Application of composites of graphene derivatives and conducting polymers in solid-state electrochemical sensors

Tom Lindfors; Zhanna Boeva; Konstantin Milakin; Anna Österholm

Application of composites of graphene derivatives and conducting polymers in solid-state electrochemical sensors

Tom Lindfors^*, Zhanna Boeva, Konstantin Milakin, Anna Österholm

^*Tämän työn vastaava kirjoittaja

Tutkimustuotos: Konferenssiin myötävaikuttaminen › Ilmoitus › Tieteellinen

Abstrakti

We report the incorporation of few-layer graphene (< 3 monolayers), graphene oxide (GO), reduced graphene oxide (RGO) or exfoliated graphite in electrically conducting polyaniline (PANI) and poly(3,4-ethylenedioxythiophene) matrices [1-6]. The composite films were used either as such in electrochemical solid-state sensor applications [6] or as buried ion-to-electron transducer layers in polymeric solid-contact ion-selective electrodes (SC-ISEs) aimed for trace analysis and applications within health diagnostics [7, 8]. In both the two- and three-electrode cell [5, 9], the composite materials had very good potential cycling stability in aqueous electrolyte solutions for at least 10000 cycles with only minor degradation (6%), which is beneficial for obtaining high signal stability in electrochemical sensors.

It is shown that SC-ISE having the transducer made of a composite consisting of few-layer graphene and PANI had a detection limit of only 5x10(-9) M Ca(2+) (0.2 ppb; parts per billion) [7]. In addition to the hydrophobicity of graphene, the transducer makes use of the synergistic effect of PANI and graphene resulting in increased redox capacitance which is crucial for obtaining good long-term signal stability. Moreover, the presentation discusses shortly the relationship of the graphene barrier properties and the reproducibility of the standard potential of electrochemical sensors. This is one of the key issues in the fabrication of conditioning- and calibration-free devices.

References
[1] A. Österholm, T. Lindfors, J. Kauppila, P. Damlin, and C. Kvarnström, Electrochim. Acta, 83, 463-470, (2012)
[2] T. Lindfors, A. Österholm, J. Kauppila, and M. Pesonen, Electrochim. Acta, 110, 428-436, (2013)
[3] T. Lindfors, A. Österholm, J. Kauppila, and R.E. Gyurcsányi, Carbon, 63, 588-592, (2013)
[4] T. Lindfors and R.-M. Latonen, Carbon, 69, 122-131, (2014)
[5] T. Lindfors, Z. Boeva, and R.-M. Latonen, RSC Adv., 4, 25279-25286, (2014)
[6] Z.A. Boeva, K.A. Milakin, M. Pesonen, A.N. Ozerin, and V.G. Sergeyev, T. Lindfors, RSC Adv., 4, 46340-46350, (2014)
[7] Z.A. Boeva and T. Lindfors, manuscript in preparation
[8] T. Lindfors, L. Höfler, G. Jagerszki, and R.E. Gyurcsányi, Anal. Chem., 83, 4902-4908, (2011)
[9] T. Lindfors, Electroanalysis, in press, (2015)

Alkuperäiskieli	Englanti
Tila	Julkaistu - 2015
OKM-julkaisutyyppi	O2 Other
Tapahtuma	Graphene Week 2015 - University of Manchester, Manchester, United Kingdom Kesto: 22 kesäk. 2015 → 26 kesäk. 2015 https://graphene-flagship.eu/events/graphene-week-2015/

Konferenssi

Konferenssi	Graphene Week 2015
Maa/Alue	United Kingdom
Kaupunki	Manchester
Ajanjakso	22/06/15 → 26/06/15
www-osoite	https://graphene-flagship.eu/events/graphene-week-2015/

Viittausmuodot

@conference{6004459373ce4c5192bb963b767e1898,

title = "Application of composites of graphene derivatives and conducting polymers in solid-state electrochemical sensors",

abstract = "We report the incorporation of few-layer graphene (< 3 monolayers), graphene oxide (GO), reduced graphene oxide (RGO) or exfoliated graphite in electrically conducting polyaniline (PANI) and poly(3,4-ethylenedioxythiophene) matrices [1-6]. The composite films were used either as such in electrochemical solid-state sensor applications [6] or as buried ion-to-electron transducer layers in polymeric solid-contact ion-selective electrodes (SC-ISEs) aimed for trace analysis and applications within health diagnostics [7, 8]. In both the two- and three-electrode cell [5, 9], the composite materials had very good potential cycling stability in aqueous electrolyte solutions for at least 10000 cycles with only minor degradation (6%), which is beneficial for obtaining high signal stability in electrochemical sensors. It is shown that SC-ISE having the transducer made of a composite consisting of few-layer graphene and PANI had a detection limit of only 5x10(-9) M Ca(2+) (0.2 ppb; parts per billion) [7]. In addition to the hydrophobicity of graphene, the transducer makes use of the synergistic effect of PANI and graphene resulting in increased redox capacitance which is crucial for obtaining good long-term signal stability. Moreover, the presentation discusses shortly the relationship of the graphene barrier properties and the reproducibility of the standard potential of electrochemical sensors. This is one of the key issues in the fabrication of conditioning- and calibration-free devices. References[1] A. {\"O}sterholm, T. Lindfors, J. Kauppila, P. Damlin, and C. Kvarnstr{\"o}m, Electrochim. Acta, 83, 463-470, (2012)[2] T. Lindfors, A. {\"O}sterholm, J. Kauppila, and M. Pesonen, Electrochim. Acta, 110, 428-436, (2013)[3] T. Lindfors, A. {\"O}sterholm, J. Kauppila, and R.E. Gyurcs{\'a}nyi, Carbon, 63, 588-592, (2013)[4] T. Lindfors and R.-M. Latonen, Carbon, 69, 122-131, (2014)[5] T. Lindfors, Z. Boeva, and R.-M. Latonen, RSC Adv., 4, 25279-25286, (2014)[6] Z.A. Boeva, K.A. Milakin, M. Pesonen, A.N. Ozerin, and V.G. Sergeyev, T. Lindfors, RSC Adv., 4, 46340-46350, (2014)[7] Z.A. Boeva and T. Lindfors, manuscript in preparation[8] T. Lindfors, L. H{\"o}fler, G. Jagerszki, and R.E. Gyurcs{\'a}nyi, Anal. Chem., 83, 4902-4908, (2011)[9] T. Lindfors, Electroanalysis, in press, (2015)",

keywords = "Ion-selective electrode, Solid contact, Graphene",

author = "Tom Lindfors and Zhanna Boeva and Konstantin Milakin and Anna {\"O}sterholm",

year = "2015",

language = "English",

note = "Graphene Week 2015 ; Conference date: 22-06-2015 Through 26-06-2015",

url = "https://graphene-flagship.eu/events/graphene-week-2015/",

}

TY - CONF

T1 - Application of composites of graphene derivatives and conducting polymers in solid-state electrochemical sensors

AU - Lindfors, Tom

AU - Boeva, Zhanna

AU - Milakin, Konstantin

AU - Österholm, Anna

PY - 2015

Y1 - 2015

N2 - We report the incorporation of few-layer graphene (< 3 monolayers), graphene oxide (GO), reduced graphene oxide (RGO) or exfoliated graphite in electrically conducting polyaniline (PANI) and poly(3,4-ethylenedioxythiophene) matrices [1-6]. The composite films were used either as such in electrochemical solid-state sensor applications [6] or as buried ion-to-electron transducer layers in polymeric solid-contact ion-selective electrodes (SC-ISEs) aimed for trace analysis and applications within health diagnostics [7, 8]. In both the two- and three-electrode cell [5, 9], the composite materials had very good potential cycling stability in aqueous electrolyte solutions for at least 10000 cycles with only minor degradation (6%), which is beneficial for obtaining high signal stability in electrochemical sensors. It is shown that SC-ISE having the transducer made of a composite consisting of few-layer graphene and PANI had a detection limit of only 5x10(-9) M Ca(2+) (0.2 ppb; parts per billion) [7]. In addition to the hydrophobicity of graphene, the transducer makes use of the synergistic effect of PANI and graphene resulting in increased redox capacitance which is crucial for obtaining good long-term signal stability. Moreover, the presentation discusses shortly the relationship of the graphene barrier properties and the reproducibility of the standard potential of electrochemical sensors. This is one of the key issues in the fabrication of conditioning- and calibration-free devices. References[1] A. Österholm, T. Lindfors, J. Kauppila, P. Damlin, and C. Kvarnström, Electrochim. Acta, 83, 463-470, (2012)[2] T. Lindfors, A. Österholm, J. Kauppila, and M. Pesonen, Electrochim. Acta, 110, 428-436, (2013)[3] T. Lindfors, A. Österholm, J. Kauppila, and R.E. Gyurcsányi, Carbon, 63, 588-592, (2013)[4] T. Lindfors and R.-M. Latonen, Carbon, 69, 122-131, (2014)[5] T. Lindfors, Z. Boeva, and R.-M. Latonen, RSC Adv., 4, 25279-25286, (2014)[6] Z.A. Boeva, K.A. Milakin, M. Pesonen, A.N. Ozerin, and V.G. Sergeyev, T. Lindfors, RSC Adv., 4, 46340-46350, (2014)[7] Z.A. Boeva and T. Lindfors, manuscript in preparation[8] T. Lindfors, L. Höfler, G. Jagerszki, and R.E. Gyurcsányi, Anal. Chem., 83, 4902-4908, (2011)[9] T. Lindfors, Electroanalysis, in press, (2015)

AB - We report the incorporation of few-layer graphene (< 3 monolayers), graphene oxide (GO), reduced graphene oxide (RGO) or exfoliated graphite in electrically conducting polyaniline (PANI) and poly(3,4-ethylenedioxythiophene) matrices [1-6]. The composite films were used either as such in electrochemical solid-state sensor applications [6] or as buried ion-to-electron transducer layers in polymeric solid-contact ion-selective electrodes (SC-ISEs) aimed for trace analysis and applications within health diagnostics [7, 8]. In both the two- and three-electrode cell [5, 9], the composite materials had very good potential cycling stability in aqueous electrolyte solutions for at least 10000 cycles with only minor degradation (6%), which is beneficial for obtaining high signal stability in electrochemical sensors. It is shown that SC-ISE having the transducer made of a composite consisting of few-layer graphene and PANI had a detection limit of only 5x10(-9) M Ca(2+) (0.2 ppb; parts per billion) [7]. In addition to the hydrophobicity of graphene, the transducer makes use of the synergistic effect of PANI and graphene resulting in increased redox capacitance which is crucial for obtaining good long-term signal stability. Moreover, the presentation discusses shortly the relationship of the graphene barrier properties and the reproducibility of the standard potential of electrochemical sensors. This is one of the key issues in the fabrication of conditioning- and calibration-free devices. References[1] A. Österholm, T. Lindfors, J. Kauppila, P. Damlin, and C. Kvarnström, Electrochim. Acta, 83, 463-470, (2012)[2] T. Lindfors, A. Österholm, J. Kauppila, and M. Pesonen, Electrochim. Acta, 110, 428-436, (2013)[3] T. Lindfors, A. Österholm, J. Kauppila, and R.E. Gyurcsányi, Carbon, 63, 588-592, (2013)[4] T. Lindfors and R.-M. Latonen, Carbon, 69, 122-131, (2014)[5] T. Lindfors, Z. Boeva, and R.-M. Latonen, RSC Adv., 4, 25279-25286, (2014)[6] Z.A. Boeva, K.A. Milakin, M. Pesonen, A.N. Ozerin, and V.G. Sergeyev, T. Lindfors, RSC Adv., 4, 46340-46350, (2014)[7] Z.A. Boeva and T. Lindfors, manuscript in preparation[8] T. Lindfors, L. Höfler, G. Jagerszki, and R.E. Gyurcsányi, Anal. Chem., 83, 4902-4908, (2011)[9] T. Lindfors, Electroanalysis, in press, (2015)

KW - Ion-selective electrode

KW - Solid contact

KW - Graphene

M3 - Poster

T2 - Graphene Week 2015

Y2 - 22 June 2015 through 26 June 2015

ER -

Application of composites of graphene derivatives and conducting polymers in solid-state electrochemical sensors

Abstrakti

Konferenssi

Sormenjälki

Viittausmuodot