1. Introduction

Volatile organic compounds (VOCs) are liquid or gaseous organic compounds that easily evaporate into the atmosphere due to their low boiling point. All carbon compounds, except for the negligible substances designated by the EPA (United States Environmental Protection Agency, Washington, DC, USA), are included in VOCs. The WHO (World Health Organization, Geneva, Switzerland) classifies VOCs according to their ease of release based on their boiling point measured at 101.3 kPa: VVOC (very volatile organic compounds, B_T (Boring temperature): ~0 to 50~100 °C), VOC (volatile organic compounds, B_T: 50~100 to 240~260 °C), and SVOC (semi-volatile organic compounds, B_T: 240~260 to 380~400 °C) [1].

Currently, the main sources of VOCs emission sources include gasoline/diesel vehicles, construction equipment, electric utilities, petrochemicals, and odor handling process, as well as the paint, solvent, adhesive, and synthetic resin manufacturing industries [2]. According to Li et al., China, had the highest contribution to global VOC emissions, as of 2017. They also reported that 33% of the total VOCs are aromatic compounds with the highest content in the order of toluene > xylene > ethylene > acetylene > benzene > others [3]. Brown et al. examined the main sources of VOCs in LA and observed that approximately 50% of all VOCs originated from processes that use solvents [4]. Similarly, in Korea, approximately 53% of total VOCs are emitted from the paint, ink, and print manufacturing facilities [5].

VOCs emissions from various sources typically include BTEX (benzene, ethylbenzene, toluene, xylene), alcohols, esters, and organic solvents. VOCs, such as BTEX and ethylene, are precursors that generate ozone and photochemical smog through photochemical reactions with nitrogen oxides (NOx) in the atmosphere, thereby contributing to global warming. VOCs are also known as secondary fine dust precursors [6]. The effective removal of VOCs may reduce the emission of fine dust generating materials, which is a significant focus of research at present [7]. Additionally, based on the risk of VOCs to humans, according to the carcinogenic substance classification system by the International Agency for Research on Cancer (IARC), benzene, 1,3-butadiene, formaldehyde, trichlorethylene, among others, are carcinogenic to humans (group 1). Furthermore, tetrachloroethylene is classified as a putative substance and is probably carcinogenic to humans (group 2A).

Technologies for VOC emission reduction can be broadly divided into two types. The first one is a method of degrading VOCs using chemical conversion, such as oxidation or decomposition, and the second one is a method of adsorbing or recovering VOCs without chemical conversion and reusing it. Examples of methods using chemical conversion include oxidation using fuel or decomposition using UV or microorganisms. This method has a disadvantage in that VOCs cannot be recovered; this is a major drawback especially when the target VOCs are expensive. Examples of separation and recovery technologies include adsorption and film separation, as well as condensation using cooling. In this case, VOCs are mixed with different components, and this method has a disadvantage in that the total removal rate is reduced based on the selective adsorption capacity of adsorbents [8,9,10].

Catalysts used for the oxidation of VOCs include noble metals, non-noble metals, and perovskite. Noble-metal-based catalysts are widely used owing to their effectiveness for low-temperature VOC oxidation and high BTEX oxidation efficiency. Although research on non-noble-metal-based catalysts has been conducted, their application is limited due to several issues, such as difficult disposal, high toxicity, and low activity. Additionally, since many studies use a mixture of non-noble metals with a noble metal catalyst to increase VOC oxidation efficiency, it is essential to examine the characteristics of the noble metal catalyst in detail.

This review investigates a combustion catalyst that converts VOCs, which are hydrocarbon compounds, into carbon dioxide and water, and discharges them through a combustion reaction during chemical conversion. In particular, the BTEX-based combustion catalyst has been described, which is relatively difficult to oxidize due to its large and stable molecular structure that includes a benzene ring. Further, the characteristics of noble-metal-based combustion catalyst technology are investigated.

2. Catalytic Combustion Mechanism of Noble Metal Catalysts

2.1. Kinetic Analysis

To explain the VOC oxidation mechanism, many researchers have proposed a three-mechanism model: (a) Langmuir–Hinshellwood (L–H) model, (b) Eley–Rideal (E–R) model, and (c) Mars–Van Krevelen (MVK) model (two-stage redox) with the Pd-based catalysts (Figure 1 and Table 1). The (a) mechanism model emphasizes the interaction between two molecules adsorbed at the active sites of the solid metal surface, while the surface reaction between adsorbed reactants and gaseous molecules was included in the (b) mechanism model. The (c) mechanism model assumes that the oxygen surface concentration of the catalyst is constant, and the reaction occurs through the interaction of the reactant molecule and the oxidized sites of the catalyst surface [11,12,13,14,15,16,17,18,19,20,21,22].

As shown in Table 1, an MVK kinetic model is generally used to explain the oxidation reaction of VOCs on Pd catalysts. Unlike general Pd-based catalysts, the L–H model applies to the oxidation of toluene (C₇H₈) over Pd/C catalysts with activated carbon as a support [16]. Additionally, the E–R model was applied to the catalytic oxidation of trichloroethylene (TCE) using Pd/Al₂O₃ catalysts [15]. Overall, it has been reported that the effect of each mechanism is determined by the catalyst composition and VOC component. Alejo et al. investigated the mechanism of the toluene oxidation reaction through an intermediate analysis of the Pd/CeO₂ catalyst. The role of the Pd catalyst in the MVK mechanism was also investigated, and it was found to promote lattice oxygen generation [13]. Recently, Manta et al. investigated cycloalkane (cyclooctane) oxidation on Pt/γ-alumina using an E–R kinetic model, whereas catalytic o-xylene combustion over Pt/γ-alumina was described by the L–H mechanism model [20].

The kinetic model of the catalytic VOC (ethyl acetate and toluene) combustion over Au/MeO_x (Me = Mg, Fe, Ni, Cu, Y, and La) [23] and Pd/ZSM-5 [14] was a good fit for the MVK model. Shengsheng et al. [21] evaluated the activity of the toluene oxidation reaction by varying the oxygen vacancy concentration while changing the surface exposure of the Pt/CeO₂ catalyst; the main reaction was achieved through the L–H model. The catalytic oxidation of propene over Au-MeO_x/Al₂O₃ (Me = Mn, Fe, Co, and Ce) [24] and methyl-ethyl-ketone (MEK) over Pd-Mn/Al₂O₃ [25] obeyed the MVK model. In addition, the MVK model applied to the catalytic oxidation reaction of oxygenated hydrocarbons (methanol) on Pd/Y [26] and alkanes (isobutane) on Au-MeO_x/CeO₂ (Me = Mn, Fe, Co, and Ni) [27]. Thus, most researchers have analyzed the catalytic oxidation of noble metal catalysts using the MVK model.

2.2. Mechanism Studies

To remove VOCs, the mechanism of catalytic VOC combustion over noble metal catalysts was classified into hydrocarbons, oxygen-containing hydrocarbons, and chlorine-containing hydrocarbons, as presented in the following sections.

2.2.1. Hydrocarbons

The mechanism of catalytic propane combustion over a Pt catalyst supported on various zeolites (e.g., ZSM-5, Beta, HY, and KL) was reported by Garetto et al. [28]. The rate-determining step was suggested to be dissociative chemisorption of propane on Pt through interaction with surrounding adsorbed oxygen atoms after the weakest C–H bond was broken. Consequently, propane adsorption occurs, and propane molecules are activated at the surface-active sites present in the metal oxide through a parallel oxidation pathway and react with excess oxygen from the metal active sites.

Yang et al. investigated catalytic ethylene oxidation using Ag catalysts supported on zeolites (e.g., ZSM-5, Beta, Y, and MOR) [29]. The reaction mechanism by which ethylene is catalytically oxidized occurs in different stages. First, ethylene is adsorbed and activated at the Brønsted acid sites present in Ag-metal-supported zeolite catalysts. The activated ethylene species are attacked by reactive oxygen species (ROS), resulting in the formation of formaldehyde by breaking the C–C bond of ethylene species. Subsequently, formaldehyde produced on the catalyst surface is continuously oxidized to CO₂ and H₂O.

A catalytic study on the mechanism of propene combustion was conducted by Weng et al. [30]. To elucidate the mechanism, Pt metal was supported on alumina, and BaO was used as an additive. Propene is adsorbed and activated at the catalytically active site, converted to carboxylate, and formed acrylate. In this case, when BaO was used as an additive in the catalytic reaction, improved reactivity was obtained while inducing the generation of more reactive enolic species. Consequently, ROS increases on the metal surface (Pt-Ba) of the catalyst, which also increases the CO oxidation rate.

2.2.2. Oxygen-Containing Hydrocarbons

The catalytic combustion mechanism of 2-propanol was proposed by Liu and Yang using an Au-based catalyst [31]. Similar to other mechanisms, the first step in the mechanism of 2-propanol oxidation over the Au/CeO₂ catalyst is the adsorption of 2-propanol onto the catalyst. Subsequently, it was assumed that 2-propoxide surface species are generated and dehydrated at strong acid sites to propene or dehydrogenated at other active sites (medium/weak acid or strong base). Zhang and He reported a catalytic combustion mechanism of formaldehyde over TiO₂ catalysts with added noble metals, such as Pt, Rh, Pd, and Au [32].

In the catalytic combustion mechanism of acetaldehyde [33], the reactants acetaldehyde and oxygen molecules are adsorbed to the double active site of the catalyst to form acetic acid (AA). The formed AA migrates to the catalyst support surface with bridged oxygen and Ti⁴⁺ ions, serving as Lewis acid or base active sites. The AA ions and protons generated by the dissociation of AA are strongly adsorbed onto the active sites. Finally, AA was converted to CO₂ and H₂O by catalytic oxidation on Au/TiO₂.

Yue et al. reported the reaction mechanisms for catalytic MEK combustion on Pd (-Ce)/ZSM-5 [34]. It was reported that by-products produced in the oxidation reaction were increased by the introduction of CeO₂. In addition, researchers have reported that catalysts containing Ce accelerate the dehydration of the intermediate species to produce acetaldehyde and numerous secondary products.

Jiang et al. investigated the combustion of MEK on Pt/K-Al-SiO₂. MEK is adsorbed over the Brønsted acid sites of Pt/K-Al-SiO₂ before oxidation because of the interaction with the Pt species. Subsequently, it was transformed to 2,3-butandiol and diacetyl through the intermediate products, 2-butanol and acetoin, respectively. Acetaldehyde was formed from 2,3-butandiol, and acetaldehyde and AA were formed from diacetyl conversion. Acetaldehyde and AA undergo complete oxidation to CO₂ and H₂O via formaldehyde and formic acid, respectively, at the Brønsted acid sites of the catalyst [35].

2.2.3. Other Hydrocarbons (Containing Nitrogen and Chlorine)

A study on the oxidation mechanism of hydrocarbons, including nitrogen, reported the acrylonitrile oxidation pathway using an Ag-based catalyst. Nanba et al. [36] suggested that the oxidation of acrylonitrile proceeded on Ag₂O and then intermediate ammonia and acrylic acid were converted into N₂, CO, and CO₂ on Ag metal sites. In the case of Ag/ZrO₂ and Ag/MgO, the catalytic oxidation of acrylonitrile over large-sized metallic Ag particles directly produced large amounts of nitrogen oxide (NOx, N₂O). Meanwhile, acrylonitrile was oxidized to form nitrogen-containing products and various hydrocarbons on the active Ag phase of the Ag-ZSM-5 catalyst.

In the case of chlorine-containing hydrocarbons (trichloroethylene and chlorobenzene), Aranzabal et al. [37] evaluated the characteristics of TCE oxidation reaction over Pd/Al₂O₃. It was suggested that gaseous oxygen molecules are chemisorbed on the active site, and according to the E–R model, TCE can react directly with the adsorbed oxygen to form carbon oxides (CO₂ and CO). The catalytic oxidation of TCE has been reported to be associated with the dissociation of the C–Cl chemical bond between the catalyst and halogen. Subsequently, noble-metal-chloride species are produced on Al₂O₃ and AlCl₃. Noble-metal-chloride species are directly decomposed to Cl₂ and further react with TCE after being transferred onto a double bond. Dai et al. [38] proposed a catalytic oxidation mechanism for chlorobenzene over a CeO-based Ru catalyst. It was reported that the C–Cl bond in chlorobenzene decomposed relatively easily compared to the Ce³⁺/Ce⁴⁺ active site. The final reaction was proposed as a mechanism that VOC oxidizes to CO₂ and H₂O at surface or lattice oxygen atoms. It was reported that the catalyst was quickly deactivated by blocking of the active sites, due to the adsorption of chlorine species.

3. Noble-Metal-Based Catalysts for VOC Oxidation

As a catalyst for VOC removal from industrial flue gas, noble-metal-based catalysts, such as Ag, Au, Pd, Pt, Rh, and Ru, which have high activity at low temperatures, are widely used. Ceramic or metallic materials are widely used as supports for noble-metal-based catalysts. These catalysts have different VOC combustion activities depending on the type of support and bonding type with the support. However, because noble metals are expensive, studies are actively being conducted to improve the economic feasibility, stability, and selectivity of noble-metal-based catalysts by improving the catalyst dispersion, particle size, specific surface area, and structure of the active material. Furthermore, a catalyst with both high performance and economic feasibility has been developed by mixing non-noble metal catalysts possessing relatively low activity with noble metal catalysts [39].

3.1. Ag-Based Catalysts

VOC combustion generally occurs in the temperature range of 250–350 °C. However, it has been reported that Ag-based catalysts are less active in the oxidation of BTEX compounds in this temperature range, compared to other noble metal or transition metal catalysts. Baek et al. analyzed the characteristics of Ag catalysts during VOC combustion using Ag/HY-zeolite catalysts. As the Ag molecular content increased, the number of Ag nanoparticles increased, resulting in an increase in the catalytic activity [40].

Although the optimal content of Ag molecules reported by researchers varied significantly, it has been reported that, when Ag content is increased, the number of active sites is limited owing to the increase in the catalyst crystal size and, consequently, the decrease in specific surface area and void fraction [41].

However, according to Zhou et al., when Ag content was low, the VOC removal efficiency of the catalyst was reduced owing to the decreased content of the active phase [42]. Moreover, the Cu-Mn-Ag catalyst was impregnated onto a cordite monolith support, and the combustion efficiency of toluene was evaluated. Consequently, the catalyst activity was the highest at 21.2 wt% Ag content, and at a relatively higher Ag content, the catalyst activity decreased because the active phase accumulated on the surface of the support.

Generally, oxygen vacancies are widely known to promote catalytic activity for VOC combustion [43,44,45]. Ma et al. demonstrated that the binding of Ag species was related to the benzene combustion reaction. The binding of Ag species over CeO₂-Co₃O₄ induces electron transfer at the surface of the metal oxide, thus creating more active sites (Co³⁺) and oxygen defect sites (Ce³⁺) (Figure 2). This promotes the adsorption of benzene molecules on the surface of the metal oxide catalyst and the reactivity of benzene combustion at low temperatures [45].

3.2. Au-Based Catalysts

Gold-based catalysts are known to exhibit high oxidation activity, as reported by many previous studies [46,47,48,49,50]. For BTEX combustion, Au-based catalysts can react at temperatures higher than 190–400 °C, compared to Pd/Pt-based catalysts. Further, Au-based catalysts have the characteristic that they are less prone to deactivation caused by carbon coke formation inside the catalyst pores. Although Au-based catalysts have low economic efficiency compared to combustion efficiency due to the low oxygen changing rate, many studies are ongoing to address this problem by developing transition metal complexes to overcome thermal stabilities and enhance catalyst activities [51].

In particular, for Au-based catalysts in VOC combustion, the preparation method is crucial because it is highly dependent on the size of the particles and the type of support [52,53,54,55]. The mechanism of the catalytic reaction of VOC oxidation may vary depending on the type of support material used. The oxidation of VOCs is affected by the size, distribution, shape, and oxidation state of Au particles, which are the metal active sites. Many reports emphasize the role of supports and describe various supports, such as metals [23,56], aluminum [24,47,57,58], titanium [59,60], and silica [61], in Au-based catalysts. These studies optimized the shapes, sizes, contents, etc. of the Au catalyst, influencing the activity of the material in VOC oxidation, and described the correlation between catalyst and support in heterogeneous catalysts [54,62]. Table 2 lists the VOC oxidation characteristics of the Au catalysts according to the type of support material used.

Although some researchers have reported that the oxidation state of Au as a metal active site has an important effect on the activity of the VOC oxidation reaction, it was reported that the oxidation state is influenced by the particle size, shape, distribution, etc. of Au. Thus, research on increasing particle dispersion is in progress. Au-based catalysts are produced by various methods, such as precipitation and coprecipitation, to increase the dispersion of Au particles. It was reported that the deposition–precipitation method can produce particles in the range of 4 to 8 nm [24,63,64].

According to Carabineiro et al., metals in Au-based catalysts play a role in improving the support reducibility and catalytic reactivity. Catalyst activity is enhanced by an increase in the oxygen exchange between the lattice and the support surface. The Au/Y₂O₃ catalyst with the Au³⁺ oxidation state showed low catalytic activity. In contrast, for Au-based Fe₂O₃, NiO, and CuO catalysts, the toluene combustion activity increased with Au in the oxidation state of Au⁺ and Au⁰ [23].

Li et al. studied the reaction characteristics of toluene oxidation using a LaCoO₃ supported on a crystallized three-dimensionally ordered microporous material (3DOM). The Au-based 3DOM LaCoO₃ catalyst, compared to the bulk LaCoO₃ catalyst, possessed several characteristics, such as uniform pore size, surface thickness, and high Au dispersion [49]. In addition, it has been reported that the presence of oxygen species on the support surface promotes oxygen formation, which is advantageous for VOC oxidation.

3.3. Pd-Based Catalysts

Pd-based catalysts are used in a slightly higher temperature range of 200–300 °C compared to Pt-based catalysts for the VOC combustion reaction. The active phase of the Pd catalyst was Pd⁰, and the oxidation state of Pd affected the catalyst activity. Therefore, it has been reported that VOC combustion activity is highly dependent on the Pd content in the catalyst [65,66]. Although the chemical state of the Pd species is an important factor influencing the catalytic activity, there is controversy about this effect, as shown in Table 3.

According to Dégé et al., it was confirmed that the VOC oxidation activity was greatly affected by the Pd content and that the surface area, particle size, particle dispersion, and support also affect the activity of the catalyst [66]. Moreover, the results indicated that the coke content generated at low temperatures differed depending on the acidity of the zeolite (that is, the change in the Si/Al ratio) used as the support. For the oxidation of o-xylene (C₈H₁₀), the higher the acidity of the zeolite, the higher the rate of coke formation. Furthermore, it was confirmed that an increase in Pd content also plays a role in suppressing coke formation at the same temperature. During toluene combustion, it was determined that the stability of the Pd-based catalyst was higher than that of the Pt-based catalyst (the activated carbon fiber support was impregnated with 3.86 wt% Pt or Pd), which is advantageous for the combustion of cyclic organic compounds [67]. Bi et al. reported that a Pd-U-H catalyst formed nanoparticles and increased the surface Pd⁰ and lattice oxygen content. As a result of this effect, the combustion ratio of toluene was maintained at a high level in the 6-cycle reaction experiment [68].

Gil et al. examined the oxidation state of Pd according to the type of support (CeO₂, TiO₂, and Al₂O₃) through XPS analysis and evaluated the conversion rate of propene. Pd/Al₂O₃ and Pd/TiO₂ have a Pd²⁺ phase, similar to bulk PdO, whereas Pd/CeO₂ has a Pd⁴⁺ phase. These characteristics explain the poor catalytic activity of Pd/CeO₂ for propene combustion because the Pd⁴⁺ species form strong bonds with the support [69].

Weng et al. proposed that metallic Pd exhibited higher oxidation activity using the Pd/MgO-Al₂O₃ catalyst system. The oxidation state of the Pd-based catalyst was characterized by XPS analysis of fresh, hydrotreated, and spent catalysts after toluene reaction. After hydrogen treatment, the Pd²⁺ state of the catalyst increased, indicating the formation of a Pd²⁺/Pd⁰ pair that aids in the toluene oxygen activity [70].

Meanwhile, a portion of the metallic Pd is oxidized to Pd²⁺ states, and the reaction proceeds in the form of reduction aided by hydrocarbons. For Pd⁰, Pd²⁺, or mixed Pd²⁺/Pd⁰ states, Pd⁰ helps to improve the reaction rate by providing more adsorbable active sites for VOCs, and Pd²⁺ plays a role in VOC combustion [71,72].

Catalytic oxidation of VOCs over Pd catalysts with different Pd states.

As the surface area and structure of the catalyst affect the activity, several researchers have investigated the oxidation states of the catalyst with relation to the support. When activated carbon is used as a support, its physical and chemical properties affect the metal deposition, dispersion, and gas adsorption efficiency [76].

Table 4 summarizes the activities of Pd-based catalysts based on different types of supports. According to Giraudon et al., the combustion performance of Pd/TiX showed superior chlorobenzene (C₆H₅Cl) conversion compared to Pd/ZrX. This is because the reducibility of TiO₂ was improved from Ti⁴⁺ to Ti³⁺ [77]. Pérez-Cadenas et al. reported that the VOC combustion reactivity of a Pd-based catalyst is affected by the surface area of mesopores, since the activity of the mesoporous supports was higher than that of the microporous and monolithic supports [78]. Mesoporous Pd/Co₃O₄ (3D) catalysts have relatively higher activity for o-xylene oxidation than the bulk counterpart Pd/Co₃O₄. This improvement might be due to the increased surface exposure of PdO on the mesoporous Co₃O₄ support [79].

Nanoparticle catalysts have different physical and chemical properties compared to single metal catalysts; thus, there is a synergistic effect in the VOC combustion properties of Pd-based catalysts [80]. Generally, alloy catalysts show a more flexible surface structure than single metal catalysts and induce affinity between the catalyst surface and the adsorbate, which contributes to high activity [81].

Comparing the reaction mechanism of Pd-Ce/Al₂O₃ with that of Pd/Al₂O₃, the presence of Ce increased the active oxygen species and oxygen vacancy content on the catalyst surface. During the conversion of Ce³⁺ to Ce⁴⁺, electrons are donated to PdO to promote PdO to Pd, thereby generating lattice oxygens and promoting the reaction with adsorbed toluene. In addition, Ce can improve the catalyst activity by reducing the noble metal content in the catalyst [14].

Wu et al. evaluated the toluene combustion characteristics of the Au-Pd/meso-Cr₂O₃ catalyst and reported that Au-Pd nanoparticles showed excellent toluene combustion activity, compared to single metal catalysts, owing to their strong interaction with Cr₂O₃ [82]. Similarly, Chen et al. reported that, when a Pd-Pt-based nanoparticle catalyst was used for the benzene (C₆H₆) combustion reaction, it showed excellent conversion, which was due to the nano effect of the catalyst and the interaction between the active materials (Pd-Pt) [83].

Comparison of Pd-based catalysts on various supports for VOC oxidation.

3.4. Pt-Based Catalysts

Pt-based catalysts are known to be the most efficient element for the combustion of cyclic hydrocarbon compounds and exhibit activity for the combustion of BTEX compounds in the temperature range of 150–350 °C [85,86]. Because the Pt-based catalyst does not interact with the support, the physical/chemical properties are maintained after impregnation. The characteristics of the support affect the deposition and dispersion of the active element, which ultimately influences the durability and poisoning resistance of the catalyst [87].

The dispersion degree of the Pt-based catalyst depends on the support, so it is important to improve this parameter to obtain high activity. Since the metal catalyst easily combines with the oxidized site of the support, the dispersibility of Pt can be improved by oxidizing the activated carbon support by acid treatment or air oxidation [88]. To improve the deposition rate of the metal catalyst onto the support, a Pt catalyst was deposited on a porous support by dry impregnation rather than wet impregnation. In addition, the ion-exchange method was used to deposit metal catalysts onto the zeolite surface [86].

Table 5 summarizes the oxidation characteristics of Pt-based catalysts using cerium oxide as a support (Pt/CeO₂). It has been reported that the Pt/CeO₂ catalyst has superior oxygen storage capacity, reducibility, and VOC combustion performance compared to the CeO₂ catalyst [89]. In particular, when CeO₂-Al₂O₃ was used as a support, the Pt catalyst formed nanoparticles and exhibited high reducibility and activity in xylene and toluene oxidation. In addition, owing to the improvement in the dispersion degree of Pt particles, the high temperature (>300 °C) oxidation activity might be increased [90]. The catalyst using Al₂O₃-CeO₂ as a support exhibited improved oxidation of dichloromethane (DCM, CH₂Cl₂) [91]. The addition of Ce and Pt catalysts enhanced the selectivity of CO₂ and inhibits catalyst deactivation by reducing the formation of CH₃Cl, CH₂O, CO, etc.

The activity of the catalyst for VOC oxidation was greatly affected by the type and shape of the catalyst support. The surface oxygen vacancies, which play an important role in adsorbing gaseous oxygen and promoting combustion activity, depend on shape of catalyst. Peng et al. [92] prepared catalysts by adding Pt catalysts to CeO₂ supports with various crystal sizes. A high-efficiency Pt/CeO₂ catalyst was optimized for toluene combustion by controlling the degree of exposure of the support surface and the role of CeO₂ was reported.

Recently, many studies have been reported on the combustion of chlorinated volatile organic compounds (CVOCs). As a result of evaluating the support of the Pt-based catalysts used for DOM combustion, the activity of Pt/Al₂O₃ was superior compared to that of Pt/TiO₂, Pt/CeO₂, and Pt/MgO. This is because when Al₂O₃ is used as a support, the particle size of Pt is reduced to less than 1.2 nm [93].

Pt molecules serve to increase the number of weak acid sites and reduce the number of strong acid sites on the catalyst surface. This phenomenon strengthens the adsorption strength between the VOCs and the catalyst surface. Yang et al. confirmed that an insufficient active oxygen supply was improved by adding Pt to the Pd/CeO₂/γ-Al₂O₃ catalyst in the oxidation of various VOCs [94].

3.5. Rh-Based Catalysts

It is known that Rh-based VOC combustion catalysts are far less explored than other novel metal-based catalysts. Recently, they have attracted attention because of their improved effects on the catalytic oxidation of CVOCs, aromatics, and alkanes.

Rh-based catalysts have high stability with the support material compared to other noble metal catalysts (Ru, Rh, Pd, and Pt) [91,95]. Noble metals have high thermal stability while forming an M–O–Ce bond with a CeO₂ support. Saburo et al. reported that the M-O–Ce bond was maintained above 800 °C for Ru-and Pd-based catalysts, while the M–O–Ce bond endured below 500 °C, and Ru was present as bulk RuO₂ below 500 °C. Therefore, it was concluded that the stability between noble metals and the CeO₂ support was high and followed the order of Rh > Pd > Pt > Ru [96].

According to Pitkäaho et al. in Table 6, the Rh-based catalytic activity sequence with different supports was Al₂O₃ > Al₂O₃-CeO₂ > Al₂O₃-TiO₂. When the same support was used, the Rh-based catalyst exhibited higher activity than other metal-based catalysts (Pd, V₂O₅, and Pt). For the combustion of CVOCs, selectivity to CO, CO₂, HCl, and high activity are required. The addition of Rh improved the HCl yield of the Al₂O₃ supported catalyst and had a HCl selectivity of 93%. For the Rh catalyst, the amount of CO formed differed depending on the support. It showed a high CO yield of 46% over the Al₂O₃ supported catalysts, 14% over Rh/Al₂O₃-TiO₂, and 1% over Rh/Al₂O₃-CeO₂ [91].

In the reports on Rh-based catalysts, Rh/TiO₂ yielded the lowest Cl content of 0.61% after CVOC oxidation, which was consistent with the amount of polychlorinated by-products (dichlorobenzene, trichlorobenzene, tetra-chlorobenzene, pent-chlorobenzene, etc.) detected by XPS analyses. The maximum concentration of chlorobenzene combustion by-products, 1,3-dichlorobenzene and 1,4-dichlorobenzene, reached 23 ppm at 310 °C [97].

We can now summarize the contents of verse 3, although the combustion characteristics of VOCs depend on the support; the characteristics of Pd, Pt, and Rh catalysts supported on TiO₂ were examined in the oxidation of chlorobenzene, as shown in Figure 3 [97]. For all three catalysts, the oxidation of chlorobenzene is initiated at 250 °C, and all of them exhibit a conversion rate of more than 95% at temperatures above 350 °C.: (1) T₉₀ (Pd/TiO₂) = 340 °C, (2) T₉₀ (Pt/TiO₂) = 337 °C, and (3) T₉₀ (Rh/TiO₂) = 339 °C. In particular, Pt/TiO₂ exhibited higher low-temperature catalytic activity than those of Pd/TiO₂ and Rh/TiO₂. According to the evaluation of the COx concentration, the CO yield was lower than 1%, which indicated that CO₂ selectivity was high. The generated trend for the by-products (PhCl₂, PhCl₃, PhCl₄, etc.) is shown in Figure 3b. The maximum amounts of by-products are 65 ppm, 88 ppm, and 100 ppm at 360 °C, 340 °C, and 340 °C for Pt/TiO₂, Pd/TiO₂ and Rh/TiO₂, respectively. The Pt-based catalyst exhibited high VOC oxidation activity at temperatures ≤ 300 °C, and the use of the Rh-based catalyst was advantageous at temperatures ≥ 370 °C.

As mentioned above, most research on VOC oxidation over noble metals used Pt or Pd, which were manufactured using supports, such as TiO₂, CeO₂, Al₂O₃, and ZrO₂. It has been reported that the acid–base properties of the support typically play an important role in catalyst performance. In particular, the Pd-based catalyst has been reported to have excellent durability in the catalytic oxidation of chlorinated VOCs. Meanwhile, some researchers have reported that a combination of Pt and Pd achieved higher VOC oxidation efficiency compared to that of single metal catalysts. In the oxidation reaction over noble metal catalysts, catalytic performance varies depending on the components of VOCs and supports. Therefore the main catalyst should be selected according to their application, such as the operation temperature, VOCs concentration, and components.

4. Deactivation and Regeneration

4.1. Catalyst Poisoning and Deactivation

For industrial applications, VOC catalysts should exhibit high catalytic activity and stability. Noble metal VOC catalysts have high combustion activities, but catalysts may suffer from deactivation (via coking, poisoning, thermal sintering, etc.) of the catalysts. Nitride, chloride, and water vapor cause poisoning of the catalysts, by disabling the active sites in the catalytic combustion of VOCs.

In general, water vapor is present in most flue gases and are produced by VOC combustion reactions. Water vapor has two competing effects, either promoting VOC combustion or poisoning the catalyst [98,99]. When water molecules are adsorbed on the catalyst surface, they may induce the generation of -OH components over the catalyst by dissociation of H₂O, and additional water molecules are adsorbed through hydrogen bonding to form multi-layered water molecules. This phenomenon has two competing effects on VOC combustion. The positive effect is that the water molecules serve as a precursor of -OH to promote combustion, whereas the negative effect is that the adsorbate (water molecules) competes with VOC molecules for the active surface sites. Therefore, it is possible to optimize the water vapor effect by compromising the above competitive effects [100].

He et al. examined the effect of water vapor on the mineralization and deactivation of a VOC oxidation catalyst. The oxidation activity of VOCs is highly dependent on their hydrophobic and hydrophilic properties because they must pass through the multilayer of adsorbed water to approach the catalyst active sites.

For example, hydrophilic VOCs, such as n-propionaldehyde, n-propanol, and n-propylamine, can easily pass through the water layers to approach the catalyst surface. Meanwhile, hydrophobic VOCs, such as n-propanethiol and n-chloropropane, experience an inhibitory effect attributed to the hydrous multilayer of adsorbed water molecules [101].

CVOCs can poison catalysts by oxidizing to form chlorine, chlorides, and HCl. Chlorine partially blocks the active sites of the catalyst and the formation of active oxy-chlorinated species. In addition, Cl can inhibit catalyst activity by strong adsorption [102]. The chlorine produced by CVOC combustion can be converted to HCl through the Deacon reaction, which is the combustion reaction of chlorinated volatile organic compounds [103].

Cen et al. investigated the Cl species deactivation effect on CeO₂ (1 1 1) catalyst surfaces and identified their selectivity to HCl and Cl₂. In the combustion process of CVOCs, the higher the O₂/Cl ratio in the feed gas, the more inhibited the deactivation of the catalysts. Therefore, the introduction of the H-containing component helps to convert Cl species to HCl rather than Cl₂. In this regard, water can improve the selectivity of HCl/Cl₂ produced by the Deacon reaction. It should be noted that competitive adsorption between water vapor and oxygen may lead to the loss of catalyst activity at low temperatures [104]. Zhao et al. studied the influence of water on 1,2-dichlorobenzene combustion and analyzed the catalyst deactivation mechanism caused by water vapor [105]. Qiguang et al. reported that, in the combustion of DCM over P/CeO₂ and Ru/CeO₂ catalysts (as shown in Figure 4), the presence of water inhibits the formation of intermediates, which results in an inhibitory effect of DCM oxidation. It was confirmed that hydrogenation and dichlorination occurred when a P/CeO₂ catalyst was used in flue gas after the reaction, and chlorination and dehydrogenation occurred when a Ru/CeO₂ catalyst was used. It was reported less that catalyst deactivation occurred when Ru was present in the catalyst [106].

Nitrogen-containing VOCs (NVOCs) form intermediates, such as NO, N₂O, NH₃, and HCN, which easily cause catalyst deactivation. Pd catalysts have been reported to be unsuitable for use in the nitrile oxidation of VOCs because they produce undesirable NOx gases [107].

4.2. Catalyst Regeneration

An ideal VOC combustion catalyst is expected to have high combustion efficiency, easy regeneration, fast combustion rate, and high thermal and hydrothermal stability [22]. Although noble metal catalysts have high catalytic activity, they may suffer from deactivation (coking, poisoning, thermal sintering, and catalyst volatilization). These factors cause a decrease in the number of active sites, surface area, and plug pores, leading to deactivation of the catalyst [108].

The ability of catalyst regeneration depends on the reversibility of the deactivation process. Deactivated catalysts can be regenerated by several methods, such as heat treatment, chemical regeneration, ozone oxidation, plasma treatment, stripping, or supplying air [109,110,111]. When deactivated by carbon deposition or coking, it can be regenerated relatively easily by gasification with hydrogen, oxygen, water, or air at the required temperature [112,113,114]. Catalyst sintering is generally irreversible. However, some noble metal catalysts can be expected to recover VOC combustion efficiency by metal redispersion.

However, for the elimination of CVOCs, it is difficult to find an effective regeneration and reuse method for deactivated catalysts. The formation of volatile metal oxy-hydrochloride may lead to irreversible deactivation of the catalyst, in which the active phase is volatilized. Zhang et al. investigated the correlation between catalyst deactivation and physicochemical properties through experiments of the reaction–regeneration cycle using a LaMnO₃ perovskite catalyst [110]. With regeneration, the specific surface area and adsorbed oxygen concentration decreased, which was proposed to be due to the effect of the decrease in Mn⁴⁺ content on the surface of the catalyst. Therefore, the mobility of surface oxygen and the activation of gaseous oxygen was reduced; thus, the catalyst activity is lowered even after regeneration [115].

Oliveira et al. confirmed that, in the combustion of chlorobenzene and xylene using a catalyst prepared by impregnating Cr in bentonite, Cr reacted with HCl, Cl₂, etc. to generate volatile compounds of CrO₂Cl₂ and the active species were lost [116]. When catalysts, such as Pt/TiO₂, Pd/TiO₂, and Ru/TiO₂, were used for the combustion of DCM, -Cl species were adsorbed on the catalyst surface. The adsorbate altered the chemical structure and composition at the active site to generate inactive chlorine compounds, such as PdCl₂, PdCl₄, and PtCl₄ [108].

The reproducibility of these catalysts can be determined by several factors, such as irreversible volatilization of the active species, changes in physicochemical state, reversible chlorination, sintering, and carbon deposition. Catalysts deactivated by reversible factors can be regenerated relatively easily. In addition, the presence of water vapor during regeneration helps to remove coke and chlorine, which makes moist air more favorable for catalyst regeneration than dry air [117]. Cuicui et al. reported that the oxidation of CVOCs occurs on the catalyst and H₂O removes adsorbed chlorine through the mechanism shown in Figure 5 [118].

Pengfei et al. explored the regeneration performance and mechanism of a bimetal H-zeolite catalyst (Cu-Nb/HZSM-5) for chlorobenzene combustion. Chlorobenzene combustion occurred on the Brønsted acid sites and active copper sites. Therefore, the reason for catalyst deactivation was the formation of copper chloride and surface coke, which resulted in a loss of Brønsted acid sites. Catalyst recovery was mostly possible by converting the coke to saturated hydrocarbons or CO₂ via isothermal regeneration in air at 400 °C. In addition, copper hydrochloride can be transformed into copper oxide by the Deacon reaction with surface lattice oxygens. In particular, by supplying water vapor, the chloride and coke adsorbed on the catalyst can be comprehensively removed by further hydrolysis [119].

Currently, many catalysts that can be regenerated using heat treatment and mechanical methods are being developed. However, methodological limitations arise when irreversible catalyst deactivation occurs, and studies are being conducted to overcome this material limitation through process optimization, such as the supply of moisture.

5. Conclusions

Catalytic oxidation is used as an effective method to treat VOCs emitted by various industrial sites. Various catalysts, such as noble metals, non-noble metals, and perovskites, have been investigated for the catalytic combustion of VOCs. Noble metal catalysts are one of the most effective materials because they can be applied to VOC combustion at lower temperatures compared to other materials. The catalyst activity depends on the type of active material and the characteristics of the support. In addition, the particle size, pore size, specific surface area, structure, strength of acid sites, etc., according to the preparation method of the catalyst, may affect VOC combustion activity. This research field continues to be active. In this review, we describe recent trends in the catalytic oxidation of VOCs using noble metal catalysts. Most of the research published to date has focused on achieving remarkable results through catalyst design for low-temperature VOC combustion. Materials based on non-noble metals, such as Ce, Cu, and Mn, which are often used as supports for noble metals, have been considerably studied due to their inherent catalytic activity. However, the addition of noble metal catalysts improves VOC combustion performance at low temperatures. Nevertheless, studies on the development of catalysts for various VOC components and overcoming deactivation due to sintering, coking, and chlorine/sulfur/water poisoning are still insufficient. Therefore, additional studies related to the development of catalysts for various VOC components and the interpretation of catalyst deactivation mechanisms are required.

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Figure 1. Kinetic models of catalytic VOC oxidation: (a) L–H model, (b) E–R model, and (c) MVK model.

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Figure 2. Benzene oxidation characteristics of Ag-based catalysts: XPS profiles of (a) Co2+/Co3+ and (b) Ce3+. (c) Arrhenius plot of prepared site, and (d) conversion of benzene. Reprinted with permission from ref. [45]. Copyright 2021 Elsevier.

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Figure 3. Conversion over Pd/TiO2, Pt/TiO2, Rh/TiO2: (a) chlorobenzene conversion and (b) by-product yields. Reprinted with permission from ref. [97]. Copyright 2019 Elsevier.

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Figure 4. (a,b) Deactivation effect of catalysts by H2O in CVOC oxidation by analyzing by-products using P/CeO2 and Ru/CeO2. Reprinted with permission from ref. [106]. Copyright 2019 Elsevier.

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Figure 5. (a) Oxidation and (b) regeneration of catalysts by the H2O mechanism of CVOCs.

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