Search Results - "Lanchi, M"

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  1. 1

    Environmental Impacts of a Solar Dish Coupled With a Micro-Gas Turbine for Power Generation by Agostini, A., Carbone, C., Lanchi, M., Miliozzi, A., Misceo, M., Russo, V.

    Published in Frontiers in energy research (23-11-2021)
    “…Concentrated solar power (CSP) systems are regarded as a renewable energy source technology that can contribute to decoupling the energy mix from fossil fuel…”
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    Journal Article
  2. 2

    Hydrogen/methanol production by sulfur–iodine thermochemical cycle powered by combined solar/fossil energy by Giaconia, A., Grena, R., Lanchi, M., Liberatore, R., Tarquini, P.

    Published in International journal of hydrogen energy (01-03-2007)
    “…Hydrogen production from water using the sulfur–iodine (S–I) thermochemical cycle, powered by combined solar and fossil heat sources, has been investigated…”
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    Journal Article
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    Decomposition of hydrogen iodide in the S–I thermochemical cycle over Ni catalyst systems by Favuzza, P., Felici, C., Lanchi, M., Liberatore, R., Mazzocchia, C.V., Spadoni, A., Tarquini, P., Tito, A.C.

    Published in International journal of hydrogen energy (01-05-2009)
    “…The sulphur–iodine thermochemical cycle for hydrogen production has been investigated by ENEA (Agency of New Technologies, Energy and Environment, Italy) over…”
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    Journal Article Conference Proceeding
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    Cu–Zn–Al based catalysts for low temperature bioethanol steam reforming by solar energy by Sau, G.S., Bianco, F., Lanchi, M., Liberatore, R., Mazzocchia, C.V., Spadoni, A., Tito, C.A., Tarquini, P., Diaz, G., Pin, F.

    Published in International journal of hydrogen energy (01-07-2010)
    “…Bioethanol steam reforming is one of the most promising route to produce hydrogen from a renewable liquid biofuel. Activity of two Cu–Zn–Al based catalysts was…”
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    Journal Article
  9. 9

    Fluidized bed reactor sizing using manganese aluminium spinel for thermochemical storage by Liberatore, R., Delise, T., Tizzoni, A.C., Spadoni, A., Mansi, E., Corsaro, N., Turchetti, L., Morabito, T., Lanchi, M., Sau, S.

    Published in Journal of energy storage (01-02-2024)
    “…In the field of high-temperature thermal energy storage, the use of reacting systems that reversibly decompose and regenerate, absorbing and releasing heat on…”
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    Journal Article
  10. 10

    Thermochemical heat storage through CaO-Mayenite/CaCO3 system: Thermal performances comparison for two synthesis methods by Spadoni, A., Sau, S., Corsaro, N., Lanchi, M., Tizzoni, A.C., Veca, E., Falconieri, M., Della Seta, L., De Girolamo Del Mauro, A., Turchetti, L., Mansi, E., Liberatore, R.

    Published in Journal of energy storage (20-11-2023)
    “…ThermoChemical Storage systems (TCS) are gaining attention for long term-thermal energy storage applications. Those systems can successfully increase the…”
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    Journal Article
  11. 11

    Thermal characterization of a cavity receiver for hydrogen production by thermochemical cycles operating at moderate temperatures by Lanchi, Michela, Varsano, Francesca, Brunetti, Bruno, Murmura, Maria Anna, Annesini, Maria Cristina, Turchetti, Luca, Grena, Roberto

    Published in Solar energy (01-06-2013)
    “…•A cavity receiver has been realized for powering the ENEA mixed ferrites cycle.•Thanks to the moderate operating T the receiver is made of conventional…”
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    Journal Article
  12. 12

    Use of metallic Ni for H 2 production in S–I thermochemical cycle: Experimental and theoretical analysis by Lanchi, M., Caputo, G., Liberatore, R., Marrelli, L., Sau, S., Spadoni, A., Tarquini, P.

    Published in International journal of hydrogen energy (01-02-2009)
    “…The gaseous hydrogen iodide decomposition is a thermodynamically limited reaction and subsequently a considerable energy expense for the separation and…”
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    Journal Article
  13. 13

    Experimental vapour–liquid equilibrium data of HI–H 2O–I 2 mixtures for hydrogen production by Sulphur–Iodine thermochemical cycle by Liberatore, R., Ceroli, A., Lanchi, M., Spadoni, A., Tarquini, P.

    “…The Sulphur–Iodine thermochemical cycle for hydrogen production has been investigated by ENEA in the framework of the Italian TEPSI Project whose main…”
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    Journal Article
  14. 14

    HI extraction by H sub(3PO) sub(4) in the Sulfur-Iodine thermochemical water splitting cycle: Composition optimization of the HI/H sub(2O/H) sub(3)PO sub(4/I) sub(2) biphasic quaternary system by Lanchi, M, Laria, F, Liberatore, R, Marrelli, L, Sau, S, Spadoni, A, Tarquini, P

    Published in International journal of hydrogen energy (01-08-2009)
    “…Iodine excess separation from hydriodic acid (HI) is one of the most challenging steps of the Sulfur-Iodine thermochemical water splitting cycle. One promising…”
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    Journal Article
  15. 15

    S-I thermochemical cycle: A thermodynamic analysis of the HI-H sub(2O-I) sub(2) system and design of the HI sub(x decomposition section) by Lanchi, M, Ceroli, A, Liberatore, R, Marrelli, L, Maschietti, M, Spadoni, A, Tarquini, P

    Published in International journal of hydrogen energy (01-03-2009)
    “…It is widely agreed that the most energy consuming part of the Sulphur-Iodine (S-I) thermochemical cycle for hydrogen production is represented by separation…”
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    Journal Article
  16. 16

    Use of metallic Ni for H sub(2 production in S-I thermochemical cycle: Experimental and theoretical analysis) by Lanchi, M, Caputo, G, Liberatore, R, Marrelli, L, Sau, S, Spadoni, A, Tarquini, P

    Published in International journal of hydrogen energy (01-02-2009)
    “…The gaseous hydrogen iodide decomposition is a thermodynamically limited reaction and subsequently a considerable energy expense for the separation and…”
    Get full text
    Journal Article
  17. 17

    S–I thermochemical cycle: A thermodynamic analysis of the HI–H 2O–I 2 system and design of the HI x decomposition section by Lanchi, M., Ceroli, A., Liberatore, R., Marrelli, L., Maschietti, M., Spadoni, A., Tarquini, P.

    “…It is widely agreed that the most energy consuming part of the Sulphur–Iodine (S–I) thermochemical cycle for hydrogen production is represented by separation…”
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    Journal Article
  18. 18

    HI extraction by H 3PO 4 in the Sulfur–Iodine thermochemical water splitting cycle: Composition optimization of the HI/H 2O/H 3PO 4/I 2 biphasic quaternary system by Lanchi, M., Laria, F., Liberatore, R., Marrelli, L., Sau, S., Spadoni, A., Tarquini, P.

    “…Iodine excess separation from hydriodic acid (HI) is one of the most challenging steps of the Sulfur–Iodine thermochemical water splitting cycle. One promising…”
    Get full text
    Journal Article
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