metal cation selected from the group consisting of ^{Ca 2 +, Mg 2 +,} Zn 2 +, Ni 2 +, Mn 2 +, Co 2 +, Fe 2 +, Cu 2 + , and combinations thereof , wherein M ^III is ^{+ 3} Fe, Al ^{3 +,} Cr ^3+, Mn ^{+ 3,} Ga ^{+ 3,} Co ^{+ 3,} Ni ^{+ 3,} and comprises a metal cation selected from the group consisting of a combination of Wherein the mesoporous layered nanohybrid is prepared by a method comprising the steps of:
10. The method of claim 9,
Wherein the metal nanoclusters have a semiconducting property.
10. The method of claim 9,
The polyoxometallate may be at least one selected from the group consisting of Ti, Ni, Cu, Zr, Sr, Zn, In, Yr, La, V, Mo, W, Sn, Nb, Mg, Al, Y, Sc, Sm, Pd, Wherein the metal nanoparticles comprise a metal selected from the group consisting of combinations thereof.
10. The method of claim 9,
Wherein the polyoxometallate comprises an isopolyoxovanadate (V ₁₀ O ₂₈ ^6- ) or an isopolyoxotungstate (W ₇ O ₂₄ ^{6 -} ). Way.

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