SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2010368000> ?p ?o ?g. }

Showing items 1 to 100 of ±107 with 100 items per page.

W2010368000 endingPage "2972" @default.
W2010368000 startingPage "2960" @default.
W2010368000 abstract "Abstract The reduction of sulfate to sulfide coupled with the oxidation of hydrocarbons to carbon dioxide, commonly referred to as thermochemical sulfate reduction (TSR), is an important abiotic alteration process that most commonly occurs in hot carbonate petroleum reservoirs. In the present study we focus on the role that organic labile sulfur compounds play in increasing the rate of TSR. A series of gold-tube hydrous pyrolysis experiments were conducted with n -octane and CaSO 4 in the presence of reduced sulfur (e.g. H 2 S, S°, organic S) at temperatures of 330 and 356 °C under a constant confining pressure. The in-situ pH was buffered to 3.5 (∼6.3 at room temperature) with talc and silica. For comparison, three types of oil with different total S and labile S contents were reacted under similar conditions. The results show that the initial presence of organic or inorganic sulfur compounds increases the rate of TSR. However, organic sulfur compounds, such as 1-pentanethiol or diethyldisulfide, were significantly more effective in increasing the rate of TSR than H 2 S or elemental sulfur (on a mole S basis). The increase in rate is achieved at relatively low concentrations of 1-pentanethiol, less than 1 wt% of the total n -octane, which is comparable to the concentration of organic S that is common in many oils (∼0.3 wt%). We examined several potential reaction mechanisms to explain the observed reactivity of organic LSC. First, the release of H 2 S from the thermal degradation of thiols was discounted as an important mechanism due to the significantly greater reactivity of thiol compared to an equivalent amount of H 2 S. Second, we considered the generation of olefines in association with the elimination of H 2 S during thermal degradation of thiols because olefines are much more reactive than n -alkanes during TSR. In our experiments, olefines increased the rate of TSR, but were less effective than 1-pentanethiol and other organic LSC. Third, the thermal decomposition of organic LSC creates free-radicals that in turn might initiate a radical chain-reaction that creates more reactive species. Experiments involving radical initiators, such as diethyldisulfide and benzyldisulfide, did not show an increase in reactivity compared to 1-pentanethiol. Therefore, we conclude that none of these can sufficiently explain our observations of the initial stages of TSR; they may, however, be important in the later stages. In order to gain greater insight into the potential mechanism for the observed reactivity of these organic sulfur compounds during TSR, we applied density functional theory-based molecular modeling techniques to our system. The results of these calculations indicate that 1-pentanethiol or its thermal degradation products may directly react with sulfate and reduce the activation energy required to rupture the first S–O bond through the formation of a sulfate ester. This study demonstrates the importance of labile sulfur compounds in reducing the onset timing and temperature of TSR. It is therefore essential that labile sulfur concentrations are taken into consideration when trying to make accurate predictions of TSR kinetics and the potential for H 2 S accumulation in petroleum reservoirs." @default.
W2010368000 created "2016-06-24" @default.
W2010368000 creator A5005439774 @default.
W2010368000 creator A5006144755 @default.
W2010368000 creator A5006797335 @default.
W2010368000 creator A5032499598 @default.
W2010368000 creator A5073272634 @default.
W2010368000 date "2008-06-01" @default.
W2010368000 modified "2023-10-16" @default.
W2010368000 title "The role of labile sulfur compounds in thermochemical sulfate reduction" @default.
W2010368000 cites W1634438879 @default.
W2010368000 cites W1965844431 @default.
W2010368000 cites W1970549136 @default.
W2010368000 cites W1979728293 @default.
W2010368000 cites W1997785740 @default.
W2010368000 cites W2000093983 @default.
W2010368000 cites W2000859118 @default.
W2010368000 cites W2001748810 @default.
W2010368000 cites W2010648514 @default.
W2010368000 cites W2012425818 @default.
W2010368000 cites W2014070369 @default.
W2010368000 cites W2021534482 @default.
W2010368000 cites W2023271753 @default.
W2010368000 cites W2026557438 @default.
W2010368000 cites W2028593781 @default.
W2010368000 cites W2030191756 @default.
W2010368000 cites W2030785057 @default.
W2010368000 cites W2033681646 @default.
W2010368000 cites W2033961186 @default.
W2010368000 cites W2038468368 @default.
W2010368000 cites W2040705385 @default.
W2010368000 cites W2041184157 @default.
W2010368000 cites W2054420874 @default.
W2010368000 cites W2058592444 @default.
W2010368000 cites W2060408276 @default.
W2010368000 cites W2061589819 @default.
W2010368000 cites W2066534372 @default.
W2010368000 cites W2069233298 @default.
W2010368000 cites W2085569289 @default.
W2010368000 cites W2097170311 @default.
W2010368000 cites W2127116852 @default.
W2010368000 cites W2143981217 @default.
W2010368000 cites W2150925076 @default.
W2010368000 cites W2153227345 @default.
W2010368000 cites W2160121378 @default.
W2010368000 doi "https://doi.org/10.1016/j.gca.2008.03.022" @default.
W2010368000 hasPublicationYear "2008" @default.
W2010368000 type Work @default.
W2010368000 sameAs 2010368000 @default.
W2010368000 citedByCount "101" @default.
W2010368000 countsByYear W20103680002012 @default.
W2010368000 countsByYear W20103680002013 @default.
W2010368000 countsByYear W20103680002014 @default.
W2010368000 countsByYear W20103680002015 @default.
W2010368000 countsByYear W20103680002016 @default.
W2010368000 countsByYear W20103680002017 @default.
W2010368000 countsByYear W20103680002018 @default.
W2010368000 countsByYear W20103680002019 @default.
W2010368000 countsByYear W20103680002020 @default.
W2010368000 countsByYear W20103680002021 @default.
W2010368000 countsByYear W20103680002022 @default.
W2010368000 countsByYear W20103680002023 @default.
W2010368000 crossrefType "journal-article" @default.
W2010368000 hasAuthorship W2010368000A5005439774 @default.
W2010368000 hasAuthorship W2010368000A5006144755 @default.
W2010368000 hasAuthorship W2010368000A5006797335 @default.
W2010368000 hasAuthorship W2010368000A5032499598 @default.
W2010368000 hasAuthorship W2010368000A5073272634 @default.
W2010368000 hasConcept C107872376 @default.
W2010368000 hasConcept C111335779 @default.
W2010368000 hasConcept C178790620 @default.
W2010368000 hasConcept C179104552 @default.
W2010368000 hasConcept C185592680 @default.
W2010368000 hasConcept C2524010 @default.
W2010368000 hasConcept C2778343803 @default.
W2010368000 hasConcept C33923547 @default.
W2010368000 hasConcept C518881349 @default.
W2010368000 hasConceptScore W2010368000C107872376 @default.
W2010368000 hasConceptScore W2010368000C111335779 @default.
W2010368000 hasConceptScore W2010368000C178790620 @default.
W2010368000 hasConceptScore W2010368000C179104552 @default.
W2010368000 hasConceptScore W2010368000C185592680 @default.
W2010368000 hasConceptScore W2010368000C2524010 @default.
W2010368000 hasConceptScore W2010368000C2778343803 @default.
W2010368000 hasConceptScore W2010368000C33923547 @default.
W2010368000 hasConceptScore W2010368000C518881349 @default.
W2010368000 hasIssue "12" @default.
W2010368000 hasLocation W20103680001 @default.
W2010368000 hasOpenAccess W2010368000 @default.
W2010368000 hasPrimaryLocation W20103680001 @default.
W2010368000 hasRelatedWork W1808033642 @default.
W2010368000 hasRelatedWork W2005262727 @default.
W2010368000 hasRelatedWork W2008799222 @default.
W2010368000 hasRelatedWork W2032251068 @default.
W2010368000 hasRelatedWork W2038553215 @default.
W2010368000 hasRelatedWork W2144402991 @default.
W2010368000 hasRelatedWork W2593007083 @default.
W2010368000 hasRelatedWork W3051865640 @default.