FusionWiki - User contributions [en]

LNF: Exploration of novel (anti) corrosion and permeation barriers (EXCORPION)

2024-09-11T06:46:03Z

Martamalo:

== LNF - Nationally funded project ==
'''Title''': Exploration of novel (anti) corrosion and permeation
barriers (EXCORPION)

'''Reference''': PID2022-141926OA-I00

'''Programme and date''': Proyectos de Generación de Conocimiento, convocatoria 2022

'''Programme type (Modalidad de proyecto)''': Tipo A

'''Area/subarea (Área temática / subárea)''': Energía y transporte/Energía

'''Principal Investigator(s)''': Elisabetta Carella [https://orcid.org/0000-0002-4802-2546] [https://wiki.fusion.ciemat.es/wiki/User:Elisabetta] and Marta Malo [https://orcid.org/0000-0002-0093-5004]

'''Project type''': Proyecto individual

'''Start-end dates''': 01/09/2023 - 01/09/2026

'''Financing granted (direct costs)''': 90000 €

[[File:Logo EXCORPIONv2-transformed.png|200px|thumb|left|Caption]File:File.png|200px|thumb|right|Caption]]

== Description of the project ==

United Nations (UN) has declared a State of Climate Emergency until carbon neutrality
has been reached worldwide. EU has assumed a leading position in decarbonization,
going for a climate-neutral Europe in 2050. Much of this energy is still produced from
burning fossil fuels on a massive scale.

The international effort on
the development of
alternative energy systems,
see the
CIEMAT
involved with different innovative projects.
The development of new materials is a key question in different areas.
An urgent need for
developing advanced multi-functional coatings that can provide
protection against corrosion, gas permeation and/or provide determined features to
structural and functional base materials has been identified for multiple technological
applications.
For example,
a suitable protective layer for
structural steels
to minimize
tritium permeation and corrosive effects of the
PbLi
is fundamental for the development
of
some
key fusion reactor components.
High reflectivity and electrical conductivity
coatings are required for the new generati
on of solar cells. Low permeability is expected
for the development of hydrogen storage methods. Corrosion protection against molten
salts is required for applications
under nuclear fission conditions
, but also a protection of
the structural material from hydrogen embrittlement due to permeation.

The global objective of the project is to
promote the development of coating
technologies
for applications in the Energy
sector.
Complex multifunctional coatings are key pieces for the consecution of sustainable and
safe new energy sources and must fulfil slightly different requirements depending on the
specific working area.
Due to the extreme expected operational
conditions, the most
restrictive demands are imposed for use in Fusion devices. In particular, suitable
chemical composition in order to reduce neutron activation and hence minimize
radioactive waste is critical for the design of future fusion plants. This
consideration will
serve as a starting point for the selection of the candidate compositions for the
design
and fabrication
stage, together with the current existing background.
Cascade
validation of the fabricated coatings
is proposed from a lesser to
a
greater level of
specificity. This way, even though not every single requirement is met for (all)
of
the
examined coatings, their potential use in different disciplines will be considered
depending on the satisfied properties.
EXCORPION will study the above new materials
solutions in terms of
# compatibility with different corrosive materials
# hydrogen isotopes permeation reduction
# radiation tolerance by dedicated gamma and ion irradiation experiments
# validation to a system level and scale-up to welding and newgeometries.

The
proposal
of
this
transversal
project
between
various
research
groups
highlights
the
need
for
synergies
to
obtain
new
materials
capable
of
meeting
all
the
extreme
conditions
to
which
they
are
subjected
and
improving
the
efficiency
of
these
alternative
sources
for
energy
production,
with
the
ultimate
goal
of
being
a
real
alternative
to
fossil
fuels.


== References ==
# M. Malo, A. Moroño and E. R. Hodgson, In situ luminescence qualifications of radiation damage in aluminas: F aggregation and Al colloids, Fusion Engineering and Design 89 (2014) 2179-2183.
# M. Malo, A. Moroño, and E.R. Hodgson, “Radioluminescence characterization of SiC and SiC/SiC”, Journal of Nuclear Materials 442 (2013) s404-s409.
# M. Carmona Gázquez, S. Bassini, T. Hernández and M. Utili “Al2O3 Coating as Barrier against corrosion in Pb-17Li” Fusion Engineering and Design Vol. 124, (2017) 837-840.
# P. Muñoz, et. al, “Radiation effects on deuterium permeation for PLD alumina coated Eurofer steel measured during 1.8 MeV electron irradiation” Journal of Nuclear Materials 512 (2018) 118 – 125
# T.Hernández, et al., “Corrosion protective action of different coatings for the helium cooled pebble breeder concept” Journal of Nuclear Materials 516 (2019) 160-168.
# T. Hernández, et al., “Corrosion behavior of diverse sputtered coatings for the helium cooled pebbles bed (HCPB) breeder concept” Nuclear Materials and Energy, 25 (2020) 100795.
# A. Moroño, E.R. Hodgson and M. Malo, “Radiation enhanced deuterium absorption for Al2O3 and macor ceramic”, Fusion Engineering and Design 88 (2013) 2488-2491.
# T. Hernández, et al., “Study of deuterium permeation, retention, and desorption in SiC coatings submitted to relevant conditions for breeder blanket applications: thermal cycling effect under electron irradiation and oxygen exposure” Journal of Nuclear Materials 557 (2021) 153219
# Gonzalez-Arrabal, R., Rivera, A., & Perlado, J. M. (2020). “Limitations for tungsten as plasma facing material in the diverse scenarios of the European inertial confinement fusion facility HiPER: Current status and new approaches” Matter and Radiation at Extremes, 5(5), 055201.
# Panizo-Laiz, et al., (2019). “Experimental and computational studies of the influence of grain boundaries and temperature on the radiation-induced damage and hydrogen behavior in tungsten” Nuclear Fusion, 59(8).
# C. Abed, et al., “Processing and Study of Optical and Electrical Properties of (Mg, Al) Co-Doped ZnO Thin Films Prepared by RF Magnetron Sputtering for Photovoltaic Application” Materials 13 (2020) 2146-2158.
# S. Fernández, et al.”Non-treated low temperature indium tin oxide fabricated in oxygen-free environment to low-cost silicon-based solar technology” Vacuum 184 (2021) 109783.
# S. Fernández, et al.,”Sputtered non-hydrogenated amorphous silicon as alternative absorber for silicon photovoltaic technology” Materials (2021), 14, 6550.
# S. Fernández, et al., “Roles of low temperature sputtered indium tin oxide for solar photovoltaic technology” Materials (2021), 14, Issue 24, 7758.
# S. Suárez, et al., Parameters to be considered for the development highly photoactive TiO2 layers on aluminium substrates by magnetron sputtering. Catalysis Today (In press).
# E. Carella, D. Rapisarda, S.Lenk. “Design of the CIEMAT Corrosion Loop for Liquid Metal Experiments” Applied Sciences, 12 (2022), 3104.
# E. Carella, C. Moreno, F. R. Urgorri, D. Rapisarda, A. Ibarra “Tritium modeling in HCPB breeder blanket at a system level” Fusion Engineering and Design, 124 (2017) 687-691.
# E. Carella, M. Gonzalez, R. Gonzalez-Arrabal “D-depth profiling in as-implanted and annealed Li-based Breeder Blanket ceramics” Journal of Nuclear Materials, Vol. 438, Issues 1–3 (2013) 193-198.

[[File:File.png]]


<hr>
[[LNF:Nationally Funded Projects|Back to list of nationally funded projects]]

[[Category:LNF Nationally Funded Projects]]

LNF: Exploration of novel (anti) corrosion and permeation barriers (EXCORPION)

2024-09-11T06:45:13Z

Martamalo:

== LNF - Nationally funded project ==
'''Title''': Exploration of novel (anti) corrosion and permeation
barriers (EXCORPION)

'''Reference''': PID2022-141926OA-I00

'''Programme and date''': Proyectos de Generación de Conocimiento, convocatoria 2022

'''Programme type (Modalidad de proyecto)''': Tipo A

'''Area/subarea (Área temática / subárea)''': Energía y transporte/Energía

'''Principal Investigator(s)''': Elisabetta Carella [https://orcid.org/0000-0002-4802-2546] [https://wiki.fusion.ciemat.es/wiki/User:Elisabetta] and Marta Malo [https://orcid.org/0000-0002-0093-5004]

'''Project type''': Proyecto individual

'''Start-end dates''': 01/09/2023 - 01/09/2026

'''Financing granted (direct costs)''': 90000 €

[[File:Logo EXCORPIONv2-transformed.png|200px|thumb|left|Caption]File:File.png|200px|thumb|right|Caption]]

== Description of the project ==

United Nations (UN) has declared a State of Climate Emergency until carbon neutrality
has been reached worldwide. EU has assumed a leading position in decarbonization,
going for a climate-neutral Europe in 2050. Much of this energy is still produced from
burning fossil fuels on a massive scale.

The international effort on
the development of
alternative energy systems,
see the
CIEMAT
involved with different innovative projects.
The development of new materials is a key question in different areas.
An urgent need for
developing advanced multi-functional coatings that can provide
protection against corrosion, gas permeation and/or provide determined features to
structural and functional base materials has been identified for multiple technological
applications.
For example,
a suitable protective layer for
structural steels
to minimize
tritium permeation and corrosive effects of the
PbLi
is fundamental for the development
of
some
key fusion reactor components.
High reflectivity and electrical conductivity
coatings are required for the new generati
on of solar cells. Low permeability is expected
for the development of hydrogen storage methods. Corrosion protection against molten
salts is required for applications
under nuclear fission conditions
, but also a protection of
the structural material from hydrogen embrittlement due to permeation.

The global objective of the project is to
promote the development of coating
technologies
for applications in the Energy
sector.
Complex multifunctional coatings are key pieces for the consecution of sustainable and
safe new energy sources and must fulfil slightly different requirements depending on the
specific working area.
Due to the extreme expected operational
conditions, the most
restrictive demands are imposed for use in Fusion devices. In particular, suitable
chemical composition in order to reduce neutron activation and hence minimize
radioactive waste is critical for the design of future fusion plants. This
consideration will
serve as a starting point for the selection of the candidate compositions for the
design
and fabrication
stage, together with the current existing background.
Cascade
validation of the fabricated coatings
is proposed from a lesser to
a
greater level of
specificity. This way, even though not every single requirement is met for (all)
of
the
examined coatings, their potential use in different disciplines will be considered
depending on the satisfied properties.
EXCORPION will study the above new materials
solutions in terms of
# compatibility with different corrosive materials
# hydrogen isotopes permeation reduction
# radiation tolerance by dedicated gamma and ion irradiation experiments
# validation to a system level and scale-up to welding and newgeometries.

The
proposal
of
this
transversal
project
between
various
research
groups
highlights
the
need
for
synergies
to
obtain
new
materials
capable
of
meeting
all
the
extreme
conditions
to
which
they
are
subjected
and
improving
the
efficiency
of
these
alternative
sources
for
energy
production,
with
the
ultimate
goal
of
being
a
real
alternative
to
fossil
fuels.


== References ==
# M. Malo, A. Moroño and E. R. Hodgson, In situ luminescence qualifications of radiation damage in aluminas: F aggregation and Al colloids, Fusion Engineering and Design 89 (2014) 2179-2183.
# M. Malo, A. Moroño, and E.R. Hodgson, “Radioluminescence characterization of SiC and SiC/SiC”, Journal of Nuclear Materials 442 (2013) s404-s409.
# M. Carmona Gázquez, S. Bassini, T. Hernández and M. Utili “Al2O3 Coating as Barrier against corrosion in Pb-17Li” Fusion Engineering and Design Vol. 124, (2017) 837-840.
# P. Muñoz, et. al, “Radiation effects on deuterium permeation for PLD alumina coated Eurofer steel measured during 1.8 MeV electron irradiation” Journal of Nuclear Materials 512 (2018) 118 – 125
# T.Hernández, et al., “Corrosion protective action of different coatings for the helium cooled pebble breeder concept” Journal of Nuclear Materials 516 (2019) 160-168.
# T. Hernández, et al., “Corrosion behavior of diverse sputtered coatings for the helium cooled pebbles bed (HCPB) breeder concept” Nuclear Materials and Energy, 25 (2020) 100795.
# A. Moroño, E.R. Hodgson and M. Malo, “Radiation enhanced deuterium absorption for Al2O3 and macor ceramic”, Fusion Engineering and Design 88 (2013) 2488-2491.
# T. Hernández, et al., “Study of deuterium permeation, retention, and desorption in SiC coatings submitted to relevant conditions for breeder blanket applications: thermal cycling effect under electron irradiation and oxygen exposure” Journal of Nuclear Materials 557 (2021) 153219
# Gonzalez-Arrabal, R., Rivera, A., & Perlado, J. M. (2020). “Limitations for tungsten as plasma facing material in the diverse scenarios of the European inertial confinement fusion facility HiPER: Current status and new approaches” Matter and Radiation at Extremes, 5(5), 055201.
# Panizo-Laiz, et al., (2019). “Experimental and computational studies of the influence of grain boundaries and temperature on the radiation-induced damage and hydrogen behavior in tungsten” Nuclear Fusion, 59(8).
# C. Abed, et al., “Processing and Study of Optical and Electrical Properties of (Mg, Al) Co-Doped ZnO Thin Films Prepared by RF Magnetron Sputtering for Photovoltaic Application” Materials 13 (2020) 2146-2158.
# S. Fernández, et al.”Non-treated low temperature indium tin oxide fabricated in oxygen-free environment to low-cost silicon-based solar technology” Vacuum 184 (2021) 109783.
# S. Fernández, et al.,”Sputtered non-hydrogenated amorphous silicon as alternative absorber for silicon photovoltaic technology” Materials (2021), 14, 6550.
# S. Fernández, et al., “Roles of low temperature sputtered indium tin oxide for solar photovoltaic technology” Materials (2021), 14, Issue 24, 7758.
# S. Suárez, et al., Parameters to be considered for the development highly photoactive TiO2 layers on aluminium substrates by magnetron sputtering. Catalysis Today (In press).
# E. Carella, D. Rapisarda, S.Lenk. “Design of the CIEMAT Corrosion Loop for Liquid Metal Experiments” Applied Sciences, 12 (2022), 3104.
# E. Carella, C. Moreno, F. R. Urgorri, D. Rapisarda, A. Ibarra “Tritium modeling in HCPB breeder blanket at a system level” Fusion Engineering and Design, 124 (2017) 687-691.
# E. Carella, M. Gonzalez, R. Gonzalez-Arrabal “D-depth profiling in as-implanted and annealed Li-based Breeder Blanket ceramics” Journal of Nuclear Materials, Vol. 438, Issues 1–3 (2013) 193-198.

[[File:File.jpg]]


<hr>
[[LNF:Nationally Funded Projects|Back to list of nationally funded projects]]

[[Category:LNF Nationally Funded Projects]]

File:File.png

2024-09-11T06:44:10Z

Martamalo:

LNF: Exploration of novel (anti) corrosion and permeation barriers (EXCORPION)

2024-09-11T06:43:50Z

Martamalo:

== LNF - Nationally funded project ==
'''Title''': Exploration of novel (anti) corrosion and permeation
barriers (EXCORPION)

'''Reference''': PID2022-141926OA-I00

'''Programme and date''': Proyectos de Generación de Conocimiento, convocatoria 2022

'''Programme type (Modalidad de proyecto)''': Tipo A

'''Area/subarea (Área temática / subárea)''': Energía y transporte/Energía

'''Principal Investigator(s)''': Elisabetta Carella [https://orcid.org/0000-0002-4802-2546] [https://wiki.fusion.ciemat.es/wiki/User:Elisabetta] and Marta Malo [https://orcid.org/0000-0002-0093-5004]

'''Project type''': Proyecto individual

'''Start-end dates''': 01/09/2023 - 01/09/2026

'''Financing granted (direct costs)''': 90000 €

[[File:Logo EXCORPIONv2-transformed.png|200px|thumb|left|Caption]File:File.png|200px|thumb|right|Caption]]

== Description of the project ==

United Nations (UN) has declared a State of Climate Emergency until carbon neutrality
has been reached worldwide. EU has assumed a leading position in decarbonization,
going for a climate-neutral Europe in 2050. Much of this energy is still produced from
burning fossil fuels on a massive scale.

The international effort on
the development of
alternative energy systems,
see the
CIEMAT
involved with different innovative projects.
The development of new materials is a key question in different areas.
An urgent need for
developing advanced multi-functional coatings that can provide
protection against corrosion, gas permeation and/or provide determined features to
structural and functional base materials has been identified for multiple technological
applications.
For example,
a suitable protective layer for
structural steels
to minimize
tritium permeation and corrosive effects of the
PbLi
is fundamental for the development
of
some
key fusion reactor components.
High reflectivity and electrical conductivity
coatings are required for the new generati
on of solar cells. Low permeability is expected
for the development of hydrogen storage methods. Corrosion protection against molten
salts is required for applications
under nuclear fission conditions
, but also a protection of
the structural material from hydrogen embrittlement due to permeation.

The global objective of the project is to
promote the development of coating
technologies
for applications in the Energy
sector.
Complex multifunctional coatings are key pieces for the consecution of sustainable and
safe new energy sources and must fulfil slightly different requirements depending on the
specific working area.
Due to the extreme expected operational
conditions, the most
restrictive demands are imposed for use in Fusion devices. In particular, suitable
chemical composition in order to reduce neutron activation and hence minimize
radioactive waste is critical for the design of future fusion plants. This
consideration will
serve as a starting point for the selection of the candidate compositions for the
design
and fabrication
stage, together with the current existing background.
Cascade
validation of the fabricated coatings
is proposed from a lesser to
a
greater level of
specificity. This way, even though not every single requirement is met for (all)
of
the
examined coatings, their potential use in different disciplines will be considered
depending on the satisfied properties.
EXCORPION will study the above new materials
solutions in terms of
# compatibility with different corrosive materials
# hydrogen isotopes permeation reduction
# radiation tolerance by dedicated gamma and ion irradiation experiments
# validation to a system level and scale-up to welding and newgeometries.

The
proposal
of
this
transversal
project
between
various
research
groups
highlights
the
need
for
synergies
to
obtain
new
materials
capable
of
meeting
all
the
extreme
conditions
to
which
they
are
subjected
and
improving
the
efficiency
of
these
alternative
sources
for
energy
production,
with
the
ultimate
goal
of
being
a
real
alternative
to
fossil
fuels.


== References ==
# M. Malo, A. Moroño and E. R. Hodgson, In situ luminescence qualifications of radiation damage in aluminas: F aggregation and Al colloids, Fusion Engineering and Design 89 (2014) 2179-2183.
# M. Malo, A. Moroño, and E.R. Hodgson, “Radioluminescence characterization of SiC and SiC/SiC”, Journal of Nuclear Materials 442 (2013) s404-s409.
# M. Carmona Gázquez, S. Bassini, T. Hernández and M. Utili “Al2O3 Coating as Barrier against corrosion in Pb-17Li” Fusion Engineering and Design Vol. 124, (2017) 837-840.
# P. Muñoz, et. al, “Radiation effects on deuterium permeation for PLD alumina coated Eurofer steel measured during 1.8 MeV electron irradiation” Journal of Nuclear Materials 512 (2018) 118 – 125
# T.Hernández, et al., “Corrosion protective action of different coatings for the helium cooled pebble breeder concept” Journal of Nuclear Materials 516 (2019) 160-168.
# T. Hernández, et al., “Corrosion behavior of diverse sputtered coatings for the helium cooled pebbles bed (HCPB) breeder concept” Nuclear Materials and Energy, 25 (2020) 100795.
# A. Moroño, E.R. Hodgson and M. Malo, “Radiation enhanced deuterium absorption for Al2O3 and macor ceramic”, Fusion Engineering and Design 88 (2013) 2488-2491.
# T. Hernández, et al., “Study of deuterium permeation, retention, and desorption in SiC coatings submitted to relevant conditions for breeder blanket applications: thermal cycling effect under electron irradiation and oxygen exposure” Journal of Nuclear Materials 557 (2021) 153219
# Gonzalez-Arrabal, R., Rivera, A., & Perlado, J. M. (2020). “Limitations for tungsten as plasma facing material in the diverse scenarios of the European inertial confinement fusion facility HiPER: Current status and new approaches” Matter and Radiation at Extremes, 5(5), 055201.
# Panizo-Laiz, et al., (2019). “Experimental and computational studies of the influence of grain boundaries and temperature on the radiation-induced damage and hydrogen behavior in tungsten” Nuclear Fusion, 59(8).
# C. Abed, et al., “Processing and Study of Optical and Electrical Properties of (Mg, Al) Co-Doped ZnO Thin Films Prepared by RF Magnetron Sputtering for Photovoltaic Application” Materials 13 (2020) 2146-2158.
# S. Fernández, et al.”Non-treated low temperature indium tin oxide fabricated in oxygen-free environment to low-cost silicon-based solar technology” Vacuum 184 (2021) 109783.
# S. Fernández, et al.,”Sputtered non-hydrogenated amorphous silicon as alternative absorber for silicon photovoltaic technology” Materials (2021), 14, 6550.
# S. Fernández, et al., “Roles of low temperature sputtered indium tin oxide for solar photovoltaic technology” Materials (2021), 14, Issue 24, 7758.
# S. Suárez, et al., Parameters to be considered for the development highly photoactive TiO2 layers on aluminium substrates by magnetron sputtering. Catalysis Today (In press).
# E. Carella, D. Rapisarda, S.Lenk. “Design of the CIEMAT Corrosion Loop for Liquid Metal Experiments” Applied Sciences, 12 (2022), 3104.
# E. Carella, C. Moreno, F. R. Urgorri, D. Rapisarda, A. Ibarra “Tritium modeling in HCPB breeder blanket at a system level” Fusion Engineering and Design, 124 (2017) 687-691.
# E. Carella, M. Gonzalez, R. Gonzalez-Arrabal “D-depth profiling in as-implanted and annealed Li-based Breeder Blanket ceramics” Journal of Nuclear Materials, Vol. 438, Issues 1–3 (2013) 193-198.

[[File:File.png|200px|thumb|left|Caption]]


<hr>
[[LNF:Nationally Funded Projects|Back to list of nationally funded projects]]

[[Category:LNF Nationally Funded Projects]]

File:500px-LogoOficial PlanNacional 2021.png

2024-09-11T06:38:39Z

Martamalo:

LNF: Exploration of novel (anti) corrosion and permeation barriers (EXCORPION)

2024-04-11T12:59:35Z

Martamalo: /* LNF - Nationally funded project */

== LNF - Nationally funded project ==
'''Title''': Exploration of novel (anti) corrosion and permeation
barriers (EXCORPION)

'''Reference''': PID2022-141926OA-I00

'''Programme and date''': Proyectos de Generación de Conocimiento, convocatoria 2022

'''Programme type (Modalidad de proyecto)''': Tipo A

'''Area/subarea (Área temática / subárea)''': Energía y transporte/Energía

'''Principal Investigator(s)''': Elisabetta Carella [https://orcid.org/0000-0002-4802-2546] [https://wiki.fusion.ciemat.es/wiki/User:Elisabetta] and Marta Malo [https://orcid.org/0000-0002-0093-5004]

'''Project type''': Proyecto individual

'''Start-end dates''': 01/09/2023 - 01/09/2026

'''Financing granted (direct costs)''': 90000 €

[[File:Logo EXCORPIONv2-transformed.png|200px|thumb|left|Caption]File:File.png|200px|thumb|right|Caption]]

== Description of the project ==

United Nations (UN) has declared a State of Climate Emergency until carbon neutrality
has been reached worldwide. EU has assumed a leading position in decarbonization,
going for a climate-neutral Europe in 2050. Much of this energy is still produced from
burning fossil fuels on a massive scale.

The international effort on
the development of
alternative energy systems,
see the
CIEMAT
involved with different innovative projects.
The development of new materials is a key question in different areas.
An urgent need for
developing advanced multi-functional coatings that can provide
protection against corrosion, gas permeation and/or provide determined features to
structural and functional base materials has been identified for multiple technological
applications.
For example,
a suitable protective layer for
structural steels
to minimize
tritium permeation and corrosive effects of the
PbLi
is fundamental for the development
of
some
key fusion reactor components.
High reflectivity and electrical conductivity
coatings are required for the new generati
on of solar cells. Low permeability is expected
for the development of hydrogen storage methods. Corrosion protection against molten
salts is required for applications
under nuclear fission conditions
, but also a protection of
the structural material from hydrogen embrittlement due to permeation.

The global objective of the project is to
promote the development of coating
technologies
for applications in the Energy
sector.
Complex multifunctional coatings are key pieces for the consecution of sustainable and
safe new energy sources and must fulfil slightly different requirements depending on the
specific working area.
Due to the extreme expected operational
conditions, the most
restrictive demands are imposed for use in Fusion devices. In particular, suitable
chemical composition in order to reduce neutron activation and hence minimize
radioactive waste is critical for the design of future fusion plants. This
consideration will
serve as a starting point for the selection of the candidate compositions for the
design
and fabrication
stage, together with the current existing background.
Cascade
validation of the fabricated coatings
is proposed from a lesser to
a
greater level of
specificity. This way, even though not every single requirement is met for (all)
of
the
examined coatings, their potential use in different disciplines will be considered
depending on the satisfied properties.
EXCORPION will study the above new materials
solutions in terms of
# compatibility with different corrosive materials
# hydrogen isotopes permeation reduction
# radiation tolerance by dedicated gamma and ion irradiation experiments
# validation to a system level and scale-up to welding and newgeometries.

The
proposal
of
this
transversal
project
between
various
research
groups
highlights
the
need
for
synergies
to
obtain
new
materials
capable
of
meeting
all
the
extreme
conditions
to
which
they
are
subjected
and
improving
the
efficiency
of
these
alternative
sources
for
energy
production,
with
the
ultimate
goal
of
being
a
real
alternative
to
fossil
fuels.


== References ==
# M. Malo, A. Moroño and E. R. Hodgson, In situ luminescence qualifications of radiation damage in aluminas: F aggregation and Al colloids, Fusion Engineering and Design 89 (2014) 2179-2183.
# M. Malo, A. Moroño, and E.R. Hodgson, “Radioluminescence characterization of SiC and SiC/SiC”, Journal of Nuclear Materials 442 (2013) s404-s409.
# M. Carmona Gázquez, S. Bassini, T. Hernández and M. Utili “Al2O3 Coating as Barrier against corrosion in Pb-17Li” Fusion Engineering and Design Vol. 124, (2017) 837-840.
# P. Muñoz, et. al, “Radiation effects on deuterium permeation for PLD alumina coated Eurofer steel measured during 1.8 MeV electron irradiation” Journal of Nuclear Materials 512 (2018) 118 – 125
# T.Hernández, et al., “Corrosion protective action of different coatings for the helium cooled pebble breeder concept” Journal of Nuclear Materials 516 (2019) 160-168.
# T. Hernández, et al., “Corrosion behavior of diverse sputtered coatings for the helium cooled pebbles bed (HCPB) breeder concept” Nuclear Materials and Energy, 25 (2020) 100795.
# A. Moroño, E.R. Hodgson and M. Malo, “Radiation enhanced deuterium absorption for Al2O3 and macor ceramic”, Fusion Engineering and Design 88 (2013) 2488-2491.
# T. Hernández, et al., “Study of deuterium permeation, retention, and desorption in SiC coatings submitted to relevant conditions for breeder blanket applications: thermal cycling effect under electron irradiation and oxygen exposure” Journal of Nuclear Materials 557 (2021) 153219
# Gonzalez-Arrabal, R., Rivera, A., & Perlado, J. M. (2020). “Limitations for tungsten as plasma facing material in the diverse scenarios of the European inertial confinement fusion facility HiPER: Current status and new approaches” Matter and Radiation at Extremes, 5(5), 055201.
# Panizo-Laiz, et al., (2019). “Experimental and computational studies of the influence of grain boundaries and temperature on the radiation-induced damage and hydrogen behavior in tungsten” Nuclear Fusion, 59(8).
# C. Abed, et al., “Processing and Study of Optical and Electrical Properties of (Mg, Al) Co-Doped ZnO Thin Films Prepared by RF Magnetron Sputtering for Photovoltaic Application” Materials 13 (2020) 2146-2158.
# S. Fernández, et al.”Non-treated low temperature indium tin oxide fabricated in oxygen-free environment to low-cost silicon-based solar technology” Vacuum 184 (2021) 109783.
# S. Fernández, et al.,”Sputtered non-hydrogenated amorphous silicon as alternative absorber for silicon photovoltaic technology” Materials (2021), 14, 6550.
# S. Fernández, et al., “Roles of low temperature sputtered indium tin oxide for solar photovoltaic technology” Materials (2021), 14, Issue 24, 7758.
# S. Suárez, et al., Parameters to be considered for the development highly photoactive TiO2 layers on aluminium substrates by magnetron sputtering. Catalysis Today (In press).
# E. Carella, D. Rapisarda, S.Lenk. “Design of the CIEMAT Corrosion Loop for Liquid Metal Experiments” Applied Sciences, 12 (2022), 3104.
# E. Carella, C. Moreno, F. R. Urgorri, D. Rapisarda, A. Ibarra “Tritium modeling in HCPB breeder blanket at a system level” Fusion Engineering and Design, 124 (2017) 687-691.
# E. Carella, M. Gonzalez, R. Gonzalez-Arrabal “D-depth profiling in as-implanted and annealed Li-based Breeder Blanket ceramics” Journal of Nuclear Materials, Vol. 438, Issues 1–3 (2013) 193-198.


<hr>
[[LNF:Nationally Funded Projects|Back to list of nationally funded projects]]

[[Category:LNF Nationally Funded Projects]]

LNF: Exploration of novel (anti) corrosion and permeation barriers (EXCORPION)

2024-04-11T12:57:48Z

Martamalo: /* LNF - Nationally funded project */

== LNF - Nationally funded project ==
'''Title''': Exploration of novel (anti) corrosion and permeation
barriers (EXCORPION)

'''Reference''': PID2022-141926OA-I00

'''Programme and date''': Proyectos de Generación de Conocimiento, convocatoria 2022

'''Programme type (Modalidad de proyecto)''': Tipo A

'''Area/subarea (Área temática / subárea)''': Energía y transporte/Energía

'''Principal Investigator(s)''': Elisabetta Carella [https://orcid.org/0000-0002-4802-2546] [https://wiki.fusion.ciemat.es/wiki/User:Elisabetta] and Marta Malo [https://orcid.org/0000-0002-0093-5004]

'''Project type''': Proyecto individual

'''Start-end dates''': 01/09/2023 - 01/09/2026

'''Financing granted (direct costs)''': 90000 €

[[File:Logo EXCORPIONv2-transformed.png|200px|thumb|left|Caption]File:File.png|200px|thumb|left|Caption]]

== Description of the project ==

United Nations (UN) has declared a State of Climate Emergency until carbon neutrality
has been reached worldwide. EU has assumed a leading position in decarbonization,
going for a climate-neutral Europe in 2050. Much of this energy is still produced from
burning fossil fuels on a massive scale.

The international effort on
the development of
alternative energy systems,
see the
CIEMAT
involved with different innovative projects.
The development of new materials is a key question in different areas.
An urgent need for
developing advanced multi-functional coatings that can provide
protection against corrosion, gas permeation and/or provide determined features to
structural and functional base materials has been identified for multiple technological
applications.
For example,
a suitable protective layer for
structural steels
to minimize
tritium permeation and corrosive effects of the
PbLi
is fundamental for the development
of
some
key fusion reactor components.
High reflectivity and electrical conductivity
coatings are required for the new generati
on of solar cells. Low permeability is expected
for the development of hydrogen storage methods. Corrosion protection against molten
salts is required for applications
under nuclear fission conditions
, but also a protection of
the structural material from hydrogen embrittlement due to permeation.

The global objective of the project is to
promote the development of coating
technologies
for applications in the Energy
sector.
Complex multifunctional coatings are key pieces for the consecution of sustainable and
safe new energy sources and must fulfil slightly different requirements depending on the
specific working area.
Due to the extreme expected operational
conditions, the most
restrictive demands are imposed for use in Fusion devices. In particular, suitable
chemical composition in order to reduce neutron activation and hence minimize
radioactive waste is critical for the design of future fusion plants. This
consideration will
serve as a starting point for the selection of the candidate compositions for the
design
and fabrication
stage, together with the current existing background.
Cascade
validation of the fabricated coatings
is proposed from a lesser to
a
greater level of
specificity. This way, even though not every single requirement is met for (all)
of
the
examined coatings, their potential use in different disciplines will be considered
depending on the satisfied properties.
EXCORPION will study the above new materials
solutions in terms of
# compatibility with different corrosive materials
# hydrogen isotopes permeation reduction
# radiation tolerance by dedicated gamma and ion irradiation experiments
# validation to a system level and scale-up to welding and newgeometries.

The
proposal
of
this
transversal
project
between
various
research
groups
highlights
the
need
for
synergies
to
obtain
new
materials
capable
of
meeting
all
the
extreme
conditions
to
which
they
are
subjected
and
improving
the
efficiency
of
these
alternative
sources
for
energy
production,
with
the
ultimate
goal
of
being
a
real
alternative
to
fossil
fuels.


== References ==
# M. Malo, A. Moroño and E. R. Hodgson, In situ luminescence qualifications of radiation damage in aluminas: F aggregation and Al colloids, Fusion Engineering and Design 89 (2014) 2179-2183.
# M. Malo, A. Moroño, and E.R. Hodgson, “Radioluminescence characterization of SiC and SiC/SiC”, Journal of Nuclear Materials 442 (2013) s404-s409.
# M. Carmona Gázquez, S. Bassini, T. Hernández and M. Utili “Al2O3 Coating as Barrier against corrosion in Pb-17Li” Fusion Engineering and Design Vol. 124, (2017) 837-840.
# P. Muñoz, et. al, “Radiation effects on deuterium permeation for PLD alumina coated Eurofer steel measured during 1.8 MeV electron irradiation” Journal of Nuclear Materials 512 (2018) 118 – 125
# T.Hernández, et al., “Corrosion protective action of different coatings for the helium cooled pebble breeder concept” Journal of Nuclear Materials 516 (2019) 160-168.
# T. Hernández, et al., “Corrosion behavior of diverse sputtered coatings for the helium cooled pebbles bed (HCPB) breeder concept” Nuclear Materials and Energy, 25 (2020) 100795.
# A. Moroño, E.R. Hodgson and M. Malo, “Radiation enhanced deuterium absorption for Al2O3 and macor ceramic”, Fusion Engineering and Design 88 (2013) 2488-2491.
# T. Hernández, et al., “Study of deuterium permeation, retention, and desorption in SiC coatings submitted to relevant conditions for breeder blanket applications: thermal cycling effect under electron irradiation and oxygen exposure” Journal of Nuclear Materials 557 (2021) 153219
# Gonzalez-Arrabal, R., Rivera, A., & Perlado, J. M. (2020). “Limitations for tungsten as plasma facing material in the diverse scenarios of the European inertial confinement fusion facility HiPER: Current status and new approaches” Matter and Radiation at Extremes, 5(5), 055201.
# Panizo-Laiz, et al., (2019). “Experimental and computational studies of the influence of grain boundaries and temperature on the radiation-induced damage and hydrogen behavior in tungsten” Nuclear Fusion, 59(8).
# C. Abed, et al., “Processing and Study of Optical and Electrical Properties of (Mg, Al) Co-Doped ZnO Thin Films Prepared by RF Magnetron Sputtering for Photovoltaic Application” Materials 13 (2020) 2146-2158.
# S. Fernández, et al.”Non-treated low temperature indium tin oxide fabricated in oxygen-free environment to low-cost silicon-based solar technology” Vacuum 184 (2021) 109783.
# S. Fernández, et al.,”Sputtered non-hydrogenated amorphous silicon as alternative absorber for silicon photovoltaic technology” Materials (2021), 14, 6550.
# S. Fernández, et al., “Roles of low temperature sputtered indium tin oxide for solar photovoltaic technology” Materials (2021), 14, Issue 24, 7758.
# S. Suárez, et al., Parameters to be considered for the development highly photoactive TiO2 layers on aluminium substrates by magnetron sputtering. Catalysis Today (In press).
# E. Carella, D. Rapisarda, S.Lenk. “Design of the CIEMAT Corrosion Loop for Liquid Metal Experiments” Applied Sciences, 12 (2022), 3104.
# E. Carella, C. Moreno, F. R. Urgorri, D. Rapisarda, A. Ibarra “Tritium modeling in HCPB breeder blanket at a system level” Fusion Engineering and Design, 124 (2017) 687-691.
# E. Carella, M. Gonzalez, R. Gonzalez-Arrabal “D-depth profiling in as-implanted and annealed Li-based Breeder Blanket ceramics” Journal of Nuclear Materials, Vol. 438, Issues 1–3 (2013) 193-198.


<hr>
[[LNF:Nationally Funded Projects|Back to list of nationally funded projects]]

[[Category:LNF Nationally Funded Projects]]

File:Logo EXCORPIONv2-transformed.png

2024-04-11T12:49:29Z

Martamalo: /* Summary */

== Summary ==

File:Logo EXCORPIONv2-transformed.png

2024-04-11T12:48:55Z

Martamalo: Logo

== Summary ==
Logo

LNF: Exploration of novel (anti) corrosion and permeation barriers (EXCORPION)

2024-04-11T08:37:42Z

Martamalo: /* LNF - Nationally funded project */

== LNF - Nationally funded project ==
'''Title''': Exploration of novel (anti) corrosion and permeation
barriers (EXCORPION)

'''Reference''': PID2022-141926OA-I00

'''Programme and date''': Proyectos de Generación de Conocimiento, convocatoria 2022

'''Programme type (Modalidad de proyecto)''': Tipo A

'''Area/subarea (Área temática / subárea)''': Energía y transporte/Energía

'''Principal Investigator(s)''': Elisabetta Carella [https://orcid.org/0000-0002-4802-2546] and Marta Malo [https://orcid.org/0000-0002-0093-5004]

'''Project type''': Proyecto individual

'''Start-end dates''': 01/09/2023 - 01/09/2026

'''Financing granted (direct costs)''': 90000 €

== Description of the project ==

United Nations (UN) has declared a State of Climate Emergency until carbon neutrality
has been reached worldwide. EU has assumed a leading position in decarbonization,
going for a climate
-
neutral Europe in 2050. Much of this energy is still produced from
burning fossil fuels on a massive scale
.
The international effort on
the development of
alternative energy systems,
see the
CIEMAT
involved with different innovative projects
.
The development of new materials is a key question in different areas.
An urgent need for
developing advanced multi
-
functional coatings that can provide
protection against corrosion, gas permeation and/or provide determined features to
structural and functional base materials has been identified for multiple technological
applications.
For example,
a suitable protective layer for
structural steels
to minimize
tritium permeation and corrosive effects of the
PbLi
is fundamental for the development
of
some
key fusion reactor components.
High reflectivity and electrical conductivity
coatings are required for the new generati
on of solar cells. Low permeability is expected
for the development of hydrogen storage methods. Corrosion protection against molten
salts is required for applications
under nuclear fission conditions
, but also a protection of
the structural material from hydrogen embrittlement due to permeation
.
The global objective of the project is to
promote the development of coating
technologies
for applications in the Energy
sector.
Complex multifunctional coatings are key pieces for the consecution of sustainable and
safe new energy sources and must fulfil slightly different requirements depending on the
specific working area.
Due to the extreme expected operational
conditions, the most
restrictive demands are imposed for use in Fusion devices
. In particular, suitable
chemical composition in order to reduce neutron activation and hence minimize
radioactive waste is critical for the design of future fusion plants. This
consideration will
serve as a starting point for the selection of the candidate compositions for the
design
and fabrication
stage, together with the current existing background.
Cascade
validation of the fabricated coatings
is proposed from a lesser t
o
a
greater level of
specificity. This way, even though not every single requirement is met for (all)
of
the
examined coatings, their potential use in different disciplines will be considered
depending on the satisfied properties.
EXCORPION will study the abo
ve new materials
solutions in terms of
1) compatibility with different corrosive materials 2) hydrogen
isotopes permeation reduction 3) radiation tolerance by dedicated gamma and ion
irradiation experiments
4) validation to a system level and scale
-
up to w
elding and new
geometries
.
The
proposal
of
this
transversal
project
between
various
research
groups
highlights
the
need
for
synergies
to
obtain
new
materials
capable
of
meeting
all
the
extreme
conditions
to
which
they
are
subjected
and
improving
the
effic
iency
of
these
alternative
sources
for
energy
production
,
with
the
ultimate
goal
of
being
a
real
alternative
to
fossil
fuels


== References ==
1. M. Malo, A. Moroño and E. R. Hodgson, In situ luminescence qualifications of radiation damage in aluminas: F aggregation and Al colloids, Fusion Engineering and Design 89 (2014) 2179-2183.
2. M. Malo, A. Moroño, and E.R. Hodgson, “Radioluminescence characterization of SiC and SiC/SiC”, Journal of Nuclear Materials 442 (2013) s404-s409.
3. M. Carmona Gázquez, S. Bassini, T. Hernández and M. Utili “Al2O3 Coating as Barrier against corrosion in Pb-17Li” Fusion Engineering and Design Vol. 124, (2017) 837-840.
4. P. Muñoz, et. al, “Radiation effects on deuterium permeation for PLD alumina coated Eurofer steel measured during 1.8 MeV electron irradiation” Journal of Nuclear Materials 512 (2018) 118 – 125
5. T.Hernández, et al., “Corrosion protective action of different coatings for the helium cooled pebble breeder concept” Journal of Nuclear Materials 516 (2019) 160-168.
6. T. Hernández, et al., “Corrosion behavior of diverse sputtered coatings for the helium cooled pebbles bed (HCPB) breeder concept” Nuclear Materials and Energy, 25 (2020) 100795.
7. A. Moroño, E.R. Hodgson and M. Malo, “Radiation enhanced deuterium absorption for Al2O3 and macor ceramic”, Fusion Engineering and Design 88 (2013) 2488-2491.
8. T. Hernández, et al., “Study of deuterium permeation, retention, and desorption in SiC coatings submitted to relevant conditions for breeder blanket applications: thermal cycling effect under electron irradiation and oxygen exposure” Journal of Nuclear Materials 557 (2021) 153219
9. Gonzalez-Arrabal, R., Rivera, A., & Perlado, J. M. (2020). “Limitations for tungsten as plasma facing material in the diverse scenarios of the European inertial confinement fusion facility HiPER: Current status and new approaches” Matter and Radiation at Extremes, 5(5), 055201.
10. Panizo-Laiz, et al., (2019). “Experimental and computational studies of the influence of grain boundaries and temperature on the radiation-induced damage and hydrogen behavior in tungsten” Nuclear Fusion, 59(8).
11. C. Abed, et al., “Processing and Study of Optical and Electrical Properties of (Mg, Al) Co-Doped ZnO Thin Films Prepared by RF Magnetron Sputtering for Photovoltaic Application” Materials 13 (2020) 2146-2158.
12. S. Fernández, et al.”Non-treated low temperature indium tin oxide fabricated in oxygen-free environment to low-cost silicon-based solar technology” Vacuum 184 (2021) 109783.
13. S. Fernández, et al.,”Sputtered non-hydrogenated amorphous silicon as alternative absorber for silicon photovoltaic technology” Materials (2021), 14, 6550.
14. S. Fernández, et al., “Roles of low temperature sputtered indium tin oxide for solar photovoltaic technology” Materials (2021), 14, Issue 24, 7758.
15. S. Suárez, et al., Parameters to be considered for the development highly photoactive TiO2 layers on aluminium substrates by magnetron sputtering. Catalysis Today (In press).
16. E. Carella, D. Rapisarda, S.Lenk. “Design of the CIEMAT Corrosion Loop for Liquid Metal Experiments” Applied Sciences, 12 (2022), 3104.
17. E. Carella, C. Moreno, F. R. Urgorri, D. Rapisarda, A. Ibarra “Tritium modeling in HCPB breeder blanket at a system level” Fusion Engineering and Design, 124 (2017) 687-691.
18. E. Carella, M. Gonzalez, R. Gonzalez-Arrabal “D-depth profiling in as-implanted and annealed Li-based Breeder Blanket ceramics” Journal of Nuclear Materials, Vol. 438, Issues 1–3 (2013) 193-198.


<hr>
[[LNF:Nationally Funded Projects|Back to list of nationally funded projects]]

[[Category:LNF Nationally Funded Projects]]

LNF: Exploration of novel (anti) corrosion and permeation barriers (EXCORPION)

2024-04-11T08:36:13Z

Martamalo: /* LNF - Nationally funded project */

== LNF - Nationally funded project ==
'''Title''': Exploration of novel (anti) corrosion and permeation
barriers (EXCORPION)

'''Reference''': PID2022-141926OA-I00

'''Programme and date''': Proyectos de Generación de Conocimiento, convocatoria 2022

'''Programme type (Modalidad de proyecto)''': Tipo A

'''Area/subarea (Área temática / subárea)''': Energía y transporte/Energía

'''Principal Investigator(s)''': Elisabetta Carella [https://orcid.org/0000-0002-4802-2546] and Marta Malo [https://orcid.org/0000-0002-0093-5004]

'''Project type''': Proyecto individual

'''Start-end dates''': 01/09/2023 - 01/09/2026

'''Financing granted (direct costs)''': 120000 €

== Description of the project ==

United Nations (UN) has declared a State of Climate Emergency until carbon neutrality
has been reached worldwide. EU has assumed a leading position in decarbonization,
going for a climate
-
neutral Europe in 2050. Much of this energy is still produced from
burning fossil fuels on a massive scale
.
The international effort on
the development of
alternative energy systems,
see the
CIEMAT
involved with different innovative projects
.
The development of new materials is a key question in different areas.
An urgent need for
developing advanced multi
-
functional coatings that can provide
protection against corrosion, gas permeation and/or provide determined features to
structural and functional base materials has been identified for multiple technological
applications.
For example,
a suitable protective layer for
structural steels
to minimize
tritium permeation and corrosive effects of the
PbLi
is fundamental for the development
of
some
key fusion reactor components.
High reflectivity and electrical conductivity
coatings are required for the new generati
on of solar cells. Low permeability is expected
for the development of hydrogen storage methods. Corrosion protection against molten
salts is required for applications
under nuclear fission conditions
, but also a protection of
the structural material from hydrogen embrittlement due to permeation
.
The global objective of the project is to
promote the development of coating
technologies
for applications in the Energy
sector.
Complex multifunctional coatings are key pieces for the consecution of sustainable and
safe new energy sources and must fulfil slightly different requirements depending on the
specific working area.
Due to the extreme expected operational
conditions, the most
restrictive demands are imposed for use in Fusion devices
. In particular, suitable
chemical composition in order to reduce neutron activation and hence minimize
radioactive waste is critical for the design of future fusion plants. This
consideration will
serve as a starting point for the selection of the candidate compositions for the
design
and fabrication
stage, together with the current existing background.
Cascade
validation of the fabricated coatings
is proposed from a lesser t
o
a
greater level of
specificity. This way, even though not every single requirement is met for (all)
of
the
examined coatings, their potential use in different disciplines will be considered
depending on the satisfied properties.
EXCORPION will study the abo
ve new materials
solutions in terms of
1) compatibility with different corrosive materials 2) hydrogen
isotopes permeation reduction 3) radiation tolerance by dedicated gamma and ion
irradiation experiments
4) validation to a system level and scale
-
up to w
elding and new
geometries
.
The
proposal
of
this
transversal
project
between
various
research
groups
highlights
the
need
for
synergies
to
obtain
new
materials
capable
of
meeting
all
the
extreme
conditions
to
which
they
are
subjected
and
improving
the
effic
iency
of
these
alternative
sources
for
energy
production
,
with
the
ultimate
goal
of
being
a
real
alternative
to
fossil
fuels


== References ==
1. M. Malo, A. Moroño and E. R. Hodgson, In situ luminescence qualifications of radiation damage in aluminas: F aggregation and Al colloids, Fusion Engineering and Design 89 (2014) 2179-2183.
2. M. Malo, A. Moroño, and E.R. Hodgson, “Radioluminescence characterization of SiC and SiC/SiC”, Journal of Nuclear Materials 442 (2013) s404-s409.
3. M. Carmona Gázquez, S. Bassini, T. Hernández and M. Utili “Al2O3 Coating as Barrier against corrosion in Pb-17Li” Fusion Engineering and Design Vol. 124, (2017) 837-840.
4. P. Muñoz, et. al, “Radiation effects on deuterium permeation for PLD alumina coated Eurofer steel measured during 1.8 MeV electron irradiation” Journal of Nuclear Materials 512 (2018) 118 – 125
5. T.Hernández, et al., “Corrosion protective action of different coatings for the helium cooled pebble breeder concept” Journal of Nuclear Materials 516 (2019) 160-168.
6. T. Hernández, et al., “Corrosion behavior of diverse sputtered coatings for the helium cooled pebbles bed (HCPB) breeder concept” Nuclear Materials and Energy, 25 (2020) 100795.
7. A. Moroño, E.R. Hodgson and M. Malo, “Radiation enhanced deuterium absorption for Al2O3 and macor ceramic”, Fusion Engineering and Design 88 (2013) 2488-2491.
8. T. Hernández, et al., “Study of deuterium permeation, retention, and desorption in SiC coatings submitted to relevant conditions for breeder blanket applications: thermal cycling effect under electron irradiation and oxygen exposure” Journal of Nuclear Materials 557 (2021) 153219
9. Gonzalez-Arrabal, R., Rivera, A., & Perlado, J. M. (2020). “Limitations for tungsten as plasma facing material in the diverse scenarios of the European inertial confinement fusion facility HiPER: Current status and new approaches” Matter and Radiation at Extremes, 5(5), 055201.
10. Panizo-Laiz, et al., (2019). “Experimental and computational studies of the influence of grain boundaries and temperature on the radiation-induced damage and hydrogen behavior in tungsten” Nuclear Fusion, 59(8).
11. C. Abed, et al., “Processing and Study of Optical and Electrical Properties of (Mg, Al) Co-Doped ZnO Thin Films Prepared by RF Magnetron Sputtering for Photovoltaic Application” Materials 13 (2020) 2146-2158.
12. S. Fernández, et al.”Non-treated low temperature indium tin oxide fabricated in oxygen-free environment to low-cost silicon-based solar technology” Vacuum 184 (2021) 109783.
13. S. Fernández, et al.,”Sputtered non-hydrogenated amorphous silicon as alternative absorber for silicon photovoltaic technology” Materials (2021), 14, 6550.
14. S. Fernández, et al., “Roles of low temperature sputtered indium tin oxide for solar photovoltaic technology” Materials (2021), 14, Issue 24, 7758.
15. S. Suárez, et al., Parameters to be considered for the development highly photoactive TiO2 layers on aluminium substrates by magnetron sputtering. Catalysis Today (In press).
16. E. Carella, D. Rapisarda, S.Lenk. “Design of the CIEMAT Corrosion Loop for Liquid Metal Experiments” Applied Sciences, 12 (2022), 3104.
17. E. Carella, C. Moreno, F. R. Urgorri, D. Rapisarda, A. Ibarra “Tritium modeling in HCPB breeder blanket at a system level” Fusion Engineering and Design, 124 (2017) 687-691.
18. E. Carella, M. Gonzalez, R. Gonzalez-Arrabal “D-depth profiling in as-implanted and annealed Li-based Breeder Blanket ceramics” Journal of Nuclear Materials, Vol. 438, Issues 1–3 (2013) 193-198.


<hr>
[[LNF:Nationally Funded Projects|Back to list of nationally funded projects]]

[[Category:LNF Nationally Funded Projects]]

LNF: Exploration of novel (anti) corrosion and permeation barriers (EXCORPION)

2024-04-11T08:32:59Z

Martamalo: /* LNF - Nationally funded project */

== LNF - Nationally funded project ==
'''Title''': Exploration of novel (anti) corrosion and permeation
barriers (EXCORPION)

'''Reference''': PID2022-141926OA-I00

'''Programme and date''': Proyectos de Generación de Conocimiento, convocatoria 2022

'''Programme type (Modalidad de proyecto)''': Tipo A

'''Area/subarea (Área temática / subárea)''': Energía y transporte/Energía

'''Principal Investigator(s)''': Elisabetta Carella [https://orcid.org/0000-0002-4802-2546] and Marta Malo [https://orcid.org/0000-0002-0093-5004]

'''Project type''': Proyecto individual

'''Start-end dates''': 01/09/2023 - 01/09/2026

'''Financing granted (direct costs)''': 90000 €

== Description of the project ==

United Nations (UN) has declared a State of Climate Emergency until carbon neutrality
has been reached worldwide. EU has assumed a leading position in decarbonization,
going for a climate
-
neutral Europe in 2050. Much of this energy is still produced from
burning fossil fuels on a massive scale
.
The international effort on
the development of
alternative energy systems,
see the
CIEMAT
involved with different innovative projects
.
The development of new materials is a key question in different areas.
An urgent need for
developing advanced multi
-
functional coatings that can provide
protection against corrosion, gas permeation and/or provide determined features to
structural and functional base materials has been identified for multiple technological
applications.
For example,
a suitable protective layer for
structural steels
to minimize
tritium permeation and corrosive effects of the
PbLi
is fundamental for the development
of
some
key fusion reactor components.
High reflectivity and electrical conductivity
coatings are required for the new generati
on of solar cells. Low permeability is expected
for the development of hydrogen storage methods. Corrosion protection against molten
salts is required for applications
under nuclear fission conditions
, but also a protection of
the structural material from hydrogen embrittlement due to permeation
.
The global objective of the project is to
promote the development of coating
technologies
for applications in the Energy
sector.
Complex multifunctional coatings are key pieces for the consecution of sustainable and
safe new energy sources and must fulfil slightly different requirements depending on the
specific working area.
Due to the extreme expected operational
conditions, the most
restrictive demands are imposed for use in Fusion devices
. In particular, suitable
chemical composition in order to reduce neutron activation and hence minimize
radioactive waste is critical for the design of future fusion plants. This
consideration will
serve as a starting point for the selection of the candidate compositions for the
design
and fabrication
stage, together with the current existing background.
Cascade
validation of the fabricated coatings
is proposed from a lesser t
o
a
greater level of
specificity. This way, even though not every single requirement is met for (all)
of
the
examined coatings, their potential use in different disciplines will be considered
depending on the satisfied properties.
EXCORPION will study the abo
ve new materials
solutions in terms of
1) compatibility with different corrosive materials 2) hydrogen
isotopes permeation reduction 3) radiation tolerance by dedicated gamma and ion
irradiation experiments
4) validation to a system level and scale
-
up to w
elding and new
geometries
.
The
proposal
of
this
transversal
project
between
various
research
groups
highlights
the
need
for
synergies
to
obtain
new
materials
capable
of
meeting
all
the
extreme
conditions
to
which
they
are
subjected
and
improving
the
effic
iency
of
these
alternative
sources
for
energy
production
,
with
the
ultimate
goal
of
being
a
real
alternative
to
fossil
fuels


== References ==
1. M. Malo, A. Moroño and E. R. Hodgson, In situ luminescence qualifications of radiation damage in aluminas: F aggregation and Al colloids, Fusion Engineering and Design 89 (2014) 2179-2183.
2. M. Malo, A. Moroño, and E.R. Hodgson, “Radioluminescence characterization of SiC and SiC/SiC”, Journal of Nuclear Materials 442 (2013) s404-s409.
3. M. Carmona Gázquez, S. Bassini, T. Hernández and M. Utili “Al2O3 Coating as Barrier against corrosion in Pb-17Li” Fusion Engineering and Design Vol. 124, (2017) 837-840.
4. P. Muñoz, et. al, “Radiation effects on deuterium permeation for PLD alumina coated Eurofer steel measured during 1.8 MeV electron irradiation” Journal of Nuclear Materials 512 (2018) 118 – 125
5. T.Hernández, et al., “Corrosion protective action of different coatings for the helium cooled pebble breeder concept” Journal of Nuclear Materials 516 (2019) 160-168.
6. T. Hernández, et al., “Corrosion behavior of diverse sputtered coatings for the helium cooled pebbles bed (HCPB) breeder concept” Nuclear Materials and Energy, 25 (2020) 100795.
7. A. Moroño, E.R. Hodgson and M. Malo, “Radiation enhanced deuterium absorption for Al2O3 and macor ceramic”, Fusion Engineering and Design 88 (2013) 2488-2491.
8. T. Hernández, et al., “Study of deuterium permeation, retention, and desorption in SiC coatings submitted to relevant conditions for breeder blanket applications: thermal cycling effect under electron irradiation and oxygen exposure” Journal of Nuclear Materials 557 (2021) 153219
9. Gonzalez-Arrabal, R., Rivera, A., & Perlado, J. M. (2020). “Limitations for tungsten as plasma facing material in the diverse scenarios of the European inertial confinement fusion facility HiPER: Current status and new approaches” Matter and Radiation at Extremes, 5(5), 055201.
10. Panizo-Laiz, et al., (2019). “Experimental and computational studies of the influence of grain boundaries and temperature on the radiation-induced damage and hydrogen behavior in tungsten” Nuclear Fusion, 59(8).
11. C. Abed, et al., “Processing and Study of Optical and Electrical Properties of (Mg, Al) Co-Doped ZnO Thin Films Prepared by RF Magnetron Sputtering for Photovoltaic Application” Materials 13 (2020) 2146-2158.
12. S. Fernández, et al.”Non-treated low temperature indium tin oxide fabricated in oxygen-free environment to low-cost silicon-based solar technology” Vacuum 184 (2021) 109783.
13. S. Fernández, et al.,”Sputtered non-hydrogenated amorphous silicon as alternative absorber for silicon photovoltaic technology” Materials (2021), 14, 6550.
14. S. Fernández, et al., “Roles of low temperature sputtered indium tin oxide for solar photovoltaic technology” Materials (2021), 14, Issue 24, 7758.
15. S. Suárez, et al., Parameters to be considered for the development highly photoactive TiO2 layers on aluminium substrates by magnetron sputtering. Catalysis Today (In press).
16. E. Carella, D. Rapisarda, S.Lenk. “Design of the CIEMAT Corrosion Loop for Liquid Metal Experiments” Applied Sciences, 12 (2022), 3104.
17. E. Carella, C. Moreno, F. R. Urgorri, D. Rapisarda, A. Ibarra “Tritium modeling in HCPB breeder blanket at a system level” Fusion Engineering and Design, 124 (2017) 687-691.
18. E. Carella, M. Gonzalez, R. Gonzalez-Arrabal “D-depth profiling in as-implanted and annealed Li-based Breeder Blanket ceramics” Journal of Nuclear Materials, Vol. 438, Issues 1–3 (2013) 193-198.


<hr>
[[LNF:Nationally Funded Projects|Back to list of nationally funded projects]]

[[Category:LNF Nationally Funded Projects]]

LNF: Exploration of novel (anti) corrosion and permeation barriers (EXCORPION)

2024-04-11T08:32:17Z

Martamalo: Created page with "== LNF - Nationally funded project == '''Title''': Exploration of novel (anti) corrosion and permeation barriers (EXCORPION) '''Reference''': PID2022-141926OA-I00 '''Programme and date''': Proyectos de Generación de Conocimiento, convocatoria 2022 '''Programme type (Modalidad de proyecto)''': Tipo A '''Area/subarea (Área temática / subárea)''': Energía y transporte/Energía '''Principal Investigator(s)''': Elisabetta Carella [https://orcid.org/0000-0002-4802-25..."

== LNF - Nationally funded project ==
'''Title''': Exploration of novel (anti) corrosion and permeation
barriers (EXCORPION)

'''Reference''': PID2022-141926OA-I00

'''Programme and date''': Proyectos de Generación de Conocimiento, convocatoria 2022

'''Programme type (Modalidad de proyecto)''': Tipo A

'''Area/subarea (Área temática / subárea)''': Energía y transporte/Energía

'''Principal Investigator(s)''': Elisabetta Carella [https://orcid.org/0000-0002-4802-2546] y Marta Malo [https://orcid.org/0000-0002-0093-5004]

'''Project type''': Proyecto individual

'''Start-end dates''': 01/09/2023 - 01/09/2026

'''Financing granted (direct costs)''': 90000 €

== Description of the project ==

United Nations (UN) has declared a State of Climate Emergency until carbon neutrality
has been reached worldwide. EU has assumed a leading position in decarbonization,
going for a climate
-
neutral Europe in 2050. Much of this energy is still produced from
burning fossil fuels on a massive scale
.
The international effort on
the development of
alternative energy systems,
see the
CIEMAT
involved with different innovative projects
.
The development of new materials is a key question in different areas.
An urgent need for
developing advanced multi
-
functional coatings that can provide
protection against corrosion, gas permeation and/or provide determined features to
structural and functional base materials has been identified for multiple technological
applications.
For example,
a suitable protective layer for
structural steels
to minimize
tritium permeation and corrosive effects of the
PbLi
is fundamental for the development
of
some
key fusion reactor components.
High reflectivity and electrical conductivity
coatings are required for the new generati
on of solar cells. Low permeability is expected
for the development of hydrogen storage methods. Corrosion protection against molten
salts is required for applications
under nuclear fission conditions
, but also a protection of
the structural material from hydrogen embrittlement due to permeation
.
The global objective of the project is to
promote the development of coating
technologies
for applications in the Energy
sector.
Complex multifunctional coatings are key pieces for the consecution of sustainable and
safe new energy sources and must fulfil slightly different requirements depending on the
specific working area.
Due to the extreme expected operational
conditions, the most
restrictive demands are imposed for use in Fusion devices
. In particular, suitable
chemical composition in order to reduce neutron activation and hence minimize
radioactive waste is critical for the design of future fusion plants. This
consideration will
serve as a starting point for the selection of the candidate compositions for the
design
and fabrication
stage, together with the current existing background.
Cascade
validation of the fabricated coatings
is proposed from a lesser t
o
a
greater level of
specificity. This way, even though not every single requirement is met for (all)
of
the
examined coatings, their potential use in different disciplines will be considered
depending on the satisfied properties.
EXCORPION will study the abo
ve new materials
solutions in terms of
1) compatibility with different corrosive materials 2) hydrogen
isotopes permeation reduction 3) radiation tolerance by dedicated gamma and ion
irradiation experiments
4) validation to a system level and scale
-
up to w
elding and new
geometries
.
The
proposal
of
this
transversal
project
between
various
research
groups
highlights
the
need
for
synergies
to
obtain
new
materials
capable
of
meeting
all
the
extreme
conditions
to
which
they
are
subjected
and
improving
the
effic
iency
of
these
alternative
sources
for
energy
production
,
with
the
ultimate
goal
of
being
a
real
alternative
to
fossil
fuels


== References ==
1. M. Malo, A. Moroño and E. R. Hodgson, In situ luminescence qualifications of radiation damage in aluminas: F aggregation and Al colloids, Fusion Engineering and Design 89 (2014) 2179-2183.
2. M. Malo, A. Moroño, and E.R. Hodgson, “Radioluminescence characterization of SiC and SiC/SiC”, Journal of Nuclear Materials 442 (2013) s404-s409.
3. M. Carmona Gázquez, S. Bassini, T. Hernández and M. Utili “Al2O3 Coating as Barrier against corrosion in Pb-17Li” Fusion Engineering and Design Vol. 124, (2017) 837-840.
4. P. Muñoz, et. al, “Radiation effects on deuterium permeation for PLD alumina coated Eurofer steel measured during 1.8 MeV electron irradiation” Journal of Nuclear Materials 512 (2018) 118 – 125
5. T.Hernández, et al., “Corrosion protective action of different coatings for the helium cooled pebble breeder concept” Journal of Nuclear Materials 516 (2019) 160-168.
6. T. Hernández, et al., “Corrosion behavior of diverse sputtered coatings for the helium cooled pebbles bed (HCPB) breeder concept” Nuclear Materials and Energy, 25 (2020) 100795.
7. A. Moroño, E.R. Hodgson and M. Malo, “Radiation enhanced deuterium absorption for Al2O3 and macor ceramic”, Fusion Engineering and Design 88 (2013) 2488-2491.
8. T. Hernández, et al., “Study of deuterium permeation, retention, and desorption in SiC coatings submitted to relevant conditions for breeder blanket applications: thermal cycling effect under electron irradiation and oxygen exposure” Journal of Nuclear Materials 557 (2021) 153219
9. Gonzalez-Arrabal, R., Rivera, A., & Perlado, J. M. (2020). “Limitations for tungsten as plasma facing material in the diverse scenarios of the European inertial confinement fusion facility HiPER: Current status and new approaches” Matter and Radiation at Extremes, 5(5), 055201.
10. Panizo-Laiz, et al., (2019). “Experimental and computational studies of the influence of grain boundaries and temperature on the radiation-induced damage and hydrogen behavior in tungsten” Nuclear Fusion, 59(8).
11. C. Abed, et al., “Processing and Study of Optical and Electrical Properties of (Mg, Al) Co-Doped ZnO Thin Films Prepared by RF Magnetron Sputtering for Photovoltaic Application” Materials 13 (2020) 2146-2158.
12. S. Fernández, et al.”Non-treated low temperature indium tin oxide fabricated in oxygen-free environment to low-cost silicon-based solar technology” Vacuum 184 (2021) 109783.
13. S. Fernández, et al.,”Sputtered non-hydrogenated amorphous silicon as alternative absorber for silicon photovoltaic technology” Materials (2021), 14, 6550.
14. S. Fernández, et al., “Roles of low temperature sputtered indium tin oxide for solar photovoltaic technology” Materials (2021), 14, Issue 24, 7758.
15. S. Suárez, et al., Parameters to be considered for the development highly photoactive TiO2 layers on aluminium substrates by magnetron sputtering. Catalysis Today (In press).
16. E. Carella, D. Rapisarda, S.Lenk. “Design of the CIEMAT Corrosion Loop for Liquid Metal Experiments” Applied Sciences, 12 (2022), 3104.
17. E. Carella, C. Moreno, F. R. Urgorri, D. Rapisarda, A. Ibarra “Tritium modeling in HCPB breeder blanket at a system level” Fusion Engineering and Design, 124 (2017) 687-691.
18. E. Carella, M. Gonzalez, R. Gonzalez-Arrabal “D-depth profiling in as-implanted and annealed Li-based Breeder Blanket ceramics” Journal of Nuclear Materials, Vol. 438, Issues 1–3 (2013) 193-198.


<hr>
[[LNF:Nationally Funded Projects|Back to list of nationally funded projects]]

[[Category:LNF Nationally Funded Projects]]

LNF:Organization

2023-01-31T10:51:03Z

Martamalo:

== Laboratorio Nacional de Fusión ==

Asociación [[Euratom]]-[[CIEMAT]]: see [[Laboratorio Nacional de Fusión]].

Contact information is also available via the [http://www.ciemat.es/cargarFichaOrganizacion.do?idOrganizacion=F00 CIEMAT website]

The telephone numbers listed below are extensions; to call from outside the laboratory, dial: +34-91346xxxx, where xxxx is the extension. (When using 4-digit dialing from inside the laboratory: substitute any initial "0" by a "7".)

[https://www.gruptelecom.com/wp-content/uploads/2018/07/Manual_Unify_CP-200.pdf IP-phone manual]

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Hidalgo Vera, Carlos, Director || 6498 ||
|-
| Guerard Ortego, Carlos Kjell || - ||
|-
|}

=== TJ-II Experimental Division ===

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Alonso de Pablo, Arturo || +49 3834 88 2342 ||
|-
| Baciero Adrados, Alfonso || 6493 || 362601
|-
| Blanco Villareal, Emilio J. || 7904 ||
|-
| de la Cal Heusch, Eduardo || 6317 ||
|-
| Carralero Ortiz, Daniel || 7852 ||
|-
| Castro Rojo, Rodrigo || 6419 ||
|-
| Estrada García, Mª. Teresa || 0845 ||
|-
| Fontdecaba Climent, Jose María || 6642 ||
|-
| García Cortés, Mª. Isabel || 6515 || 362625
|-
| Hernanz Hernanz, Francisco J. || 6641 ||
|-
| López Miranda, Belén || || 362093
|-
| McCarthy, Kieran Joseph || 0846 || 362934
|-
| Medina Yela, Francisco || 0847 || 362935
|-
| Ochando Garcia, Mª. Antonia || 6462 ||
|-
| de Pablos Hernández, Jose Luis || 6374 ||
|-
| Panadero Álvarez, Nerea || 6642 || 362781
|-
| Pastor Díaz, Ignacio || 6324 ||
|-
| Pastor Santos, Carmen || || 362564
|-
| Rattá Gutiérrez, Giuseppe A. || 7917 ||
|-
| Rodríguez Fernández, Mª. Carmen || 2611 ||
|-
| [[User:Admin|van Milligen, Boudewijn]] || 6379 || 362482
|-
| Vega Sánchez, Jesús Antonio || 6474 ||
|}

=== TJ-II Operation Division===

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Ascasíbar, Enrique, Head Investigator || 6369 ||
|-
| Alegre Castro, Daniel || 0914 ||
|-
| Cappa Ascasíbar, Alvaro || 6646 Sala de Control ECRH 6828 ||
|-
| Cebrián Ruiz, Luis A. || 6338 ||
|-
| Chamorro Lastra, Manuel || 6641 ||
|-
| García Gomez, Raúl || 6641 ||
|-
| Guasp Pérez, Jose || 6510 ||
|-
| Guisse Arévalo, Víctor H. || 6285 ||
|-
| Liniers Vazquez, Macarena || 0844 Sala de Control NBI 6851 ||
|-
| Martín Diaz, Fernando || 0920 Sala de Control NBI 6851 ||
|-
| Martinez Fernandez, Jose || 6646 Sala de Control ECRH 6828 ||
|-
| Bueno Jañez, Luis Alberto || 6285 ||
|-
| Miguel Honrubia, Francisco J. || 6762 ||
|-
| Navarro Santana Miguel || 6824 ||
|-
| Pereira Gonzalez, Augusto || 0929 ||
|-
| Portas Ferreiro, Ana Belén || 0929 ||
|-
| Ros Vivancos, Alfonso || 6642 Sala de Control ECRH 6828 Lab. μOndas 6808 || 362782
|-
| Sánchez Sarabia, Emilio || 6762 ||
|-
| Sebastián Alfaro, José Antonio || 6684 Sala de Control NBI 6851 || 362828
|-
| Tabarés Vazquez, Francisco Luis || 6458 ||
|-
| Tafalla García, David || 0843 ||
|-
| Tolkachev, Alexander || 6828 ||
|}

=== Fusion Theory Unit ===

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Calvo Rubio, Iván, Head Investigator || 6739 || 362872
|-
| Escoto López, Francisco Javier || ||
|-
| García Regaña, José Manuel || 7850 || 362938
|-
| Godino Sedano, Guillermo Luis || ||
|-
| González Jerez, Antonio || 7916 ||
|-
| López Bruna, Daniel || 6638 ||
|-
| [[User:Esolano|Solano (Rodríguez-Solano Ribeiro), Emilia R.]]|| 6153 ||
|-
| Sánchez González, Edilberto || 6162 ||
|-
| Thienpondt, Hanne || ||
|-
| Velasco Garasa, José Luis || 6504 || 362610
|}

=== Engineering Unit ===

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Alonso, José Javier, Head Investigator || 6639 ||
|-
| Cabrera Pérez, Santiago || || 362994
|-
| Carrasco García, Ricardo || 7928 ||
|-
| Jimenez Denche, Andrés Enrique || 6584 ||
|-
| Kirpitchev, Igor || 6337 ||
|-
| Lapayese Puebla, Fernando || 0928 ||
|-
| Medrano Casanova, Mercedes || 6639 ||
|-
| Méndez Montero, Purificación || 6337 ||
|-
| de la Peña Gómez, Ángel || 6644 ||
|-
| Queral Mas, Vicente || 6419 || 362518
|-
| Ramos Rivero, Francisco || 6584 ||
|-
| Rincón Rincón, María Esther || 6637 ||
|-
| Soleto Palomo, M. Alfonso || 6636 ||
|-
| Weber Suárez, Moisés || 6636 ||
|}

=== Technology Division ===

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Rapisarda Socorro, David, Head Investigator || 0913/6335 (prov) || 362998
|-
| Brañas Lasala, Beatriz || 6289 ||
|-
| Carella, Elisabetta || 6507 ||
|-
| Fernández Berceruelo, Iván || 2579 ||
|-
| García Gonzalez, Juan Manuel || 7842 ||
|-
| Gonzalez Viada, María || 2582 ||
|-
| Hernandez Diaz, Mª. Teresa || 2581 ||
|-
| Herranz Marco, Jesús Antonio || 0848 ||
|-
| Jimenez Baena, Francisco M. || 6204 ||
|-
| Jiménez Rey, David || 6640 ||
|-
| Malo Huerta, Marta || 6636 || 362769
|-
| Martín Laso, Montserrat || 6512 ||
|-
| Molla Lorente, Joaquín || 6580 ||
|-
| de la Morena Álvarez-Palencia, Cristina || 2600 ||
|-
| Moroño Guadalajara, Alejandro A. || 6372 ||
|-
| Mota García, Fernando || 6578 || 362708
|-
| Ortíz, Christophe || 2582 ||
|-
| Palermo, Iole || 6784 ||
|-
| Regidor Serrano, David || 6584 ||
|-
| Roldán Blanco, Marcelo || 2574 Lab. 6512 ||
|-
| Román Chacón, Raquel || 6203 ||
|-
| Sánchez Sanz, Fernando José || 6578 FIB-SEM 6790 ||
|-
| Valle Paisan, Francisco J. || 6204 ||
|-
| Vila Vazquez, Rafael Alberto || 6580 ||
|-
| Villamayor Callejo, Víctor || 6578 ||
|-
|}

=== Support Unit ===

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Barrera Orte, Laura || || 362262
|-
| Fernandez-Mayoralas López, Lorena || 6663 ||
|-
| Moreno García, Sabina || 6159 ||
|-
| Sánchez Rubio, Cristina || 6738 ||
|}

LNF:Organization

2023-01-31T10:49:56Z

Martamalo:

== Laboratorio Nacional de Fusión ==

Asociación [[Euratom]]-[[CIEMAT]]: see [[Laboratorio Nacional de Fusión]].

Contact information is also available via the [http://www.ciemat.es/cargarFichaOrganizacion.do?idOrganizacion=F00 CIEMAT website]

The telephone numbers listed below are extensions; to call from outside the laboratory, dial: +34-91346xxxx, where xxxx is the extension. (When using 4-digit dialing from inside the laboratory: substitute any initial "0" by a "7".)

[https://www.gruptelecom.com/wp-content/uploads/2018/07/Manual_Unify_CP-200.pdf IP-phone manual]

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Hidalgo Vera, Carlos, Director || 6498 ||
|-
| Guerard Ortego, Carlos Kjell || - ||
|-
|}

=== TJ-II Experimental Division ===

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Alonso de Pablo, Arturo || +49 3834 88 2342 ||
|-
| Baciero Adrados, Alfonso || 6493 || 362601
|-
| Blanco Villareal, Emilio J. || 7904 ||
|-
| de la Cal Heusch, Eduardo || 6317 ||
|-
| Carralero Ortiz, Daniel || 7852 ||
|-
| Castro Rojo, Rodrigo || 6419 ||
|-
| Estrada García, Mª. Teresa || 0845 ||
|-
| Fontdecaba Climent, Jose María || 6642 ||
|-
| García Cortés, Mª. Isabel || 6515 || 362625
|-
| Hernanz Hernanz, Francisco J. || 6641 ||
|-
| López Miranda, Belén || || 362093
|-
| McCarthy, Kieran Joseph || 0846 || 362934
|-
| Medina Yela, Francisco || 0847 || 362935
|-
| Ochando Garcia, Mª. Antonia || 6462 ||
|-
| de Pablos Hernández, Jose Luis || 6374 ||
|-
| Panadero Álvarez, Nerea || 6642 || 362781
|-
| Pastor Díaz, Ignacio || 6324 ||
|-
| Pastor Santos, Carmen || || 362564
|-
| Rattá Gutiérrez, Giuseppe A. || 7917 ||
|-
| Rodríguez Fernández, Mª. Carmen || 2611 ||
|-
| [[User:Admin|van Milligen, Boudewijn]] || 6379 || 362482
|-
| Vega Sánchez, Jesús Antonio || 6474 ||
|}

=== TJ-II Operation Division===

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Ascasíbar, Enrique, Head Investigator || 6369 ||
|-
| Alegre Castro, Daniel || 0914 ||
|-
| Cappa Ascasíbar, Alvaro || 6646 Sala de Control ECRH 6828 ||
|-
| Cebrián Ruiz, Luis A. || 6338 ||
|-
| Chamorro Lastra, Manuel || 6641 ||
|-
| García Gomez, Raúl || 6641 ||
|-
| Guasp Pérez, Jose || 6510 ||
|-
| Guisse Arévalo, Víctor H. || 6285 ||
|-
| Liniers Vazquez, Macarena || 0844 Sala de Control NBI 6851 ||
|-
| Martín Diaz, Fernando || 0920 Sala de Control NBI 6851 ||
|-
| Martinez Fernandez, Jose || 6646 Sala de Control ECRH 6828 ||
|-
| Bueno Jañez, Luis Alberto || 6285 ||
|-
| Miguel Honrubia, Francisco J. || 6762 ||
|-
| Navarro Santana Miguel || 6824 ||
|-
| Pereira Gonzalez, Augusto || 0929 ||
|-
| Portas Ferreiro, Ana Belén || 0929 ||
|-
| Ros Vivancos, Alfonso || 6642 Sala de Control ECRH 6828 Lab. μOndas 6808 || 362782
|-
| Sánchez Sarabia, Emilio || 6762 ||
|-
| Sebastián Alfaro, José Antonio || 6684 Sala de Control NBI 6851 || 362828
|-
| Tabarés Vazquez, Francisco Luis || 6458 ||
|-
| Tafalla García, David || 0843 ||
|-
| Tolkachev, Alexander || 6828 ||
|}

=== Fusion Theory Unit ===

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Calvo Rubio, Iván, Head Investigator || 6739 || 362872
|-
| Escoto López, Francisco Javier || ||
|-
| García Regaña, José Manuel || 7850 || 362938
|-
| Godino Sedano, Guillermo Luis || ||
|-
| González Jerez, Antonio || 7916 ||
|-
| López Bruna, Daniel || 6638 ||
|-
| [[User:Esolano|Solano (Rodríguez-Solano Ribeiro), Emilia R.]]|| 6153 ||
|-
| Sánchez González, Edilberto || 6162 ||
|-
| Thienpondt, Hanne || ||
|-
| Velasco Garasa, José Luis || 6504 || 362610
|}

=== Engineering Unit ===

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Alonso, José Javier, Head Investigator || 6639 ||
|-
| Cabrera Pérez, Santiago || || 362994
|-
| Carrasco García, Ricardo || 7928 ||
|-
| Jimenez Denche, Andrés Enrique || 6584 ||
|-
| Kirpitchev, Igor || 6337 ||
|-
| Lapayese Puebla, Fernando || 0928 ||
|-
| Medrano Casanova, Mercedes || 6639 ||
|-
| Méndez Montero, Purificación || 6337 ||
|-
| de la Peña Gómez, Ángel || 6644 ||
|-
| Queral Mas, Vicente || 6419 || 362518
|-
| Ramos Rivero, Francisco || 6584 ||
|-
| Rincón Rincón, María Esther || 6637 ||
|-
| Soleto Palomo, M. Alfonso || 6636 ||
|-
| Weber Suárez, Moisés || 6636 ||
|}

=== Technology Division ===

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Rapisarda Socorro, David, Head Investigator || 0913/6335 (prov) || 362998
|-
| Brañas Lasala, Beatriz || 6289 ||
|-
| Carella, Elisabetta || 6507 ||
|-
| Fernández Berceruelo, Iván || 2579 ||
|-
| García Gonzalez, Juan Manuel || 7842 ||
|-
| Gonzalez Viada, María || 2582 ||
|-
| Hernandez Diaz, Mª. Teresa || 2581 ||
|-
| Herranz Marco, Jesús Antonio || 0848 ||
|-
| Jimenez Baena, Francisco M. || 6204 ||
|-
| Jiménez Rey, David || 6640 ||
|-
| Malo Huerta, Marta || 6636 ||
|-
| Martín Laso, Montserrat || 6512 ||
|-
| Molla Lorente, Joaquín || 6580 ||
|-
| de la Morena Álvarez-Palencia, Cristina || 2600 ||
|-
| Moroño Guadalajara, Alejandro A. || 6372 ||
|-
| Mota García, Fernando || 6578 || 362708
|-
| Ortíz, Christophe || 2582 ||
|-
| Palermo, Iole || 6784 ||
|-
| Regidor Serrano, David || 6584 ||
|-
| Roldán Blanco, Marcelo || 2574 Lab. 6512 ||
|-
| Román Chacón, Raquel || 6203 ||
|-
| Sánchez Sanz, Fernando José || 6578 FIB-SEM 6790 ||
|-
| Valle Paisan, Francisco J. || 6204 ||
|-
| Vila Vazquez, Rafael Alberto || 6580 ||
|-
| Villamayor Callejo, Víctor || 6578 ||
|-
|}

=== Support Unit ===

{|class="wikitable" style="vertical-align:top;"||
|-
!Name!!Telephone (old)!!IP-phone
|-
| Barrera Orte, Laura || || 362262
|-
| Fernandez-Mayoralas López, Lorena || 6663 ||
|-
| Moreno García, Sabina || 6159 ||
|-
| Sánchez Rubio, Cristina || 6738 ||
|}