**1. Introduction**

Hydroxyapatite (HAp, Ca10(PO4 )6 (OH)2 ) is one of the most usual forms of calcium phosphate and has the similar chemical composition to the mineral phase of bone tissues. Thus, HAp has attracted the interest of the scientific community in the medicine field, material science, and tissue engineering areas in many years. However, due to the special characteristics of this material, HAp is also studied for various applications including fluorescent lamps, fuel cells, and adsorption of harmful metals, as well as catalysts [1]. TiO<sup>2</sup> material was concerned almost 48 years ago. For the first time in 1969, the possibility of solar photoelectrolysis of TiO<sup>2</sup> was demonstrated; the powdered TiO<sup>2</sup> was studied in the 1980s and TiO<sup>2</sup> film photocatalysis

© 2016 The Author(s). Licensee InTech. This chapter is distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. © 2018 The Author(s). Licensee IntechOpen. This chapter is distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

in the 1990s [2]. TiO<sup>2</sup> photocatalysis (in particles or films) has gained much attention because the material has high stability, low cost, and nontoxicity and can be easily fabricated by many processes including precipitation, hydrothermal, sol-gel, plasma, etc. The research on TiO2 /hydroxyapatite photocatalytic materials may derive from researches on TiO<sup>2</sup> /hydroxyapatite composites in medical industry. To achieve biocompatibility, osteoconduction, and osseointegration, the surface of titanium or its alloy, which is used as a permanent implant material, must be modified by developing hydroxyapatite (HAp, Ca10(PO4 )6 (OH)2 ) coating on the surface [3–9]. By inserting TiO2 inner layer between HAp coating and Ti substrate, the adhesion strength of the coating and the substrate increases [10]. The addition of TiO<sup>2</sup> inner layer is expected to reduce a thermal expansion mismatch of the layers, to improve the bonding strength between the HAp layer and Ti substrate, to prevent the corrosion of the Ti substrate, as well as to obtain an abundance of surface hydroxyl and superoxide radical groups, sequentially, to achieve a surface free of cracks and a high adhesion of the modified surface to the substrate [7, 11–13]. The reactions of photocatalysis occur on the surface of TiO<sup>2</sup> ; thus, both the surface properties and the mass transfer of the pollutant and degraded products onto the substrate affect to its photocatalytic activity. HAp, which is known as a material having a large surface area and high adsorption ability, may play the role of a transparent or semitransparent to allow UV and visible radiation to pass through it. In fact, there are numerous materials having larger surface area and higher adsorption ability such as silica gel, zeolite, activated carbon, etc. However, besides these general properties, HAp material was investigated as a support for photocatalysis due to the generation of active superoxide anion radicals (O2 ˙ <sup>−</sup>) under UV irradiation [14]; thus, the TiO<sup>2</sup> /HAp photocatalysts have gained the interest of many scientists. In this chapter, the role of hydroxyapatite in TiO<sup>2</sup> /HAp photocatalytic materials will be analyzed and evaluated to supply a clear view of the composites.

2–10 nm in thickness. This composite material may adsorb contaminants without exposure to

contaminants such as viruses, bacteria, etc. but also decompose these compounds by the photocatalytic process. Hirakura et al. [22] presented that lysozyme (LSZ) and bovine serum albumin (BSA) can be monomolecularly absorbed on HAp by using two types of fibrous crys-

remove of the specific proteins by the absorbing and decomposing under UV irradiation. Thus, the photocatalytic activity for the decomposition of proteins could be controlled with the adsorption on the surface of the nanostructured HAp crystals. The adsorption of BSA

research explained that the adsorption of the acidic protein BSA occurred at Ca2+ sites of the HAp component which contained a large number of pores supporting to the physical

deposition. The aerosol-deposition films almost fully covered the substrate (glass) and are not porous but extremely rough microstructure. The deposited films maintained good adhesion with the substrate, and the film's pencil hardness was over 9H. The aerosol-deposition TiO<sup>2</sup>

40 wt% β-TCP composite film has two different phases distinctly: white regions of β-TCP and

formed by the collision of the accelerated particles with high kinetic energy during deposi-

β-TCP adsorbent crystalline phase show the high photocatalytic activity under both UV and

was also evaluated in the report of Ma et al. [25]. This composite membrane, which was fabricated by a facile two-step approach, involves sol–gel process and calcination was a microporous membrane structure with average 0.8 m pore size, which comprised of Ag-TiO<sup>2</sup>

any structure-directing agent. The result proved the increased photocatalytic activity of the composite results from the combination of adsorption capacity of HAp and the high photo-

ites, especially in atmospheric environment [27–29]. Komazaki et al. [27] collected NO(x) by

Other reports also concerned to the adsorption properties of HAp in the HAp/TiO<sup>2</sup>

/HAp/Al<sup>2</sup>

O3

O3

/HAp composite with mosaic structure via a facile route without

/HAp composite was also presented in the publication of Katayama et al. [23]. The

photocatalyst on exposure to light. As a

http://dx.doi.org/10.5772/intechopen.81092

/HAp materials not only absorb organic

anatase can selectively


117

/HAp

compos-

/HAp composites can be used to pure the air or play the role of

Evaluation of the Role of Hydroxyapatite in TiO2/Hydroxyapatite Photocatalytic Materials


nanocrystallites with nanoscaled β-TCP crystallites

photocatalytic crystallites with a dispersion of

bioceramic composite membrane

disk support. HAp component

provided powerful photocata-

and HAp. The research shows

produces reactive oxygen species

light, and the contaminants are decomposed by TiO<sup>2</sup>

Other literatures show that the photocatalytic TiO<sup>2</sup>

the antimicrobial and antifungal coating with HAp absorber.

, 5–50 nm-sized TiO<sup>2</sup>

composite layer with a thickness of 10 m overlaid on α-Al<sup>2</sup>

acted as a highly efficient bacterial adsorbent, while Ag-TiO<sup>2</sup>

an annular diffusion scrubber coated with a mixture of TiO<sup>2</sup>

that HAp plays the role of adsorption material, while TiO<sup>2</sup>

tion. The films consisting of nano-sized TiO<sup>2</sup>

dark conditions due to adsorption effect of β-TCP.

The adsorption role of the HAp layer in Ag-TiO<sup>2</sup>

.

tals elongated in the c-axis. HAp-nanostructured crystals doping TiO<sup>2</sup>

result, the photocatalytic TiO<sup>2</sup>

Ryu et al. [24] fabricated the TiO<sup>2</sup>

lytic attack toward *E. coli* strains.

Xie et al. [26] fabricated TiO<sup>2</sup>

catalytic activity of TiO<sup>2</sup>

on TiO<sup>2</sup>

adsorption.

dark regions of TiO<sup>2</sup>

#### **2. Hydroxyapatite plays the role of adsorption material in the photocatalytic TiO2 /HAp composites**

Adsorption of biological, organic-chemical molecules on the HAp surface is generally influenced by its physicochemical properties including crystallite size, pore structure, morphology of particles, or coatings [15] which directly depend on the synthesis methods. The synthesis methods of HAp particles include solid-state reaction; sol-gel, plasma, and hydrothermal technique; layer hydrolysis of other calcium phosphate salts; etc. [16–18], while those of HAp coating include sol-gel, chemical vapor deposition, pulsed laser deposition, RF magnetron sputtering, spray pyrolysis, etc. [7, 19, 20]. The choice of a specific method depends on the purpose of research which is synthesis, characteristics, or application of pure HAp or those of TiO2 /HAp composites.

The adsorption property of HAp in the photocatalytic TiO<sup>2</sup> /HAp composites has been reported in many researches. Nonami et al. [21] soaked TiO<sup>2</sup> powder in a simulated physiological solution containing phosphate ions for periods of about 1 h at 37°C. The apatite film with a thickness of approximately 0.7 μm has formed on the approximately 0.3 μm thick TiO<sup>2</sup> layer. The crystals have a plate-like shape, measuring approximately 0.1–0.5 μm in length and 2–10 nm in thickness. This composite material may adsorb contaminants without exposure to light, and the contaminants are decomposed by TiO<sup>2</sup> photocatalyst on exposure to light. As a result, the photocatalytic TiO<sup>2</sup> /HAp composites can be used to pure the air or play the role of the antimicrobial and antifungal coating with HAp absorber.

in the 1990s [2]. TiO<sup>2</sup>

116 Photocatalysts - Applications and Attributes

on the surface [3–9]. By inserting TiO2

<sup>−</sup>) under UV irradiation [14]; thus, the TiO<sup>2</sup>

of many scientists. In this chapter, the role of hydroxyapatite in TiO<sup>2</sup>

**/HAp composites**

The adsorption property of HAp in the photocatalytic TiO<sup>2</sup>

reported in many researches. Nonami et al. [21] soaked TiO<sup>2</sup>

materials will be analyzed and evaluated to supply a clear view of the composites.

Adsorption of biological, organic-chemical molecules on the HAp surface is generally influenced by its physicochemical properties including crystallite size, pore structure, morphology of particles, or coatings [15] which directly depend on the synthesis methods. The synthesis methods of HAp particles include solid-state reaction; sol-gel, plasma, and hydrothermal technique; layer hydrolysis of other calcium phosphate salts; etc. [16–18], while those of HAp coating include sol-gel, chemical vapor deposition, pulsed laser deposition, RF magnetron sputtering, spray pyrolysis, etc. [7, 19, 20]. The choice of a specific method depends on the purpose of research which is synthesis, characteristics, or application of pure HAp or those of

ological solution containing phosphate ions for periods of about 1 h at 37°C. The apatite film with a thickness of approximately 0.7 μm has formed on the approximately 0.3 μm thick TiO<sup>2</sup> layer. The crystals have a plate-like shape, measuring approximately 0.1–0.5 μm in length and

**2. Hydroxyapatite plays the role of adsorption material in the** 

TiO2

(O2 ˙

TiO2

**photocatalytic TiO2**

/HAp composites.

photocatalysis (in particles or films) has gained much attention because

/hydroxy-

) coating

inner

; thus,

/HAp photocatalytic

/HAp composites has been

powder in a simulated physi-

)6 (OH)2

inner layer between HAp coating and Ti substrate, the

/HAp photocatalysts have gained the interest

the material has high stability, low cost, and nontoxicity and can be easily fabricated by many processes including precipitation, hydrothermal, sol-gel, plasma, etc. The research on

apatite composites in medical industry. To achieve biocompatibility, osteoconduction, and osseointegration, the surface of titanium or its alloy, which is used as a permanent implant

layer is expected to reduce a thermal expansion mismatch of the layers, to improve the bonding strength between the HAp layer and Ti substrate, to prevent the corrosion of the Ti substrate, as well as to obtain an abundance of surface hydroxyl and superoxide radical groups, sequentially, to achieve a surface free of cracks and a high adhesion of the modified surface

both the surface properties and the mass transfer of the pollutant and degraded products onto the substrate affect to its photocatalytic activity. HAp, which is known as a material having a large surface area and high adsorption ability, may play the role of a transparent or semitransparent to allow UV and visible radiation to pass through it. In fact, there are numerous materials having larger surface area and higher adsorption ability such as silica gel, zeolite, activated carbon, etc. However, besides these general properties, HAp material was investigated as a support for photocatalysis due to the generation of active superoxide anion radicals

/hydroxyapatite photocatalytic materials may derive from researches on TiO<sup>2</sup>

adhesion strength of the coating and the substrate increases [10]. The addition of TiO<sup>2</sup>

to the substrate [7, 11–13]. The reactions of photocatalysis occur on the surface of TiO<sup>2</sup>

material, must be modified by developing hydroxyapatite (HAp, Ca10(PO4

Other literatures show that the photocatalytic TiO<sup>2</sup> /HAp materials not only absorb organic contaminants such as viruses, bacteria, etc. but also decompose these compounds by the photocatalytic process. Hirakura et al. [22] presented that lysozyme (LSZ) and bovine serum albumin (BSA) can be monomolecularly absorbed on HAp by using two types of fibrous crystals elongated in the c-axis. HAp-nanostructured crystals doping TiO<sup>2</sup> anatase can selectively remove of the specific proteins by the absorbing and decomposing under UV irradiation. Thus, the photocatalytic activity for the decomposition of proteins could be controlled with the adsorption on the surface of the nanostructured HAp crystals. The adsorption of BSA on TiO<sup>2</sup> /HAp composite was also presented in the publication of Katayama et al. [23]. The research explained that the adsorption of the acidic protein BSA occurred at Ca2+ sites of the HAp component which contained a large number of pores supporting to the physical adsorption.

Ryu et al. [24] fabricated the TiO<sup>2</sup> -β-TCP nanocomposite photocatalytic thin films by aerosol deposition. The aerosol-deposition films almost fully covered the substrate (glass) and are not porous but extremely rough microstructure. The deposited films maintained good adhesion with the substrate, and the film's pencil hardness was over 9H. The aerosol-deposition TiO<sup>2</sup> - 40 wt% β-TCP composite film has two different phases distinctly: white regions of β-TCP and dark regions of TiO<sup>2</sup> , 5–50 nm-sized TiO<sup>2</sup> nanocrystallites with nanoscaled β-TCP crystallites formed by the collision of the accelerated particles with high kinetic energy during deposition. The films consisting of nano-sized TiO<sup>2</sup> photocatalytic crystallites with a dispersion of β-TCP adsorbent crystalline phase show the high photocatalytic activity under both UV and dark conditions due to adsorption effect of β-TCP.

The adsorption role of the HAp layer in Ag-TiO<sup>2</sup> /HAp/Al<sup>2</sup> O3 bioceramic composite membrane was also evaluated in the report of Ma et al. [25]. This composite membrane, which was fabricated by a facile two-step approach, involves sol–gel process and calcination was a microporous membrane structure with average 0.8 m pore size, which comprised of Ag-TiO<sup>2</sup> /HAp composite layer with a thickness of 10 m overlaid on α-Al<sup>2</sup> O3 disk support. HAp component acted as a highly efficient bacterial adsorbent, while Ag-TiO<sup>2</sup> provided powerful photocatalytic attack toward *E. coli* strains.

Xie et al. [26] fabricated TiO<sup>2</sup> /HAp composite with mosaic structure via a facile route without any structure-directing agent. The result proved the increased photocatalytic activity of the composite results from the combination of adsorption capacity of HAp and the high photocatalytic activity of TiO<sup>2</sup> .

Other reports also concerned to the adsorption properties of HAp in the HAp/TiO<sup>2</sup> composites, especially in atmospheric environment [27–29]. Komazaki et al. [27] collected NO(x) by an annular diffusion scrubber coated with a mixture of TiO<sup>2</sup> and HAp. The research shows that HAp plays the role of adsorption material, while TiO<sup>2</sup> produces reactive oxygen species under ultraviolet light (UV) illumination such as super oxide (O<sup>2</sup> <sup>−</sup>), hydroxyl radical (OH°), and peroxyhydroxyl radical (HO<sup>2</sup> °), by which nitric oxide is oxidized to nitrogen dioxide and is further oxidized to nitric acid.

Ozeki et al. [28] fabricated TiO<sup>2</sup> /HAp thin film by sputtering on glass using a radio-frequency magnetron. The film has a higher decomposition rate of formaldehyde gas than either the TiO2 or the HAp film alone. However, in the bacterial survival test, survival of cells on the TiO2 /HAp thin film is higher than that on the TiO<sup>2</sup> film, which indicates that the TiO<sup>2</sup> /HAp thin film has a lower bactericidal effect than the pure TiO<sup>2</sup> film.

Liu et al. [29] synthesized HAp-modified N-TiO<sup>2</sup> by a facile wet-chemical method and evaluated its photocatalytic activity by the decomposition of gaseous acetone under visible-light irradiation. The results demonstrated that 10%-HAp-N-TiO<sup>2</sup> sample shows the best photocatalytic activity and the remarkable photocatalytic activity may arise from the synergism between adsorption on HAp and photoactivity by TiO<sup>2</sup> which generated oxygen-reactive species diffusing and reacting with the molecules located on the HAp.

Masato Wakamura et al. have many publications on the field [30–32]. The authors evaluated the adsorption behaviors of proteins onto photocatalytic Ti4+-doped calcium hydroxyapatite (TiHAp) particles which was synthesized by the coprecipitation method using Ca(NO<sup>3</sup> )2 , Ti(SO<sup>4</sup> )2 , H<sup>3</sup> PO4 , and NH<sup>4</sup> OH original materials [31]. The result showed that all the adsorption isotherms of bovine serum albumin (BSA), myoglobin (MGB), and lysozyme (LSZ) from 1 × 10−<sup>4</sup> mol/dm<sup>3</sup> KCl solution were Langmuir type. Generally, the saturated amounts of adsorbed protein value on the TiHAp were much higher than CaHAp.

vacancies formed on the surface of the excited PO<sup>4</sup>

**Scheme 1.** Photocatalytic mechanism of cyanide degradation by Pd-TiO<sup>2</sup>

hydroxyapatite nanoparticle was higher than those of Pd-TiO<sup>2</sup>

the formation of O<sup>2</sup>

TiO2

apatite in the photocatalytic TiO<sup>2</sup>

erated electrons and holes in TiO<sup>2</sup>

enhancing quantum efficiency of photocatalysts.

efficiency of organic pollutants also increases.

The promoted impact of hydroxyapatite in the photocatalytic TiO<sup>2</sup>

sented in the report of Liu et al. [37]. The photocatalytic activities of Ag-TiO<sup>2</sup>

<sup>3</sup>− group in visible illumination will lead to

http://dx.doi.org/10.5772/intechopen.81092

and TiO<sup>2</sup>

nanoparticles is promoted by the internal polarization of


119

nanoparticles. The

/HAp composites was pre-


nanopar-

˙− and will attack the surrounding organic molecules adsorbed on HAp.


Evaluation of the Role of Hydroxyapatite in TiO2/Hydroxyapatite Photocatalytic Materials

The research [34] investigated that the amount of hydroxyl radials formed in the Pd-TiO<sup>2</sup>

absorption of radiation in the visible-light region, the small recombination rate of the electronhole pair, as well as the high surface area of HAp material are the promoted impacts of hydroxy-

The recombination rate of the electron-hole pair is also concerned in another publication [35].

ticles which was supported on electrically polarized HAp films. The separation of photogen-

the HAp support, and consequently, the recombination of charge carriers is mitigated. It can be concluded that the materials with large internal polarization can be used in strategies for

The surface area of HAp material was concerned in the research of Kobayashi et al. [36]. The

synthesized by a facile wet-chemical strategy were evaluated by photocatalytic oxidation decomposition of acetone in air under visible-light illumination. The high photocatalytic activity

/HAp photocatalytic coating was deposited by gas tunnel-type plasma spraying using powders with nano-sized grains. The photocatalytic reaction occurs on powder surface; as the grain size becomes smaller, the specific surface area becomes larger, and the degradation

/HAp composites.

Zhang et al. [35] demonstrated the increased photocatalytic performance of TiO<sup>2</sup>

#### **3. The promoted impact of hydroxyapatite in the photocatalytic TiO2 /HAp composites**

Beside the role as an adsorption material in the photocatalytic TiO<sup>2</sup> /HAp composites, some recent researches have investigated that hydroxyapatite promotes photocatalytic degradation because it can play the role of a support for photocatalysts. The activity of HAp is caused by the generation of active superoxide anion radicals (O<sup>2</sup> ˙−) due to a change in the electronic state of the surface PO<sup>4</sup> <sup>3</sup>− group under UV irradiation [14].

Hu et al. [33] proved the promotion role of HAp to TiO<sup>2</sup> in photocatalytic degradation by using experimental observations and kinetic modeling. The derived kinetic parameters including reaction rate constant, Langmuir adsorption constant, apparent activation energy, etc. confirm that the activity of TiO<sup>2</sup> /HAp composite is more effective than that of TiO<sup>2</sup> . A negative effect of HAp on the photo absorption ability of the TiO<sup>2</sup> /HAp composite is characterized by UV-vis reflectance spectra. The existence of superior chemisorption between HAp and the organic molecules leads to a better performance of TiO<sup>2</sup> /HAp for photocatalytic degradation.

Mohamed et al. [34] determined photocatalytic activities of Pd-TiO<sup>2</sup> -hydroxyapatite nanoparticles, which are synthesized by a template-ultrasonic-assisted method, by photocatalytic removal of cyanide under visible-light irradiation (**Scheme 1**). **Scheme 1** shows that the

**Scheme 1.** Photocatalytic mechanism of cyanide degradation by Pd-TiO<sup>2</sup> -HAp [34].

under ultraviolet light (UV) illumination such as super oxide (O<sup>2</sup>

/HAp thin film is higher than that on the TiO<sup>2</sup>

Liu et al. [29] synthesized HAp-modified N-TiO<sup>2</sup>

, and NH<sup>4</sup>

**/HAp composites**

thin film has a lower bactericidal effect than the pure TiO<sup>2</sup>

irradiation. The results demonstrated that 10%-HAp-N-TiO<sup>2</sup>

cies diffusing and reacting with the molecules located on the HAp.

adsorbed protein value on the TiHAp were much higher than CaHAp.

Beside the role as an adsorption material in the photocatalytic TiO<sup>2</sup>

<sup>3</sup>− group under UV irradiation [14].

the generation of active superoxide anion radicals (O<sup>2</sup>

Hu et al. [33] proved the promotion role of HAp to TiO<sup>2</sup>

effect of HAp on the photo absorption ability of the TiO<sup>2</sup>

organic molecules leads to a better performance of TiO<sup>2</sup>

Mohamed et al. [34] determined photocatalytic activities of Pd-TiO<sup>2</sup>

**3. The promoted impact of hydroxyapatite in the photocatalytic** 

between adsorption on HAp and photoactivity by TiO<sup>2</sup>

and peroxyhydroxyl radical (HO<sup>2</sup>

is further oxidized to nitric acid.

118 Photocatalysts - Applications and Attributes

Ozeki et al. [28] fabricated TiO<sup>2</sup>

TiO2

TiO2

Ti(SO<sup>4</sup> )2 , H<sup>3</sup> PO4

**TiO2**

1 × 10−<sup>4</sup> mol/dm<sup>3</sup>

of the surface PO<sup>4</sup>

firm that the activity of TiO<sup>2</sup>

<sup>−</sup>), hydroxyl radical (OH°),

/HAp

)2 ,

°), by which nitric oxide is oxidized to nitrogen dioxide and

/HAp thin film by sputtering on glass using a radio-frequency

film.

OH original materials [31]. The result showed that all the adsorp-

KCl solution were Langmuir type. Generally, the saturated amounts of

film, which indicates that the TiO<sup>2</sup>

by a facile wet-chemical method and evalu-

sample shows the best photo-

/HAp composites, some

. A negative

˙−) due to a change in the electronic state

in photocatalytic degradation by using

/HAp composite is characterized by

/HAp for photocatalytic degradation.


which generated oxygen-reactive spe-

magnetron. The film has a higher decomposition rate of formaldehyde gas than either the

ated its photocatalytic activity by the decomposition of gaseous acetone under visible-light

catalytic activity and the remarkable photocatalytic activity may arise from the synergism

Masato Wakamura et al. have many publications on the field [30–32]. The authors evaluated the adsorption behaviors of proteins onto photocatalytic Ti4+-doped calcium hydroxyapatite (TiHAp) particles which was synthesized by the coprecipitation method using Ca(NO<sup>3</sup>

tion isotherms of bovine serum albumin (BSA), myoglobin (MGB), and lysozyme (LSZ) from

recent researches have investigated that hydroxyapatite promotes photocatalytic degradation because it can play the role of a support for photocatalysts. The activity of HAp is caused by

experimental observations and kinetic modeling. The derived kinetic parameters including reaction rate constant, Langmuir adsorption constant, apparent activation energy, etc. con-

UV-vis reflectance spectra. The existence of superior chemisorption between HAp and the

ticles, which are synthesized by a template-ultrasonic-assisted method, by photocatalytic removal of cyanide under visible-light irradiation (**Scheme 1**). **Scheme 1** shows that the

/HAp composite is more effective than that of TiO<sup>2</sup>

or the HAp film alone. However, in the bacterial survival test, survival of cells on the

vacancies formed on the surface of the excited PO<sup>4</sup> <sup>3</sup>− group in visible illumination will lead to the formation of O<sup>2</sup> ˙− and will attack the surrounding organic molecules adsorbed on HAp.

The research [34] investigated that the amount of hydroxyl radials formed in the Pd-TiO<sup>2</sup> hydroxyapatite nanoparticle was higher than those of Pd-TiO<sup>2</sup> and TiO<sup>2</sup> nanoparticles. The absorption of radiation in the visible-light region, the small recombination rate of the electronhole pair, as well as the high surface area of HAp material are the promoted impacts of hydroxyapatite in the photocatalytic TiO<sup>2</sup> /HAp composites.

The recombination rate of the electron-hole pair is also concerned in another publication [35]. Zhang et al. [35] demonstrated the increased photocatalytic performance of TiO<sup>2</sup> nanoparticles which was supported on electrically polarized HAp films. The separation of photogenerated electrons and holes in TiO<sup>2</sup> nanoparticles is promoted by the internal polarization of the HAp support, and consequently, the recombination of charge carriers is mitigated. It can be concluded that the materials with large internal polarization can be used in strategies for enhancing quantum efficiency of photocatalysts.

The surface area of HAp material was concerned in the research of Kobayashi et al. [36]. The TiO2 /HAp photocatalytic coating was deposited by gas tunnel-type plasma spraying using powders with nano-sized grains. The photocatalytic reaction occurs on powder surface; as the grain size becomes smaller, the specific surface area becomes larger, and the degradation efficiency of organic pollutants also increases.

The promoted impact of hydroxyapatite in the photocatalytic TiO<sup>2</sup> /HAp composites was presented in the report of Liu et al. [37]. The photocatalytic activities of Ag-TiO<sup>2</sup> -HAp powders synthesized by a facile wet-chemical strategy were evaluated by photocatalytic oxidation decomposition of acetone in air under visible-light illumination. The high photocatalytic activity of the Ag-TiO<sup>2</sup> -HAP hybrids could be attributed to its strong absorption in the visible-light region, low recombination rate of the electron-hole pair, and large BET-specific surface area.

levels corresponded with the characterization of titanium (IV) in TiO<sup>2</sup>

states of titanium in the annealing process of TiO(OH)2

/HAp material calculated by the DRS measurement was 3.6 eV, while those

may affect the absorption ability of radiation in the visible-light region; consequently, in some cases, it is a demoted impact which reduces the photocatalytic activity of TiO<sup>2</sup>

nations which is generally influenced by the physicochemical properties of HAp material. On the other hand, the promoted impacts of hydroxyapatite in the composites are experimentally collected in the specific cases including the absorption of radiation in the visible-light region, the small recombination rate of the electron-hole pair, and the high surface area of HAp com-

continuously researched and evaluated to obtain the best composite in the photocatalytic

This work is supported by Basic Science Research Programs (No. 2015R1D1A1A01056983) through the NRF, Korea, funded by the Ministry of Education and (No. 2018R1A2B6002194)

1 Department of Chemistry, Ho Chi Minh City University of Education, Ho Chi Minh City,

2 Department of Materials Science and Engineering, Korea Advanced Institute of Science

[1] Fihri A, Len C, Varma RS, Solhy A. Hydroxyapatite: A review of syntheses, structure and applications in heterogeneous catalysis. Coordination Chemistry Reviews. 2017;

and Kwangsoo No<sup>2</sup>

\*, Seungbum Hong<sup>2</sup>

\*Address all correspondence to: linhntt@hcmup.edu.vn

were 5.3 and 3.2 eV, respectively. The shifts may relate oxidation

Evaluation of the Role of Hydroxyapatite in TiO2/Hydroxyapatite Photocatalytic Materials

/HAp composites, HAp plays the role of an adsorption of contami-

/hydroxyapatite photocatalytic materials has been

bandgap of TiO<sup>2</sup>

composites.

**4. Conclusion**

In the photocatalytic TiO<sup>2</sup>

**Acknowledgements**

**Author details**

Vietnam

**References**

**347**:48-76

Linh Nguyen Thi Truc<sup>1</sup>

ponent. However, the role of HAp in TiO<sup>2</sup>

field, as well as in other applications.

by the Ministry of Science and ICT.

and Technology, Daejeon, South Korea

of pure HAp and TiO<sup>2</sup>

. The experimental

/HAp

121

/HAp gel. The increase of bandgap

http://dx.doi.org/10.5772/intechopen.81092

Aramendia et al. [38] studied on the TiO<sup>2</sup> /natural phosphate material synthesized by sol-gel process and tested the photocatalytic activity in the photo-oxidation process of propan-2-ol. The results show that the presence of natural phosphate makes a retardation of TiO<sup>2</sup> crystallization and creates a certain interaction with titanium.

Nishikawa et al. [39] indicated that the difference in photocatalytic activity of the materials containing HAp and without HAp may be originated from the properties of the electronic state that forms the valence band of HAp-containing PO<sup>4</sup> group.

Li et al. [40] synthesized Ti-substituted hydroxyapatite (TiHAp) by the coprecipitation method. The adsorption and photocatalytic degradation of bisphenol A (BPA, an environmental endocrine disrupting chemical) over TiHAp and P25 TiO<sup>2</sup> photocatalysts were studied using liquid chromatography-mass spectrometry. The results indicated that the adsorption of BPA on TiHAp and TiO<sup>2</sup> obeyed the Langmuir adsorption equation, and the adsorption capacity and photocatalytic degradation activity of BPA of TiHAp material were much higher than those of TiO<sup>2</sup> . To explain for the results, the authors presented that the zeta potentials of TiHAp, and TiO<sup>2</sup> did not show significant difference when the pH was about seven, suggesting that the surface charge was not the reason for the different adsorption capacities of the particles. In addition, the specific surface area and average pore diameter of TiHAp and TiO<sup>2</sup> were comparable, so these would not lead to the different adsorption capacities either. In fact, TiHAp material is produced from a substitution of some Ca sites in HAp by Ti, which resulted in multiple Ti-OH groups on the TiHAp surface. Large amounts of phosphates and hydroxyls in the crystal lattice of TiHAp can adsorb the hydroxyls of BPA by hydrogen bonding.

The bandgap of TiO<sup>2</sup> /HAp materials were mentioned in some publications because it decides the energy separation between valence and conduction bands, the quantum effect, as well as the effect of visible-light utilization, etc. The bandgap of HAp was reported in [41] to be 3.95 eV by photoluminescence measurement; meanwhile, in other reports, the bandgap of HAp was calculated to be around 4.51–5.4 eV [42, 43]. The bandgap of TiO<sup>2</sup> /HAp composites calculated by UV-vis diffuse reflectance spectra was between 3.06 and 3.08 eV while that of pure TiO<sup>2</sup> was broader (3.12 eV) [44]. However, the bandgap of Ti-substituted hydroxyapatite evaluated by both experimental and theoretical methods was 3.65 eV [45]. Masato Wakamura et al. determined the effect of Ti substitution in HAp synthesized by the coprecipitation method on the bandgap which was compared with that of a typical anatase-TiO<sup>2</sup> photocatalytic powder. The experimentally obtained optical bandgap energies of TiHAp, HAp, and TiO<sup>2</sup> powder measured by diffuse reflectance spectroscopy were 3.65, >6, and 3.27 eV, respectively. The authors explained the increase of bandgap in TiHAp due to hybridizing of Ti 3d orbital with O 2p orbital and forming an internal state in the HAp bandgap, consequently, causing the absorption-edge lowering of TiHAp. Researching on the acetaldehyde gas decomposition of TiHAp by UV with VIS irradiation, the authors investigated the increase of activity comparing with when UV irradiation alone was used. Linh et al. [46] also indicated the shift of bandgap of TiO<sup>2</sup> /HAp material synthesized by the hydrothermal process containing TiO(OH)<sup>2</sup> and HAp gels. The binding energy values of Ca 2p, P 2p, and O1s levels are related to hydroxyapatite phase, whereas those of Ti 2p levels corresponded with the characterization of titanium (IV) in TiO<sup>2</sup> . The experimental bandgap of TiO<sup>2</sup> /HAp material calculated by the DRS measurement was 3.6 eV, while those of pure HAp and TiO<sup>2</sup> were 5.3 and 3.2 eV, respectively. The shifts may relate oxidation states of titanium in the annealing process of TiO(OH)2 /HAp gel. The increase of bandgap may affect the absorption ability of radiation in the visible-light region; consequently, in some cases, it is a demoted impact which reduces the photocatalytic activity of TiO<sup>2</sup> /HAp composites.
