Jump to content

User:Taylormryan/sandbox

From Wikipedia, the free encyclopedia

*Material in this sandbox have been inserted into three separate existing Wikipedia pages: Nail polish, Dibutyl phthalate, and Toluene toxicity. Headings and sub-headings are included in this sandbox like they are in each of the existing Wikipedia pages they belong to.*

Nail polish

[edit]

Environmental safety

[edit]

Regulation and environmental concerns

[edit]

As previously mentioned, nail polish is a household hazardous waste (HHW) that should not be disposed of in the trash, but must be disposed of properly[1]. Nail polish is a HHW primarily because it contains dibutyl phthalate, toluene, and formaldehyde, otherwise known as the "toxic trio." In the United States, there are an estimated 117 million nail polish users[2]. Dibutyl phthalate has been studied extensively and is proven to be an endocrine disruptor, as well as a compound that can decrease birth weight, decrease survival of newborns, reduce sperm count, and also promote testicular atrophy[3][4]. The photochemical oxidation of toluene contributes to tropospheric ozone and secondary organic aerosol (SOA) formation, which has been reported to have effects on air quality, human health, and the climate[5].

Dibutyl phthalate

[edit]

Environmental relevance

[edit]

Fundamental environmental chemistry

[edit]

Dibutyl phthalate (DBP) is one of the six phthalic acid esters found on the Priority Pollutant List, which consists of specified chemical pollutants regulated by the United States Environmental Protection Agency (EPA) [6]. Chemically, phthalate esters are diesters of ophthalmic anhydride; their plasticizing properties can be advantageous for use in cosmetics, fragrances, insect repellants, upholstery, and more. Typically, phthalate esters such as dibutyl phthalate are not covalently bound to the polymer of the plastic they are adhered to and therefore, can easily leach out of that component (i.e. nail polish) and into municipal waters [7]. Overall, DBP can be released into each sector of the environment—water, soil, and air—via leaching, microbial degradation, and photocatalytic oxidation. As water percolates throughout landfill sediment, DBP is leached into the surrounding environment [8]. However, due to the fact that DBP holds a density less than that of water, a thin surface film forms at the air-water interface. Analyses of DBP's octanol-water partition coefficient using high pressure liquid chromatography has concluded on several values that represent the compound’s hydrophobicity. Moreover, the constant can be utilized to define DBP’s ability to partition in animal lipids, sediment, and soil organic matter [9].

Octanol-Water Partition Coefficient (Log Kow)
Dibutyl Phthalate 4.11 4.31 4.46

Dissolved organic carbon

[edit]

DBP is a hydrophobic compound that has a low solubility in water. However, different interactions with dissolved organic carbon (DOC) can have solubilizing effects on DBP and increase its mobility in places it is commonly found, such as in landfills [10]. DOC is known to increase DBP’s water solubility by interacting in two ways: by changing the equilibrium distribution of the solute (DBP) and by direct interaction with DBP. In the first interaction, DBP’s sorption coefficient is lowered when partially water-miscible substances change the equilibrium distribution of DBP between its solid and liquid phase. These partially water-miscible substances are typically alcohols and are also known as cosolvents. The result of this is an increase in DBP’s mobility, but this interaction requires high concentrations of DBP to take place. Increased solubility of DBP is more likely to occur by the second interaction which involves a direct interaction between DBP and other organic compounds. DBP becomes more polar and water soluble after interaction with these typically polar organic compounds found in landfills. DBP can then bind to DOC in a partition-like interaction where the hydrophobic moeitities of DBP and DOC bind each other in a micelle-like structure within an amphiphilic macromolecule. Studies have shown that in some landfill leachates, 85% of phthalate esters are found in their solubilized form due to DOC [11].

Hydrolysis of DBP

[edit]

DBP and other phthalates found in landfills are known to undergo both acid and base catalyzed hydrolysis. Xenobiotic substances like DBP are commonly degraded by hydrolysis reactions [12]. Metal ions, anions, and organic materials can all serve as catalysts for these acid- or base-catalyzed hydrolysis reactions. In both the acid- and base-catalyzed reactions, DBP is first hydrolyzed to a monoester form that contains a carboxylic acid, and 1-butanol is released. The monoester is then hydrolyzed to form phthalic acid, and a second 1-butanol is released. The overall reaction requires two molecules of H2O and either a base or acid working as the catalyst. This hydrolysis reaction is both pH and temperature dependent in landfills. It occurs readily in the deeper layers of landfills, where temperatures are high and acidic or basic conditions are prevalent. In addition, the reactants tend to mimic their gas-phase structure in these deeper layers, which decreases steric effects during this ester hydrolysis. However, the rate of this reaction is negligible at the surface of landfills due to low temperatures and neutral pH conditions. At pH 7, esters tend to be less electrophilic and less susceptible to hydrolysis [12]. This is one of the primary reasons why DBP concentrations can be elevated on or near the surface of landfills relative to the deeper layers. These elevated concentrations create a cause for concern due to the possibility of the chemical leaching into the surrounding environment.

Acid/Base Catalyzed Hydrolysis of DBP
Acid/Base Catalyzed Hydrolysis of DBP

Photocatalytic degradation of DBP

[edit]

DBP can also be photochemically degraded with the help of titanium dioxide (TiO2) [13].

TiO2 + hv > 5.13 x 10-19 J TiO2(e-cb/h+vb) e-cb + h+vb (1)

h+vb + OH- (or H2O)surface OH(+H+) (2)

e-cb + O2 O2•− + H+ OOH (3)

TiO2 first absorbs UV light at wavelengths below 3.87 x 10-7 m (or with an energy greater than 5.13 x 10-19 J). This reaction produces electron-hole pairs which will react independently. The conduction band electrons (e-cb) react with dioxygen molecules to produce a superoxide radical anion, ·O2·-. The superoxide radical anion is then protonated to form a hydroperoxide radical (·OOH). The holes (h+) can react with either hydroxyl ions (OH-) or surface water found on the TiO2 particulate to produce a hydroxyl radical (·OH) and a hydrogen ion (H+). Once the hydroxyl radical and hydroperoxide radical are generated, they can attack either the aromatic ring or one of the aliphatic side chains of DBP. There is currently no way of determining the preference a radical has to attack either site, making the reaction more complex. Depending on where the radical attack occurs, and which radical is responsible for the attack, a number of intermediates can be formed. The complex group of intermediates are also subject to radical attacks, which forms acetaldehyde, acetic acid, or formic acid. These aliphatic intermediates can then be attacked by either radical, resulting in slow CO2 mineralization and water formation. However, the TiO2 mediated photochemical degradation of DBP occurs at an almost negligible rate in landfills. This is due to other existing organic compounds, such as acetone, that are commonly found in landfills at higher concentrations than DBP [13]. These existing organic compounds compete with DBP for the attack by a radical such as the two mentioned above. This too can lead to increased concentrations of DBP found on or near the surface of landfills that leach into the surrounding environment.

Titanium Oxide Mediated Photocatalytic Degradation of DBP
Titanium Oxide Mediated Photocatalytic Degradation of DBP

DBP leaching

[edit]

From the surface film, DBP has a very small tendency to volatilize into the atmosphere due to a vapor pressure of 2.67 x 10-3 Pa [7] and a Henry’s Law constant of 8.83 x 10-7 atm-m3/mol [12]. Rainfall transfers phthalate esters in the atmosphere to fresh water, and their accumulation here causes their wide distribution in rivers and lakes. The partitioning behavior of DBP characterizes the ability of the compound to separate from the air, which is a process catalyzed by washout. Either rain or snow is responsible for the process. The washout ratio (W) defines the ratio of chemical concentrations in rain or snow to that in air as defined by the following equation:

W = (1-f) Wv + f Wp = (1-f) RT/H + f Wp

where Wv is the vapor washout ratio, RT/H is the reciprocal of Henry’s Law constant, Wp is the particle scavenging coefficient, and f is the fraction of chemical on the particulate. Dibutyl phthalate displays a washout ratio (W) of 2.8 x 10-4 with a f of 0.014. Studies have indicated that DBP functions by a “temperature-dependent phenomena” whereby it is in the colder winter months that the vapor pressure of the compound is reduced sufficiently in order to produce an efficient washout ratio. Moreover, because of the hydrophobicity of phthalate esters, their chemical composition permits their sorption into soil and sediment among other environmental components [12]. Upon release into the environment, dibutyl phthalate is able to interact with environmental media in ways that change their chemical behavior [6].

Agencies have begun to delve into implementing affordable and resourceful methods of treating water supplies to decrease the concentration of the plasticizer components in rivers and lakes. First, adsorption to remove organic compounds has been extensively researched by the EPA whereby activated carbon is used to treat water consumed by humans. Another method under current investigation is the biological avenue which utilizes populations of microorganisms to degrade the esters. For example, Enterobacter species can biodegrade municipal solid waste—where the DBP concentration can be observed at 1500 ppm—with a half-life of 1.04 x 105 seconds. In comparison, the same species can break down 100% of dimethyl phthalate after a span of six days. However, this treatment method varies significantly depending on temperature, anaerobic and aerobic conditions, and more [14].

Toluene toxicity

[edit]

Environmental relevance

[edit]

Fundamental environmental chemistry

[edit]

Toluene, also known as methylbenzene, is one of the three chemicals that make up the "toxic trio" commonly found in nail polish. It has a relatively high vapor pressure of 3.79 x 103 Pa at 298.15 K and is a volatile liquid at room temperature [15]. It rapidly volatizes into the air and therefore is classified as a volatile organic compound. The path of toluene from disposed nail polish to the atmosphere is a relatively simple one due to its volatile nature. Once in a landfill, toluene can enter the soil and water in surrounding areas. From here, it will then readily evaporate into the atmosphere. However, the rate at which volatilization occurs depends on the conditions of the soil, such as temperature, humidity, and soil type. Once vapor phase toluene is free in the atmosphere, it is subject to react with photochemically-produced hydroxyl radicals, nitrate radicals, and ozone molecules [16].

Toluene and photochemically-produced hydroxyl radicals

[edit]

Hydroxyl radicals are formed via a two-step reaction (reactions 1 and 2). The first step is the photolysis of gaseous ozone which employs solar energy and results in diatomic oxygen gas and an oxygen atom in its excited state. The electronically excited oxygen atom has sufficient excitation energy to now react with water vapor, producing hydroxyl radicals [17][18].

Reaction (1):   O3 + hv O(1D) + O2

Reaction (2):   O(1D) + H2O 2OH

The initial reaction of toluene with a hydroxyl radical includes direct OH addition to the ortho position of the benzene ring and results in an ortho OH-toluene adduct (also known as methylhydroxycyclohexadienyl radical). The adduct subsequently reacts with atmospheric O2 via three possible pathways, however, the third will not be discussed as it has been proven to be thermodynamically and kinetically inhibited. The first pathway, upon reaction with O2, forms a primary organic peroxy radical (RO2) via O2 addition. The second pathway, upon reaction with O2, forms the phenolic compound O-cresol and hydroperoxy radicals (HO2) via hydrogen abstraction [19].

Both RO2 (reaction 3) and HO2 (reaction 4) products generated react with nitric oxide (NO) to form nitrogen dioxide (NO2) which subsequently undergoes photodissociation to produce ground-state oxygen atoms that recombine with molecular oxygen to produce tropospheric ozone (reactions 5 and 6) [20][21][22]. Tropospheric ozone, also known as “bad” ozone, functions as an air pollutant that is harmful to humans and vegetation, the main ingredient in smog, and a greenhouse gas [23]. In terms of ozone formed from toluene oxidation, the RO2 pathway contributes 65% and the HO2 pathway contributes 18% [19].

Reaction (3):   RO2 + NO RO + NO2

Reaction (4):   HO2 + NO OH + NO2

Reaction (5):   NO2 + hv NO + O·

Reaction (6):   O· + O2 + M O3 + M

Toluene and nitrate radicals

[edit]

Nitrate radicals are formed when anthropogenic NO2 gas, commonly emitted by industrial sources, reacts with atmospheric ozone (reaction 7). Nitrate radicals are known as a “night-time oxidizer” as its nighttime concentration is nearly twice the concentration of the hydroxyl radical during the daytime [24].

Reaction (7):   NO2 + O3 NO3 + O2

Nitrate radicals oxidize toluene either by the abstraction of the alpha-hydrogen atom, shown on top, or by the transfer of an electron, shown on bottom. These reactions result in nitric acid (HNO3) and nitrate (NO3-) (i.e. a strong acid and its conjugate base) [25].

Nitric acid exists in the atmosphere in its gas phase and can react with gaseous ammonia to form particulate or aerosol nitrate. Nitric acid is highly corrosive, and if concentrated in the environment, it can react rapidly with other natural or anthropogenic environmental compounds. These reactions can occur so rapidly that they result in a chemical fire or explosion [26]. Nitrate is highly soluble in the environment which enables the compound to easily move with soil water towards plant roots and to inhabit surface water and ground water. The pollution of bodies of water with excess nitrate from the atmosphere may lead to hypoxia. The compound promotes rapid algae growth, which then results in reduced oxygen water levels making it difficult for marine species to survive [27].

See also

[edit]

References

[edit]
  1. ^ "Household Hazardous Waste | Pacific Southwest: Solid Waste | US EPA". www3.epa.gov. Retrieved 2017-11-28.
  2. ^ "U.S.: Usage of nail polish and nail care products 2016 | Statistic". Statista. Retrieved 2017-11-28.
  3. ^ Kaneco, Satoshi; Katsumata, Hideyuki; Suzuki, Tohru; Ohta, Kiyohisa. "Titanium dioxide mediated photocatalytic degradation of dibutyl phthalate in aqueous solution—kinetics, mineralization and reaction mechanism". Chemical Engineering Journal. 125 (1): 59–66. doi:10.1016/j.cej.2006.08.004.
  4. ^ Liu, Hui; Liang, Ying; Zhang, Dan; Wang, Cheng; Liang, Hecheng; Cai, Hesheng. "Impact of MSW landfill on the environmental contamination of phthalate esters". Waste Management. 30 (8–9): 1569–1576. doi:10.1016/j.wasman.2010.01.040.
  5. ^ Ji, Yuemeng; Zhao, Jun; Terazono, Hajime; Misawa, Kentaro; Levitt, Nicholas P.; Li, Yixin; Lin, Yun; Peng, Jianfei; Wang, Yuan (2017-08-01). "Reassessing the atmospheric oxidation mechanism of toluene". Proceedings of the National Academy of Sciences. 114 (31): 8169–8174. doi:10.1073/pnas.1705463114. ISSN 0027-8424. PMID 28716940.
  6. ^ a b Gao, Da-Wen; Wen, Zhi-Dan. "Phthalate esters in the environment: A critical review of their occurrence, biodegradation, and removal during wastewater treatment processes". Science of The Total Environment. 541: 986–1001. doi:10.1016/j.scitotenv.2015.09.148.
  7. ^ a b Donovan, Stephen F. "New method for estimating vapor pressure by the use of gas chromatography". Journal of Chromatography A. 749 (1–2): 123–129. doi:10.1016/0021-9673(96)00418-9.
  8. ^ Kjeldsen, Peter; Barlaz, Morton A.; Rooker, Alix P.; Baun, Anders; Ledin, Anna; Christensen, Thomas H. (2002-10-01). "Present and Long-Term Composition of MSW Landfill Leachate: A Review". Critical Reviews in Environmental Science and Technology. 32 (4): 297–336. doi:10.1080/10643380290813462. ISSN 1064-3389.
  9. ^ Council, National Research (2001-11-30). Ozone and Other Photochemical Oxidants. doi:10.17226/19914.
  10. ^ Christensen, Thomas H; Kjeldsen, Peter; Bjerg, Poul L; Jensen, Dorthe L; Christensen, Jette B; Baun, Anders; Albrechtsen, Hans-Jørgen; Heron, Gorm. "Biogeochemistry of landfill leachate plumes". Applied Geochemistry. 16 (7–8): 659–718. doi:10.1016/s0883-2927(00)00082-2.
  11. ^ Bauer, M.J.; Herrmann, R. (2016-07-02). "Dissolved organic carbon as the main carrier of phthalic acid esters in municipal landfill leachates". Waste Management & Research. 16 (5): 446–454. doi:10.1177/0734242x9801600507.
  12. ^ a b c d Huang, Jingyu; Nkrumah, Philip N.; Li, Yi; Appiah-Sefah, Gloria (2013). Reviews of Environmental Contamination and Toxicology Volume 224. Reviews of Environmental Contamination and Toxicology. Springer, New York, NY. pp. 39–52. doi:10.1007/978-1-4614-5882-1_2. ISBN 9781461458814.
  13. ^ a b Kaneco, Satoshi; Katsumata, Hideyuki; Suzuki, Tohru; Ohta, Kiyohisa. "Titanium dioxide mediated photocatalytic degradation of dibutyl phthalate in aqueous solution—kinetics, mineralization and reaction mechanism". Chemical Engineering Journal. 125 (1): 59–66. doi:10.1016/j.cej.2006.08.004.
  14. ^ Abdel daiem, Mahmoud M.; Rivera-Utrilla, José; Ocampo-Pérez, Raúl; Méndez-Díaz, José D.; Sánchez-Polo, Manuel. "Environmental impact of phthalic acid esters and their removal from water and sediments by different technologies – A review". Journal of Environmental Management. 109: 164–178. doi:10.1016/j.jenvman.2012.05.014.
  15. ^ Pubchem. "toluene". pubchem.ncbi.nlm.nih.gov. Retrieved 2017-11-27.
  16. ^ "Explore Nature (U.S. National Park Service)". www.nps.gov. Retrieved 2017-11-27.
  17. ^ Gligorovski, Sasho; Strekowski, Rafal; Barbati, Stephane; Vione, Davide (2015-12-23). "Environmental Implications of Hydroxyl Radicals (•OH)". Chemical Reviews. 115 (24): 13051–13092. doi:10.1021/cr500310b. ISSN 0009-2665.
  18. ^ MacPhail, R. A.; Strauss, H. L.; Snyder, R. G.; Elliger, C. A. (1984-02-01). "Carbon-hydrogen stretching modes and the structure of n-alkyl chains. 2. Long, all-trans chains". The Journal of Physical Chemistry. 88 (3): 334–341. doi:10.1021/j150647a002. ISSN 0022-3654.
  19. ^ a b Ji, Yuemeng; Zhao, Jun; Terazono, Hajime; Misawa, Kentaro; Levitt, Nicholas P.; Li, Yixin; Lin, Yun; Peng, Jianfei; Wang, Yuan (2017-08-01). "Reassessing the atmospheric oxidation mechanism of toluene". Proceedings of the National Academy of Sciences. 114 (31): 8169–8174. doi:10.1073/pnas.1705463114. ISSN 0027-8424. PMID 28716940.
  20. ^ Tokumura, Kunihiro; Oyama, Osamu; Mukaihata, Hiromi; Itoh, Michiya (1997-02-01). "Rotational Isomerization of Phototautomer Produced in the Excited-State Proton Transfer of 2,2'-Bipyridin-3-ol". The Journal of Physical Chemistry A. 101 (8): 1419–1421. doi:10.1021/jp962540h. ISSN 1089-5639.
  21. ^ Global atmospheric change and its impact on regional air quality. Barnes, I. Dordrecht: Kluwer Academic Publishers. 2002. ISBN 9781402009587. OCLC 50725327.{{cite book}}: CS1 maint: others (link)
  22. ^ Crutzen, P J (1979-05-01). "The Role of NO and NO2 in the Chemistry of the Troposphere and Stratosphere". Annual Review of Earth and Planetary Sciences. 7 (1): 443–472. doi:10.1146/annurev.ea.07.050179.002303. ISSN 0084-6597.
  23. ^ Logan, Jennifer A. (1985-10-20). "Tropospheric ozone: Seasonal behavior, trends, and anthropogenic influence". Journal of Geophysical Research: Atmospheres. 90 (D6): 10463–10482. doi:10.1029/jd090id06p10463. ISSN 2156-2202.
  24. ^ Khan, M. a. H.; Jenkin, M. E.; Foulds, A.; Derwent, R. G.; Percival, C. J.; Shallcross, D. E. (2017-04-27). "A modeling study of secondary organic aerosol formation from sesquiterpenes using the STOCHEM global chemistry and transport model". Journal of Geophysical Research: Atmospheres. 122 (8): 2016JD026415. doi:10.1002/2016jd026415. ISSN 2169-8996.
  25. ^ Baciocchi, E.; Giacco, T. Del; Murgia, S. M.; Sebastiani, G. V. (1987-01-01). "Rate and mechanism for the reaction of the nitrate radical with aromatic and alkylaromatic compounds in acetonitrile". Journal of the Chemical Society, Chemical Communications. 0 (16). doi:10.1039/c39870001246. ISSN 0022-4936.
  26. ^ "Nitric acid | National Pollutant Inventory". www.npi.gov.au. Retrieved 2017-11-27.
  27. ^ PG, Mr. Brian Oram,. "Water Research Center - Nitrogen effects on surface and groundwater quality". www.water-research.net. Retrieved 2017-11-27.{{cite web}}: CS1 maint: extra punctuation (link) CS1 maint: multiple names: authors list (link)