Lithium Extraction From North Sea Oilfield Brines Using Ion Exchange Membranes

Botelho Disu; Roozbeh Rafati; Amin Sharifi Haddad; Nabihah Fierus

doi:10.2118/215585-MS

Lithium Extraction From North Sea Oilfield Brines Using Ion Exchange Membranes

Botelho Disu, Roozbeh Rafati, Amin Sharifi Haddad, Nabihah Fierus

Engineering

Research output: Chapter in Book/Report/Conference proceeding › Published conference contribution

Abstract

The annual demand for lithium for low-carbon technologies applications has been trading exponentially forward, 965% more in 2050 than the quantity demanded in 2017. In the current chain of demand, there is a necessity for continuous lithium production from both conventional sources (i.e., salt lakes and rock minerals) as well as the incorporation of novel extraction sites from alternative brine resources such as Oilfield and Geothermal. In the present paper, the lithium potentiality of the North Sea is evaluated with fields in the Central-East and Southern-West reaching the highest regional concentration of 40 ppm. Those include oilfields such as Montrose, Arbroath, Ula, Nelson, Brisling, Gyda, Ekofisk and Bream, as well as gas fields such as the Esmond, Anglia, Lemman, Ann, and Viking, with the possibility of brine enrichment extending itself even to shallow waters fields around the Groningen region. To experimentally evaluate the potential extractability of lithium from those oilfield brine resources in the North Sea, ion-sieve adsorbents (Li1.6Mn1.6O4) were prepared from commercially available LiMnO2 and formed into three different ion-exchange membranes. The foam had the best performance out of those structures, displaying a higher and much stabler powder insertion capacity compared to granular and flat sheet membranes, which registered significant material loss. At an optimum polymeric concentration of 10% and MNO/PVA ratio of about 50%, the foam membrane had the highest theoretical extraction capacity of 9.94 mg/g, followed by granular and flat sheet, with 7.36 and 7.24 mg/g, respectively. Those membranes had good selectivity forward lithium ion in the presence of other competing cations when used on synthetic oilfield brine with concentration mimicking that of Buchan field, being able to efficiently recover 18.4% (foam), 17% (granular), and 14.37% (flat sheet) of lithium. However, the recovery capacity was increased up to 50% when non-formed HMO powder was used, with selectivity in the following decreased order of affinity, Li+ > Mg2+ > Na+ > Ca2+ > K+. The powder recoverability raises the lithium production prospect from North Sea brine to about 26.2 kg per day with an estimated market value of 1834 USD for the produced quantity.

Original language	English
Title of host publication	SPE Offshore Europe Conference & Exhibition
Publisher	OnePetro
Number of pages	19
DOIs	https://doi.org/10.2118/215585-MS
Publication status	Published - 5 Sept 2023
Event	SPE Offshore Europe 2023 - https://www.offshore-europe.co.uk/en-gb/spe-conference.html, Aberdeen, United Kingdom Duration: 5 Sept 2023 → 8 Sept 2023

Conference

Conference	SPE Offshore Europe 2023
Country/Territory	United Kingdom
City	Aberdeen
Period	5/09/23 → 8/09/23

Bibliographical note

Paper presented at the SPE Offshore Europe Conference & Exhibition, Aberdeen, Scotland, UK, September 2023.

Acknowledgments
We would like to use this opportunity to extend our gratitude to Professor Jan Skakle, whose expertise and guidance on XRD analysis helped us to overcome challenges and attain the optimal conditions for the crystallization of the manganese oxide ion-sieve structure. We also want to acknowledge Mr. Vali Mehdipour's contribution to the North Sea brine mineral analysis with Petrel software.

Keywords

sedimentary rock
united kingdom government
united states government
social responsibility
metals & mining
sustainability
mineral
enhanced recovery
geologist
geology

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Cite this

@inproceedings{eec87ae5716941ae8af8c0bade63ff32,

title = "Lithium Extraction From North Sea Oilfield Brines Using Ion Exchange Membranes",

abstract = "The annual demand for lithium for low-carbon technologies applications has been trading exponentially forward, 965% more in 2050 than the quantity demanded in 2017. In the current chain of demand, there is a necessity for continuous lithium production from both conventional sources (i.e., salt lakes and rock minerals) as well as the incorporation of novel extraction sites from alternative brine resources such as Oilfield and Geothermal. In the present paper, the lithium potentiality of the North Sea is evaluated with fields in the Central-East and Southern-West reaching the highest regional concentration of 40 ppm. Those include oilfields such as Montrose, Arbroath, Ula, Nelson, Brisling, Gyda, Ekofisk and Bream, as well as gas fields such as the Esmond, Anglia, Lemman, Ann, and Viking, with the possibility of brine enrichment extending itself even to shallow waters fields around the Groningen region. To experimentally evaluate the potential extractability of lithium from those oilfield brine resources in the North Sea, ion-sieve adsorbents (Li1.6Mn1.6O4) were prepared from commercially available LiMnO2 and formed into three different ion-exchange membranes. The foam had the best performance out of those structures, displaying a higher and much stabler powder insertion capacity compared to granular and flat sheet membranes, which registered significant material loss. At an optimum polymeric concentration of 10% and MNO/PVA ratio of about 50%, the foam membrane had the highest theoretical extraction capacity of 9.94 mg/g, followed by granular and flat sheet, with 7.36 and 7.24 mg/g, respectively. Those membranes had good selectivity forward lithium ion in the presence of other competing cations when used on synthetic oilfield brine with concentration mimicking that of Buchan field, being able to efficiently recover 18.4% (foam), 17% (granular), and 14.37% (flat sheet) of lithium. However, the recovery capacity was increased up to 50% when non-formed HMO powder was used, with selectivity in the following decreased order of affinity, Li+ > Mg2+ > Na+ > Ca2+ > K+. The powder recoverability raises the lithium production prospect from North Sea brine to about 26.2 kg per day with an estimated market value of 1834 USD for the produced quantity.",

keywords = "sedimentary rock, united kingdom government, united states government, social responsibility, metals & mining, sustainability, mineral, enhanced recovery, geologist, geology",

author = "Botelho Disu and Roozbeh Rafati and Haddad, {Amin Sharifi} and Nabihah Fierus",

note = "Paper presented at the SPE Offshore Europe Conference & Exhibition, Aberdeen, Scotland, UK, September 2023. Acknowledgments We would like to use this opportunity to extend our gratitude to Professor Jan Skakle, whose expertise and guidance on XRD analysis helped us to overcome challenges and attain the optimal conditions for the crystallization of the manganese oxide ion-sieve structure. We also want to acknowledge Mr. Vali Mehdipour's contribution to the North Sea brine mineral analysis with Petrel software.; SPE Offshore Europe 2023 ; Conference date: 05-09-2023 Through 08-09-2023",

year = "2023",

month = sep,

day = "5",

doi = "10.2118/215585-MS",

language = "English",

booktitle = "SPE Offshore Europe Conference & Exhibition",

publisher = "OnePetro",

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T1 - Lithium Extraction From North Sea Oilfield Brines Using Ion Exchange Membranes

AU - Disu, Botelho

AU - Rafati, Roozbeh

AU - Haddad, Amin Sharifi

AU - Fierus, Nabihah

N1 - Paper presented at the SPE Offshore Europe Conference & Exhibition, Aberdeen, Scotland, UK, September 2023. Acknowledgments We would like to use this opportunity to extend our gratitude to Professor Jan Skakle, whose expertise and guidance on XRD analysis helped us to overcome challenges and attain the optimal conditions for the crystallization of the manganese oxide ion-sieve structure. We also want to acknowledge Mr. Vali Mehdipour's contribution to the North Sea brine mineral analysis with Petrel software.

PY - 2023/9/5

Y1 - 2023/9/5

N2 - The annual demand for lithium for low-carbon technologies applications has been trading exponentially forward, 965% more in 2050 than the quantity demanded in 2017. In the current chain of demand, there is a necessity for continuous lithium production from both conventional sources (i.e., salt lakes and rock minerals) as well as the incorporation of novel extraction sites from alternative brine resources such as Oilfield and Geothermal. In the present paper, the lithium potentiality of the North Sea is evaluated with fields in the Central-East and Southern-West reaching the highest regional concentration of 40 ppm. Those include oilfields such as Montrose, Arbroath, Ula, Nelson, Brisling, Gyda, Ekofisk and Bream, as well as gas fields such as the Esmond, Anglia, Lemman, Ann, and Viking, with the possibility of brine enrichment extending itself even to shallow waters fields around the Groningen region. To experimentally evaluate the potential extractability of lithium from those oilfield brine resources in the North Sea, ion-sieve adsorbents (Li1.6Mn1.6O4) were prepared from commercially available LiMnO2 and formed into three different ion-exchange membranes. The foam had the best performance out of those structures, displaying a higher and much stabler powder insertion capacity compared to granular and flat sheet membranes, which registered significant material loss. At an optimum polymeric concentration of 10% and MNO/PVA ratio of about 50%, the foam membrane had the highest theoretical extraction capacity of 9.94 mg/g, followed by granular and flat sheet, with 7.36 and 7.24 mg/g, respectively. Those membranes had good selectivity forward lithium ion in the presence of other competing cations when used on synthetic oilfield brine with concentration mimicking that of Buchan field, being able to efficiently recover 18.4% (foam), 17% (granular), and 14.37% (flat sheet) of lithium. However, the recovery capacity was increased up to 50% when non-formed HMO powder was used, with selectivity in the following decreased order of affinity, Li+ > Mg2+ > Na+ > Ca2+ > K+. The powder recoverability raises the lithium production prospect from North Sea brine to about 26.2 kg per day with an estimated market value of 1834 USD for the produced quantity.

AB - The annual demand for lithium for low-carbon technologies applications has been trading exponentially forward, 965% more in 2050 than the quantity demanded in 2017. In the current chain of demand, there is a necessity for continuous lithium production from both conventional sources (i.e., salt lakes and rock minerals) as well as the incorporation of novel extraction sites from alternative brine resources such as Oilfield and Geothermal. In the present paper, the lithium potentiality of the North Sea is evaluated with fields in the Central-East and Southern-West reaching the highest regional concentration of 40 ppm. Those include oilfields such as Montrose, Arbroath, Ula, Nelson, Brisling, Gyda, Ekofisk and Bream, as well as gas fields such as the Esmond, Anglia, Lemman, Ann, and Viking, with the possibility of brine enrichment extending itself even to shallow waters fields around the Groningen region. To experimentally evaluate the potential extractability of lithium from those oilfield brine resources in the North Sea, ion-sieve adsorbents (Li1.6Mn1.6O4) were prepared from commercially available LiMnO2 and formed into three different ion-exchange membranes. The foam had the best performance out of those structures, displaying a higher and much stabler powder insertion capacity compared to granular and flat sheet membranes, which registered significant material loss. At an optimum polymeric concentration of 10% and MNO/PVA ratio of about 50%, the foam membrane had the highest theoretical extraction capacity of 9.94 mg/g, followed by granular and flat sheet, with 7.36 and 7.24 mg/g, respectively. Those membranes had good selectivity forward lithium ion in the presence of other competing cations when used on synthetic oilfield brine with concentration mimicking that of Buchan field, being able to efficiently recover 18.4% (foam), 17% (granular), and 14.37% (flat sheet) of lithium. However, the recovery capacity was increased up to 50% when non-formed HMO powder was used, with selectivity in the following decreased order of affinity, Li+ > Mg2+ > Na+ > Ca2+ > K+. The powder recoverability raises the lithium production prospect from North Sea brine to about 26.2 kg per day with an estimated market value of 1834 USD for the produced quantity.

KW - sedimentary rock

KW - united kingdom government

KW - united states government

KW - social responsibility

KW - metals & mining

KW - sustainability

KW - mineral

KW - enhanced recovery

KW - geologist

KW - geology

U2 - 10.2118/215585-MS

DO - 10.2118/215585-MS

M3 - Published conference contribution

BT - SPE Offshore Europe Conference & Exhibition

PB - OnePetro

T2 - SPE Offshore Europe 2023

Y2 - 5 September 2023 through 8 September 2023

ER -

Lithium Extraction From North Sea Oilfield Brines Using Ion Exchange Membranes

Abstract

Conference

Bibliographical note

Keywords

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