• English
    • norsk
  • English 
    • English
    • norsk
  • Login
View Item 
  •   All institutions
  • Norges teknisk-naturvitenskapelige universitet
  • Fakultet for naturvitenskap (NV)
  • Institutt for kjemisk prosessteknologi
  • View Item
  •   All institutions
  • Norges teknisk-naturvitenskapelige universitet
  • Fakultet for naturvitenskap (NV)
  • Institutt for kjemisk prosessteknologi
  • View Item
JavaScript is disabled for your browser. Some features of this site may not work without it.

Asphaltenes and Asphaltene model compounds: Adsorption, Desorption and Interfacial Rheology.

Pradilla, Diego
Doctoral thesis
Thumbnail
View/Open
Fulltext not available (Restricted access.)
Fulltext (PDF) available (9.749Mb)
Permanent link
http://hdl.handle.net/11250/2383810
Issue date
2016
Share
Metadata
Show full item record
Collections
  • Institutt for kjemisk prosessteknologi [658]
Abstract
There are numerous problems encountered during extraction, production, transportation and

refining of crude oil. Most of these problems are typically oil-specific, meaning that they

depend upon the source of the oil, and sometimes they are reservoir-specific, meaning that

they depend on the stage of extraction (primary, secondary or enhanced recovery).

Nevertheless, a great part of the problems are related to the indigenous surface-active species

such as asphaltenes, naphthenates and resins.

The definition of asphaltenes rather than being a single molecule is instead based on a

solubility class. This means that they are polydisperse in nature which leads to differences in

properties and composition. Asphaltenes are responsible for stabilizing water-in-oil

emulsions by forming a mechanically strong gel at the interface that prevents droplet

coalescence. Asphaltenes are also known to precipitate and under certain conditions

(pressure, temperature, composition) form deposit layers which could lead to plug formation.

All this issues generate deficits in flow assurance and evidently, increases in the operational

costs.

Two strategies might be implemented to further advance in the understanding of the

mechanisms involved in asphaltene adsorption onto various interfaces (liquid-liquid or solidliquid).

(i) Fractionation or (ii) model compounds. The first strategy explores the different

sub-fractions that are obtained at different solvent/precipitant ratios using indigenous

asphaltenes. The second strategy is to design a molecule, or group of molecules with defined

functionalities that mimic the main known asphaltene properties, for instance self-association

in solution and interfacial behavior.

In this thesis, the different publications were aimed to study and explore possible solutions to

the several problems stated. In the first and second publications, adsorption and desorption

aspects of asphaltenes and demulsifiers at the liquid-liquid interface were explored.

Furthermore, interactions between asphaltenes and demulsifiers were studied via interfacial

tension measurements and interfacial dilatational rheology. The results shed light on the

mechanisms involved during chemical demulsification of water-in-crude oil emulsions. In the

third publication, rheology and sorption aspects of asphaltene model compounds at the liquidliquid

interface were studied. The main goal of this publication was to establish the interfacial

properties inherent to asphaltenes captured by a set of asphaltene model compounds

developed at the Ugelstad laboratory. Similarly, in the fourth publication adsorption of asphaltenes and asphaltene model compounds onto the solid-liquid surface was studied. In

this study, the determination of the adsorption enthalpy via microcalorimetry allowed to

elucidate the type of bond and the driving force for adsorption onto surfaces of different

nature.

With these publications, a complete study at the liquid-liquid interface and the solid-liquid

surface was developed for asphaltenes and asphaltene model compounds. This provides a

fundamental framework for model systems that can be used to understand the behavior in real

applications.
Has parts
Paper 1: Pradilla Ragua, Diego Camilo; Simon, Sebastien Charles; Sjøblom, Johan. Mixed interfaces of asphaltenes and model demulsifiers part I: Adsorption and desorption of single components. Colloids and Surfaces A: Physicochemical and Engineering Aspects 2015 ;Volum 466. s. 45-56 http://dx.doi.org/ 10.1016/j.colsurfa.2014.10.051 This article is reprinted with kind permission from Elsevier, sciencedirect.com

Paper 2: Pradilla Ragua, Diego Camilo; Simon, Sebastien Charles; Sjøblom, Johan. Mixed Interfaces of Asphaltenes and Model Demulsifiers, Part II: Study of Desorption Mechanisms at Liquid/Liquid Interfaces. Energy & Fuels 2015 ;Volum 29.(9) s. 5507-5518 http://dx.doi.org/ 10.1021/acs.energyfuels.5b01302 Copyright © 2015 American Chemical Society

Paper 3: Pradilla, Diego., Simon, Sébastien., Sjöblom, Johan., Samaniuk, Joseph., Skrzypiec, Marta., Vermant, Jan. Sorption and interfacial rheology study of model asphaltene compounds. - Accepted and published in Langmuir, 2016, 32 (12), pp 2900–2911 http://dx.doi.org/ 10.1021/acs.langmuir.6b00195 Copyright © 2016 American Chemical Society

Paper 4: Pradilla, Diego., Subramanian, Sreedhar., Simon, Sébastien., Sjöblom, Johan., Beurroies, Isabelle., Denoyel, Renaud. A microcalorimetry study on the adsorption of asphaltenes and model asphaltene compounds at the liquid-solid surface. - Is not included due to copyright
Publisher
NTNU
Series
Doctoral thesis at NTNU;2016:71

Contact Us

Search NORA
Powered by DSpace software

Service from BIBSYS
 

 

Browse this CollectionIssue DateAuthorsTitlesSubjectsDocument TypesJournalsBrowse all ArchivesArchives & CollectionsIssue DateAuthorsTitlesSubjectsDocument TypesJournals

My Account

Login

Statistics

Google Analytics StatisticsView Usage Statistics

Contact Us

Search NORA
Powered by DSpace software

Service from BIBSYS