RESEARCH

Publications:  

Google Scholars Citation Page
ORCID
a) Refereed Journals
  1. Mass transfer analysis of the pervaporative separation of chloroform from aqueous solutions in hollow fiber devices, A.M. Urtiaga, E.D. Gorri, J.K. Beasley and I. Ortiz, Journal of Membrane Science, 156 (1999) pages 275-291.
  2. Modeling of the concentration – polarization effects in a pervaporation cell with radial flow, A.M. Urtiaga, E.D. Gorri, I. Ortiz, Separation & Purification Technology 17 (1999) pages 41-51.
  3. Parallelism and differences of pervaporation and vacuum membrane distillation in the removal of VOCs from aqueous streams, A.M. Urtiaga, E.D. Gorri, G. Ruiz, I. Ortiz, Separation & Purification Technology 22-23 (2001) pages 327-337.
  4. Mass transfer modeling in the pervaporation of VOCs from diluted aqueous solutions, A.M. Urtiaga, E.D. Gorri, I. Ortiz, AIChE Journal 48 (2002) pages 572-581.
  5. Scale-up of the adsorptive styrene drying, M. J. Rivero, Daniel Gorri, Raquel Ibáñez, I. Ortiz, Polymer International 51 (2002) pages 792-799.
  6. Pervaporative dehydration of industrial solvents using a zeolite NaA commercial membrane, A.M. Urtiaga, E.D. Gorri, C. Casado and I. Ortiz, Separation & Purification Technology 32 (2003) pages 207-213.
  7. Funcionamiento de una membrana de zeolita 4-A comercial en la deshidratación de disolventes industriales mediante pervaporación, , A.M. Urtiaga, E.D. Gorri, C. Casado, I. Ortiz, Boletín de la Sociedad Española de Cerámica y Vidrio 43 (2004) pages 35-37 .
  8. Pervaporative dehydration of organic mixtures using a commercial silica membrane. Determination of kinetic parameters, C. Casado, A. Urtiaga, E.D. Gorri and I. Ortiz, Separation & Purification Technology 42 (2005) pages 39-45.
  9. Modelling of the pervaporative flux through hydrophilic membranes, I. Ortiz, E.D. Gorri, C. Casado and A.M. Urtiaga, Journal of Chemical Technology & Biotechnology 80 (2005) pages 397-405.
  10. Pervaporative recovery of acetic acid from an acetylation industrial effluent using commercial membranes, E.D. Gorri, A.M. Urtiaga and I. Ortiz, Industrial & Engineering Chemistry Research 44 (2005) pages 977-985.
  11. Laboratory and pilot plant scale study on dehydration of cyclohexane by pervaporation, I. Ortiz, A.M. Urtiaga, R. Ibáñez, P. Gómez and E.D. Gorri, Journal of Chemical Technology & Biotechnology 81 (2006) pages 48-57.
  12. Pervaporative recovery of isopropanol from industrial effluents, A.M. Urtiaga, E.D. Gorri and I. Ortiz, Separation & Purification Technology 49 (2006) pages 245-252.
  13. Comparative study of the separation of methanol-methyl acetate mixtures by pervaporation and vapor permeation using a commercial membrane, E.D. Gorri, R. Ibáñez, I. Ortiz, Journal of Membrane Science 280 (2006) pages 582-593.
  14. Pervaporation technology for the dehydration of solvents and raw materials in the process industry, A.M. Urtiaga, E.D. Gorri, P. Gómez, C. Casado, R. Ibáñez, I. Ortiz, Drying Technology 25 (2007) pages 1819-1828.
  15. Separation and concentration of bilberry impact aroma compound from dilute model solution by pervaporation, V. García, N. Diban, E.D. Gorri, R. Keiski, A. Urtiaga, I. Ortiz, Journal of Chemical Technology & Biotechnology 83 (2008) pages 973-982.
  16. Room temperature ionic liquid with silver salt as efficient reaction media for propylene/propane separation: Absorption equilibrium, A. Ortiz, A. Ruiz, D. Gorri, I. Ortiz, Separation & Purification Technology 63 (2008) pages 311-318.
  17. Water and methanol permeation through short-side-chain perfluorosulphonic acid ionomeric membranes, E.D. Gorri, M.G. De Angelis, M. Giacinti Baschetti, G.C. Sarti, Journal of Membrane Science 322 (2008) pages 383-391.
  18. The use of ionic liquids as efficient extraction medium in the reactive separation of cycloolefines from cyclohexane, E.D. Gorri, A. Ruiz, A. Ortiz, I. Ortiz, Chemical Engineering Journal 154 (2009) pages 241-245.
  19. Kinetics of reactive absorption of propylene in RTIL-Ag+ media, A. Ortiz, L.M. Galán, D. Gorri, A.B. de Haan, I. Ortiz, Separation & Purification Technology 73 (2010) pages 106-113.
  20. Separation of propylene/propane mixtures using Ag+- RTIL solutions. Evaluation and comparison of the performance of gas–liquid contactors, A. Ortiz, D. Gorri, A. Irabien, I. Ortiz, Journal of Membrane Science 360 (2010) pages 130-141.
  21. Reactive ionic liquid media for the separation of propylene/propane gaseous mixtures, A. Ortiz, L.M. Galán, D. Gorri, A.B. de Haan, I. Ortiz, Industrial & Engineering Chemistry Research 49 (2010) pages 7227-7233.
  22. Organochlorine pesticide residues in sediments from coastal environment of Cantabria (Northern Spain) and evaluation of the Atlantic Ocean, S. Gómez, D. Gorri, A. Irabien, Environmental Monitoring and Assessment 176 (2011) pages 385-401.
  23. Dual-sorption model for CO2 / H2 permeation in glassy polymeric Matrimid membrane, O.C. David, D. Gorri, I. Ortiz, A. Urtiaga, Desalination & Water Treatment 27 (2011) pages 31-36.
  24. Effect of liquid flow on the separation of propylene/propane mixtures with a gas/liquid membrane contactor using Ag+- RTIL solutions, M. Fallanza, A. Ortiz, D. Gorri, I. Ortiz, Desalination & Water Treatment 27 (2011) pages 123-129.
  25. Assessment of PCDD/Fs and PCBs in sediments from the Spanish Northern Atlantic Coast, S. Gómez, D. Gorri, A. Irabien, Water, Air, & Soil Pollution 221 (2011) pages 287-299.
  26. Mixed gas separation study for the hydrogen recovery from H2/CO/N2/CO2 post combustion mixtures using a Matrimid membrane, O.C. David, D. Gorri, A. Urtiaga, I. Ortiz, Journal of Membrane Science 378 (2011) pages 359-368.
  27. Improving the mass transfer rate in G-L membrane contactors with ionic liquids as absorption medium. Recovery of propylene, M. Fallanza, A. Ortiz, D. Gorri, I. Ortiz, Journal of Membrane Science 385-386 (2011) pages 217-225
  28. Experimental study of the separation of propane/propylene mixtures by supported ionic liquid membranes containing Ag+–RTILs as carrier, M. Fallanza, A. Ortiz, D. Gorri, I. Ortiz, Separation & Purification Technology 97 (2012) pages 83-89.
  29. On the improved absorption of CO in the ionic liquid 1-hexyl-3-methylimidazolium chlorocuprate, O.C. David, G. Zarca, D. Gorri, A. Urtiaga, I. Ortiz, Separation & Purification Technology 97 (2012) pages 65-72
  30. Hydrogen separation from multicomponent gas mixtures containing CO, N2 and CO2 using Matrimid asymmetric hollow fiber membranes, O.C. David, D. Gorri, K. Nijmeijer, I Ortiz and A. Urtiaga, Journal of Membrane Science 419-420 (2012) pages 49-56. 
  31.  Screening of RTILs for propane/propylene separation using COSMO-RS methodology, M. Fallanza, M. González-Miquel, E. Ruiz, A. Ortiz, D.Gorri, J. Palomar, I. Ortiz, Chemical Engineering Journal 220 (2013) pages 284-293.
  32. Using membrane reactive absorption modeling to predict optimum process conditions in the separation of propane-propylene mixtures, M. Fallanza, A. Ortiz, D. Gorri, I. Ortiz, Industrial & Engineering Chemistry Research 52 (2013) pages 8843-8855.
  33. Propylene and propane solubility in ionic liquids containing a silver salt, M. Fallanza, A. Ortiz, D. Gorri, I. Ortiz, Journal of Chemical & Engineering Data 58 (2013) 2147-2153.
  34. Polymer-ionic liquid composite membranes for propane/propylene separation by facilitated transport, M. Fallanza, A. Ortiz, D. Gorri, I. Ortiz, Journal of Membrane Science 444 (2013) pages 164-172.
  35. Facilitated transport of propylene through composite polymer-ionic liquid membranes. Mass transfer analysis, R. Zarca, A. Ortiz, D. Gorri, I. Ortiz, Chemical Product and Process Modeling 11 (2016) pages 77-81.
  36. Process flowsheet analysis of pervaporation-based hybrid processes in the production of ethyl tert-butyl ether, A. Norkobilov, D. Gorri, I. Ortiz, Journal of Chemical Technology & Biotechnology 92 (2017) pages 1167-1177.
  37. Efficient treatment of perfluorohexanoic acid by nanofiltration followed by electrochemical degradation of the NF concentrate, A. Soriano, D. Gorri, A. Urtiaga, Water Research 112 (2017) pages 147-156.
  38. A practical approach to fixed-site-carrier facilitated transport modeling for the separation of propylene/propane mixtures through silver-containing polymeric membranes, R. Zarca, A. Ortiz, D. Gorri, I. Ortiz, Separation & Purification Technology 180 (2017) pages 82-89.
  39. Comparative study of conventional, reactive-distillation and pervaporation integrated hybrid process for ethyl tert-butyl ether production, A. Norkobilov, D. Gorri, I. Ortiz, Chemical Engineering & Processing: Process Intensification 122 (2017) pages 434-446
  40. Generalized predictive modeling for facilitated transport membranes accounting for fixed and mobile carriers, R. Zarca, A. Ortiz, D. Gorri, I. Ortiz, Journal of Membrane Science 524 (2017) pages 168-176.
  41. Optimized distillation coupled with state-of-the-art membranes for propylene purification, R. Zarca, A. Ortiz, D. Gorri, L. Biegler, I. Ortiz, Journal of Membrane Science 556 (2018) 321-328.
  42. A perspective of solutions for membrane instabilities in olefin/paraffin separations: A review, A.C. Campos, R.A. dos Reis, A. Ortiz, D. Gorri, I. Ortiz, Industrial & Engineering Chemistry Research 57 (2018) pages 10071-10085.
  43. Membrane preconcentration as an efficient tool to reduce the energy consumption of perfluorohexanoic acid electrochemical treatment, A. Soriano, D. Gorri, A. Urtiaga, Separation & Purification Technology 208 (2019) pages 160-168.
  44. Comprehensive study on PVDF-HFP/BMImBF4/AgBF4 membranes for propylene purification, R. Zarca, A.C. Campos, A. Ortiz, D. Gorri, I. Ortiz, Journal of Membrane Science 572 (2019) pages 255-261.
  45. Selection of high flux membrane for the effective removal of short-chain perfluorocarboxylic acids, A. Soriano, D. Gorri, A. Urtiaga, Industrial & Engineering Chemistry Research 58 (2019) pages 3329-3338.
  46. Optimization of multistage olefin/paraffin membrane separation processes through rigorous modeling, R. Zarca, A. Ortiz, D. Gorri, L. Biegler, I. Ortiz, AIChE Journal 65 (2019) e16588.
  47. An optimization model for the treatment of perfluorocarboxylic acids considering membrane preconcentration and BDD electrooxidation, A. Soriano, D. Gorri, L. Biegler, A. Urtiaga, Water Research 164 (2019) Article 114954.
  48. PSA purification of waste hydrogen from ammonia plants to fuel cell grade, M. Yáñez, F. Relvas, A. Ortiz, D. Gorri, A. Mendes, I. Ortiz, Separation & Purification Technology 240 (2020) Article 116334.
  49. Comparative performance of coke oven gas, hydrogen and methane in a spark ignition engine, R. Ortiz-Imedio, A. Ortiz, J.C. Urroz, P.M. Diéguez, D. Gorri, L.M. Gandía, I. Ortiz, International Journal of Hydrogen Energy 46 (2021) 17572-17586.
  50. Comparative performance of commercial polymeric membranes in the recovery of industrial hydrogen waste gas streams, M. Yáñez, A. Ortiz, D. Gorri, I. Ortiz, International Journal of Hydrogen Energy 46 (2021) 17507-17521.
  51. Polymer inclusion membranes containing ionic liquids for the recovery of n-butanol from ABE solutions by pervaporation, C. Arregoitia-Sarabia, D. González-Revuelta, M. Fallanza, D. Gorri, I. Ortiz, Separation & Purification Technology 248 (2020) Article 117101.  
  52. Hydrogen recovery from waste gas streams to feed (high-temperature PEM) fuel cells: Environmental performance under a life-cycle thinking approach, R. Abejón, A. Fernández-Ríos, A. Domínguez-Ramos, J. Laso, I. Ruiz-Salmón, M. Yáñez, A. Ortiz, D. Gorri, N. Donzel, D. Jones, A. Irabien, I. Ortiz, R. Aldaco, M. Margallo, Applied Sciences 10 (2020) Article 7461
  53. CO2/H2 separation through poly(ionic liquid)-ionic liquid membranes: The effect of multicomponent gas mixtures, temperature and gas feed pressure, A. Gouveia, M. Yáñez, V. Alves, J. Palomar, C. Moya, D. Gorri, L. Tomé, I. Marrucho, Separation & Purification Technology 259 (2021) Article 118113.
  54. Exploring the potential application of Matrimid® and ZIFs-based membranes for hydrogen recovery: a review, P. Fernández-Castro, A. Ortiz, D. Gorri, Polymers 13 (2021) Article 1292
  55. Polyether-block-amide thin-film composite hollow fiber membranes for the recovery of butanol from ABE process by pervaporation, C. Arregoitia-Sarabia, D. González-Revuelta, M. Fallanza, A. Ortiz, D. Gorri, Separation & Purification Technology (2021) Article 119758.
  56. Hydrogen recovery from coke oven gas. Comparative analysis of technical alternatives, G. Moral, R. Ortiz-Imedio, A. Ortiz, D. Gorri, I. Ortiz, Industrial & Engineering Chemistry Research 61 (2022) pages 6106-6124.
  57. PEBA/PDMS composite multilayer hollow fiber membranes for the selective separation of butanol by pervaporation, C. Arregoitia-Sarabia, D. González-Revuelta, M. Fallanza, A. Ortiz, D. Gorri, Membranes 12 (2022) Article 1007.
  58. Hydrogen recovery from industrial waste streams using Matrimid®/ZIF mixed matrix membranes, G. Moral, A. Ortiz, D. Gorri, I. Ortiz, International Journal of Hydrogen Energy 51, Part D (2024) 210-224.
  59. Thin-film composite Matrimid-based hollow fiber membranes for oxygen/nitrogen separation by gas permeation, D. González-Revuelta, M. Fallanza, A. Ortiz, D. Gorri, Membranes 13 (2023) Article 218.
  60. PEBAX polymer inclusion hydrophobic deep eutectic solvent membranes for pervaporation of biobutanol: Mass transfer and COSMO-RS analysis, R. Cabezas, D. González-Revuelta, E. Zurob, F. Olea, E. Quijada-Maldonado, D. Gorri, Journal of Molecular Liquids 395 (2024) article 123909.
b) Chapters in books
  1. D. Gorri, A.M. Urtiaga, I. Ortiz, Supported liquid membranes for pervaporation processes, in: E. Drioli and L. Giorno (Eds.), Comprehensive Membrane Science and Engineering, volume 2, section 2.12, Elsevier, 2010.
  2. D. Gorri, A.M. Urtiaga, I. Ortiz, Separation of liquid mixtures by pervaporation, in M.J. San José (Ed.), Advances in Chemical Engineering, chapter 3, Transworld Research Network, 2010.
  3. D. Gorri, M. Fallanza, A. Ortiz, I. Ortiz, Supported liquid membranes for pervaporation processes, in: E. Drioli, L. Giorno, and E. Fontananova (Eds.), Comprehensive Membrane Science and Engineering, second edition, volume 2, section 2.11, pp. 332–354. Oxford: Elsevier, 2017.
  4. M. Fallanza, A. Ortiz, D. Gorri, I. Ortiz, Hollow fiber membrane contactors in facilitated transport-based separations- Fundamentals and applications, in: A.K. Pabby, S.R. Wickramasinghe, K. Sirkar and A. Sastre (Eds.), Hollow Fiber Membrane Contactors, chapter 16, pp. 243-252, CRC Press / Taylor and Francis, 2020. 
  5. V. Maestre, L. Gómez-Coma, A. Ortiz, D. Gorri, The keys to achieving clean, safe, and sustainable energy for the European Union in the 21st century, in: M.F. San Román and A. Domínguez-Ramos (Eds.), Ingeniería Química y el Pacto Verde Europeo, chapter 3.1, pp. 117-129, Universidad de Cantabria, 2024.
c) Proceedings (as Editor)
  1. Libro de Resúmenes de la III Reunión Nacional de Dioxinas, Furanos y Compuestos Orgánicos Persistentes Relacionados. Daniel Gorri y Sonia Gómez (Eds.). Santander 2011. ISBN: 978-84-86116-35-4.
  2. Book of Abstracts of the IX Ibero-American Congress on Membrane Science and Technology, CITEM 2014. Alfredo Ortiz and Daniel Gorri (Eds.). Santander 2014. ISBN: 978-84-697-0397-7.


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