{"id":37592,"date":"2020-05-20T03:28:44","date_gmt":"2020-05-20T01:28:44","guid":{"rendered":"\/gruppo5\/?page_id=37592"},"modified":"2023-03-02T16:33:33","modified_gmt":"2023-03-02T15:33:33","slug":"nanotechnologies","status":"publish","type":"page","link":"\/gruppo5\/en\/nanotechnologies\/","title":{"rendered":"Nanotechnologies"},"content":{"rendered":"<h1>NANOTECHNOLOGIES<\/h1>\n\n\n<p><span style=\"font-family: Open Sans;\">Coordinator: &nbsp; <br>\n<p style=\"color: #007bb3; font-family: Open Sans;\"><strong><span class=\"collapseomatic noarrow\" id=\"Fabrizio_Odorici\"  tabindex=\"0\" alt=\"Information on Fabrizio Odorici\" title=\"Information on Fabrizio Odorici\"    >+ Fabrizio Odorici<\/span><span id='swap-Fabrizio_Odorici'  class='colomat-swap' style='display:none;'>- Fabrizio Odorici<\/span><div id=\"target-Fabrizio_Odorici\" class=\"collapseomatic_content \"><\/strong> E-Mail: <a href=\"mailto:fabrizio.odorici_NOSPAM@bo.infn.it\">fabrizio.odorici@bo.infn.it<\/a><br>Lab: +39-051-2091015; Mobile: 340 2806408<br>Office: Irnerio<\/div><\/br>\n\n\n\n<p><span style=\"font-family: Open Sans; font-size: 16px;\"><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">In 2001 the Bologna Section was the initiator, within INFN, of research and development in the field of nanotechnologies.<\/span> <span title=\"\">The aim is to exploit the properties of nanostructured materials for applications of specific interest for the research of the Institute as well as of potential industrial interest.<\/span> <span title=\"\">In fact, nanotechnologies allow the synthesis of structures on a nanometric scale or, more precisely, at sub-micrometric scales, typically less than 100 nm.<\/span> <span title=\"\">These scales of magnitude anticipate the frontier of microelectronics and allow us to discover and exploit new properties of matter.<\/span><\/span> <\/span><\/p>\n<p><span style=\"font-family: Open Sans; font-size: 16px;\"><div id=\"metaslider-id-37535\" style=\"max-width: 350px; margin: 0 auto;\" class=\"ml-slider-3-107-0 metaslider metaslider-nivo metaslider-37535 ml-slider has-dots-nav ms-theme-nivo-bar\" role=\"region\" aria-label=\"Nanotech\" data-height=\"350\" data-width=\"350\">\n    <div id=\"metaslider_container_37535\">\n        <div class='slider-wrapper theme-default'><div class='ribbon'><\/div><div id='metaslider_37535' class='nivoSlider'><img loading=\"lazy\" decoding=\"async\" src=\"\/gruppo5\/wp-content\/uploads\/sites\/21\/2020\/05\/Allumina-topview200-ref2-350x350.jpg\" height=\"350\" width=\"350\" data-caption=\"SEM top view of nanopores in an alumina sample. R. Angelucci et al. \/ Nuclear Physics B (Proc. Suppl.) 150 (2006) 140&ndash;143\" title=\"Allumina-topview200-ref2\" alt=\"\" class=\"slider-37535 slide-37556 msDefaultImage\" \/><img loading=\"lazy\" decoding=\"async\" src=\"\/gruppo5\/wp-content\/uploads\/sites\/21\/2020\/05\/allumina-sideview-ref1-350x350.png\" height=\"350\" width=\"350\" data-caption=\"SEM side view of an alumina sample. R. Angelucci et al. \/Nuclear Physics B (Proc. Suppl.) 125 (2003) 164-168\" title=\"allumina-sideview-ref1\" alt=\"\" class=\"slider-37535 slide-37584 msDefaultImage\" \/><img loading=\"lazy\" decoding=\"async\" src=\"\/gruppo5\/wp-content\/uploads\/sites\/21\/2020\/05\/NWs-Co2-ref2-350x350.png\" height=\"350\" width=\"350\" data-caption=\"SEM side view of Co nanowires grown on the bottom side of alumina pores. R. Angelucci et al. \/ Nuclear Physics B (Proc. Suppl.) 150 (2006) 140&ndash;143\" title=\"NWs-Co2-ref2\" alt=\"\" class=\"slider-37535 slide-37551 msDefaultImage\" \/><img loading=\"lazy\" decoding=\"async\" src=\"\/gruppo5\/wp-content\/uploads\/sites\/21\/2020\/05\/CNT-TEM-ref2-350x350.jpg\" height=\"350\" width=\"350\" data-caption=\"TEM picture of a single Multi Wall\nCarbon Nanotube. R. Angelucci et al. \/ Nuclear Physics B (Proc. Suppl.) 150 (2006) 140&ndash;143\" title=\"CNT-TEM-ref2\" alt=\"\" class=\"slider-37535 slide-37550 msDefaultImage\" \/><img loading=\"lazy\" decoding=\"async\" src=\"\/gruppo5\/wp-content\/uploads\/sites\/21\/2020\/05\/Active-layer-detector-ref2-e1589903074951-350x350.png\" height=\"350\" width=\"350\" data-caption=\"Possible geometry of a nanochannel active\nlayer detector. R. Angelucci et al. \/ Nuclear Physics B (Proc. Suppl.) 150 (2006) 140&ndash;143\" title=\"Active-layer-detector-ref2\" alt=\"\" class=\"slider-37535 slide-37548 msDefaultImage\" \/><img loading=\"lazy\" decoding=\"async\" src=\"\/gruppo5\/wp-content\/uploads\/sites\/21\/2020\/05\/CNT-AA0-2-ref7-350x350.jpg\" height=\"350\" width=\"350\" data-caption=\"SEM side view of a carbon nanotube array grown within an alumina template. R. Angelucci et al. \/ P hys. Status Solidi C, 1&ndash;6 (2009)\" title=\"CNT-AA0-2-ref7\" alt=\"\" class=\"slider-37535 slide-37552 msDefaultImage\" \/><img loading=\"lazy\" decoding=\"async\" src=\"\/gruppo5\/wp-content\/uploads\/sites\/21\/2020\/05\/CNT-AA0-ref7-350x350.jpg\" height=\"350\" width=\"350\" data-caption=\"SEM plan view of CNTs grown within alumina nanopores (after annealing in O2 and partial etching of the template). R. Angelucci et al. \/ Phys. Status Solidi C, 1&ndash;6 (2009)\" title=\"CNT-AA0-ref7\" alt=\"\" class=\"slider-37535 slide-37553 msDefaultImage\" \/><img loading=\"lazy\" decoding=\"async\" src=\"\/gruppo5\/wp-content\/uploads\/sites\/21\/2020\/05\/CNT-egun-ref12-350x350.jpg\" height=\"350\" width=\"350\" data-caption=\"Carbon nanotube based electron guns, mounted over the RF copper waveguide in the CAESAR ion source at LNS. D. Mascali et al. \/ Plasma Sources Sci. Technol. 22 (2013) 065006\" title=\"CNT-egun-ref12\" alt=\"\" class=\"slider-37535 slide-37554 msDefaultImage\" \/><img loading=\"lazy\" decoding=\"async\" src=\"\/gruppo5\/wp-content\/uploads\/sites\/21\/2020\/05\/CNT-simulation1-ref7-350x350.png\" height=\"350\" width=\"350\" data-caption=\"Simulations of the z-component electric field for two rings of carbon nanotubes\naround a central one. R. Angeluccci et al. \/ Phys. Status Solidi C, 1&ndash;6 (2009)\" title=\"CNT-simulation1-ref7\" alt=\"\" class=\"slider-37535 slide-37555 msDefaultImage\" \/><\/div><\/div>\n        \n    <\/div>\n<\/div><\/span><\/p>\n<p>&nbsp;<\/p>\n<p style=\"text-align: justify;\"><span style=\"font-family: Open Sans; font-size: 16px;\">The main research activities are:<\/span><\/p>\n<ul>\n<li><span style=\"font-size: 16px; font-family: Open Sans;\"><strong>Synthesys of nanoporous alumina<\/strong>. \n<span class=\"collapseomatic noarrow\" id=\"Synthesys_of_nanoporous_alumina\"  tabindex=\"0\" alt=\"Information about Synthesys of nanoporous alumina\" title=\"Information about Synthesys of nanoporous alumina\"    ><strong>+ Show more<\/strong><\/span><span id='swap-Synthesys_of_nanoporous_alumina'  class='colomat-swap' style='display:none;'><strong>- Show less<\/strong><\/span><div id=\"target-Synthesys_of_nanoporous_alumina\" class=\"collapseomatic_content \">\n<span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">By electrochemical anodizing of aluminum it is possible to create a superficial oxide layer, with a porous &#8220;honeycomb&#8221; structure.<\/span> <span class=\"\" title=\"\">This layer can have a thickness of between a few hundred nm, up to tens or hundreds of microns.<\/span> <span class=\"\" title=\"\">The honeycomb structure has a variable pitch from 50 to 500 nm, which depends on the anodizing conditions, while the pore diameter is approximately equal to half the pitch.<\/span> <span class=\"\" title=\"\">With appropriate precautions, the pore matrix can reach a very high regularity.<\/span> <span class=\"\" title=\"\">In this way, arrays of nanopores with a high degree of order are obtained, even on a millimeter scale, which can have multiple applications: for example, they can be used as photonic crystals or as templates for the synthesis of other nanostructures, such as nanoparticles, nanowires or carbon nanotubes<\/span><\/span>.<\/div><\/span><\/li>\n<li><span style=\"font-family: Open Sans; font-size: 16px;\"><strong><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">Synthesis of metal nanowires<\/span><\/span>.<\/strong>\n<span class=\"collapseomatic noarrow\" id=\"Synthesis_of_metal_nanowires\"  tabindex=\"0\" alt=\"Information about Synthesis of metal nanowires\" title=\"Information about Synthesis of metal nanowires\"    ><strong>+ Show more<\/strong><\/span><span id='swap-Synthesis_of_metal_nanowires'  class='colomat-swap' style='display:none;'><strong>- Show less<\/strong><\/span><div id=\"target-Synthesis_of_metal_nanowires\" class=\"collapseomatic_content \">\n<span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">Through electroplating processes on porous alumina matrices it is possible to create metal nanowires with particular opto-electronic properties: for electromagnetic radiation with a wavelength much larger than the diameter of the nanowire and for specific resonant frequencies (in the UV-VIS-IR range<\/span> <span title=\"\">) depending on the geometry, a high absorption and the ability to transport the perturbation along the nanowire are observed, as in a light guide.<\/span><\/span><\/div> <\/span><\/li>\n<\/ul>\n<p style=\"padding-left: 40px; \"><span style=\"font-family: Open Sans; font-size: 16px;\"><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">The use of metal nanowires has found various applications, for example<\/span><\/span>:<\/span><\/p>\n<ul>\n<li style=\"list-style-type: none;\">\n<ul>\n<li><span style=\"font-size: 16px; font-family: Open Sans;\"><span style=\"text-decoration: underline;\"><span style=\"color: #ff0000; text-decoration: underline;\"><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">hyperabsorption in laser-matter interactions for the formation of plasmas of astrophysical interest<\/span><\/span><\/span><\/span><span style=\"color: #ff0000;\"><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">.<\/span><\/span><\/span>\n<span class=\"collapseomatic noarrow\" id=\"hyperabsorption\"  tabindex=\"0\" alt=\"Information about hyperabsorption\" title=\"Information about hyperabsorption\"    ><strong>+ Show more<\/strong><\/span><span id='swap-hyperabsorption'  class='colomat-swap' style='display:none;'><strong>- Show less<\/strong><\/span><div id=\"target-hyperabsorption\" class=\"collapseomatic_content \">\n<span style=\"color: #ff0000;\"><span class=\"tlid-translation translation\" lang=\"it\"><span title=\"\"><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">The <strong>PLANETA experiment<\/strong> (2017-2019) investigated the production of plasma by laser ablation of nanostructured targets.<\/span> <span class=\"\" title=\"\">Using two Nd-YAG lasers at 1064 and 532 nm wavelength, 6 ns duration pulses are fired on targets with metal nanowires embedded in a porous alumina matrix and the resulting plasma is analyzed with different detectors.<\/span> The plasmas created in this way are interesting in terms of laser-nanostructure coupling, as they seem to lead to the production of a hot, dense and long-lasting plasma (hundreds of ns), such as to achieve adequate conditions for nuclear fusion and for studies of astrophysical interest.<\/span><\/span><\/span><\/span><\/div><\/span><\/li>\n<li><span style=\"font-size: 16px; font-family: Open Sans;\"><span class=\"tlid-translation translation\" style=\"color: #007BB3;\" lang=\"en\"><span class=\"\" title=\"\"><span style=\"text-decoration: underline;\">optimization of radiation detectors<\/span> (e.g. Silicon Drift Detectors) in quantum efficiency at specific frequencies.<\/span><\/span>\n<span class=\"collapseomatic noarrow\" id=\"optimization_of_radiation_detectors\"  tabindex=\"0\" alt=\"Information about optimization of radiation detectors\" title=\"Information about optimization of radiation detectors\"    ><strong>+ Show more<\/strong><\/span><span id='swap-optimization_of_radiation_detectors'  class='colomat-swap' style='display:none;'><strong>- Show less<\/strong><\/span><div id=\"target-optimization_of_radiation_detectors\" class=\"collapseomatic_content \">\n<span style=\"color: #007BB3;\"><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">The <strong>REDSOX2 experiment<\/strong> (2016-2018) investigated the application of nanotechnology on SDD-type devices, in order to increase the quantum efficiency of the current detector in the UV range, for example for applications in the reading of scintillation light.<\/span> <span title=\"\">In particular, the possibility of increasing quantum efficiency in the near ultraviolet range (\u223c 380 nm) was verified, by the formation of a matrix of Ag nanowires with high transmittance, which is placed on the detector entrance window, above a thin<\/span> <span title=\"\">ITO (Indium Tin Oxide) layer.<\/span> <span title=\"\">The double layer also acts as an anti-reflecting coating.<\/span> <span title=\"\">The study showed that it is possible to obtain a plasmonic absorption resonance close to 380 nm.<\/span><\/span><\/span><\/div><\/span><\/li>\n<li><span style=\"font-size: 16px; font-family: Open Sans;\"><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\"><span style=\"color: #0000ff;\"><span style=\"text-decoration: underline;\">electromagnetic radiation hyperabsorption<\/span> (e.g. the solar spectrum) <span style=\"text-decoration: underline;\">and heat transfer in industrial application<\/span>. <\/span><\/span><\/span>\n<span class=\"collapseomatic noarrow\" id=\"electromagnetic_radiation_hyperabsorption\"  tabindex=\"0\" alt=\"Information about electromagnetic radiation hyperabsorption\" title=\"Information about electromagnetic radiation hyperabsorption\"    ><strong>+ Show more<\/strong><\/span><span id='swap-electromagnetic_radiation_hyperabsorption'  class='colomat-swap' style='display:none;'><strong>- Show less<\/strong><\/span><div id=\"target-electromagnetic_radiation_hyperabsorption\" class=\"collapseomatic_content \">\n<span class=\"tlid-translation translation\" lang=\"en\"><span style=\"color: #0000ff;\"><span class=\"\" title=\"\">A possible application has been preliminary experimented (in collaboration with a company), through a surface treatment based on matrices of metal nanowires.<\/span> <span class=\"\" title=\"\">These matrices create a surface with very high absorption for the UV-VIS-IR spectrum, even in conditions of high power density and for long times.<\/span> <\/span><span class=\"\" title=\"\"><span style=\"color: #0000ff;\">In the trial application it was therefore required that the high absorbance remains constant over time in highly degrading conditions<\/span>.<\/span><\/span>\n<\/div><br><\/span><\/li>\n<\/ul>\n<\/li>\n<li><span style=\"font-size: 16px; font-family: Open Sans;\"><strong><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">Synthesis of carbon nanotubes<\/span><\/span>.<\/strong>\n<span class=\"collapseomatic noarrow\" id=\"Synthesis_of_carbon_nanotubes\"  tabindex=\"0\" alt=\"Information about Synthesis of carbon nanotubes\" title=\"Information about Synthesis of carbon nanotubes\"    ><strong>+ Show more<\/strong><\/span><span id='swap-Synthesis_of_carbon_nanotubes'  class='colomat-swap' style='display:none;'><strong>- Show less<\/strong><\/span><div id=\"target-Synthesis_of_carbon_nanotubes\" class=\"collapseomatic_content \">\n<span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">By means of Chemical Vapor Deposition (CVD) it is possible to create carbon nanotubes, with a diameter between 1 and 100 nm and length of several microns.<\/span> <span title=\"\">These nanotubes show excellent electrical properties, such as high conductivity and the ability to emit electrons by tunnel effect, under the action of an electric field.<\/span> <span title=\"\">They can be created in free form (freestanding) or confined in regular porous alumina matrices<\/span><\/span>.\n<\/div><\/span><\/li>\n<\/ul>\n<p style=\"padding-left: 40px;\"><span style=\"font-size: 16px; font-family: Open Sans;\"> <span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">The use of carbon nanotubes has found various applications, for example<\/span><\/span>:<\/span><\/p>\n<ul>\n<li style=\"list-style-type: none;\">\n<ul>\n<li><span style=\"font-size: 16px; font-family: Open Sans;\"><span style=\"text-decoration: underline;\"><span class=\"tlid-translation translation\" style=\"color: #ff0000; text-decoration: underline;\" lang=\"en\"><span class=\"\" title=\"\">electron emitters in ion sources<\/span><\/span><\/span>.\n<span class=\"collapseomatic noarrow\" id=\"electron_emitters_in_ion_sources\"  tabindex=\"0\" alt=\"Information about electron emitters in ion sources\" title=\"Information about electron emitters in ion sources\"    ><strong>+ Show more<\/strong><\/span><span id='swap-electron_emitters_in_ion_sources'  class='colomat-swap' style='display:none;'><strong>- Show less<\/strong><\/span><div id=\"target-electron_emitters_in_ion_sources\" class=\"collapseomatic_content \">\n<span style=\"color: #ff0000;\"><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">The <strong>CANTES<\/strong> (2009-2010) and <strong>ESOPO<\/strong> (2011-2013) <strong>experiments<\/strong> investigated the &#8220;auxiliary electron source&#8221; technique in ion sources of the ECRIS type (Electron Cyclotron Ion Source) and<\/span> <span title=\"\">MDIS type (Microwave Discharge Ion Source) <span class=\"\" title=\"\">by means of electron guns based on carbon nanotube cathodes<\/span>.<\/span> <span title=\"\">In these studies, the resistance of carbon nanotubes to plasma damage was exploited to verify that in a magnetic confinement ion source the injection of auxiliary electrons is able to increase the electronic density of the plasma and the charge state distribution<\/span><span title=\"\">, and to reduce the (unwanted) concentration of high energy electrons<\/span><\/span>.<\/span>\n<\/div> <br><\/span><\/li>\n<li><span style=\"font-size: 16px; font-family: Open Sans;\"><span style=\"text-decoration: underline; color: #ff00ff;\"><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">electron emitters in industrial applications<\/span><\/span>.<\/span>\n<span class=\"collapseomatic noarrow\" id=\"electron_emitters_in_industrial_applications\"  tabindex=\"0\" alt=\"Information about electron emitters in industrial applications\" title=\"Information about electron emitters in industrial applications\"    ><strong>+ Show more<\/strong><\/span><span id='swap-electron_emitters_in_industrial_applications'  class='colomat-swap' style='display:none;'><strong>- Show less<\/strong><\/span><div id=\"target-electron_emitters_in_industrial_applications\" class=\"collapseomatic_content \">\n<span style=\"color: #ff00ff;\"><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">Cold cathode samples were made (in collaboration with a company) for application in innovative X-ray tubes, exploiting the low beam divergence, the high miniaturization and the prompt emission of carbon nanotubes<\/span><\/span>.<\/span>\n<\/div><\/span><\/li>\n<li><span style=\"font-family: Open Sans; font-size: 16px;\"><span style=\"text-decoration: underline;\"><span style=\"color: #0000ff; text-decoration: underline;\"><span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">high spatial resolution radiation detectors<\/span><\/span>.<\/span><\/span>\n<span class=\"collapseomatic noarrow\" id=\"high_spatial_resolution_radiation_detectors\"  tabindex=\"0\" alt=\"Information about high spatial resolution radiation detectors\" title=\"Information about high spatial resolution radiation detectors\"    ><strong>+ Show more<\/strong><\/span><span id='swap-high_spatial_resolution_radiation_detectors'  class='colomat-swap' style='display:none;'><strong>- Show less<\/strong><\/span><div id=\"target-high_spatial_resolution_radiation_detectors\" class=\"collapseomatic_content \">\n<span class=\"tlid-translation translation\" style=\"color: #0000ff;\" lang=\"en\"><span class=\"\" title=\"\">The <strong>NANOCHANT experiment<\/strong> (2003-2005) has investigated the realization of a ionizing particle detector with high spatial resolution, through the coupling between an active layer based on pixelated silicon junctions and an ordered matrix of carbon nanotubes acting as collectors<\/span> <span title=\"\">of charge with ultra fine segmentation<\/span><\/span><span style=\"color: #0000ff;\">. <\/span>\n<\/div> <\/span><\/li>\n<\/ul>\n<\/li>\n<\/ul>\n<p><span style=\"font-family: Open Sans; font-size: 16px;\"><strong>The research group<\/strong>: <a href=\"mailto:marco.cuffiani@bo.infn.it\">Marco Cuffiani<\/a>, <a href=\"mailto:luciana.malferrari@bo.infn.it\">Luciana Malferrari<\/a>, <a href=\"mailto:alessandro.montanari@bo.infn.it\">Alessandro Montanari<\/a>, <a href=\"mailto:fabrizio.odorici@bo.infn.it\">Fabrizio Odorici<\/a>. <\/span><\/p>\n<p style=\"text-align: justify;\"><span style=\"font-size: 16px; font-family: Open Sans;\"><strong>The collaboration<\/strong>: <span class=\"tlid-translation translation\" lang=\"en\"><span class=\"\" title=\"\">research is carried out in collaboration with various institutes, including the CNR-IMM-Bologna, INFN-LNS-Catania, INFN-Trieste and IAP-Frankfurt.<\/span> <span class=\"\" title=\"\">The applications tested so far, in addition to electrochemical techniques, have integrated many skills, including: aspects of optics, electronics, radiation-matter interactions, plasma physics, simulation and construction of electrostatic systems for the generation and control of electron beams<\/span> <span title=\"\">low energy.<\/span><br><br><span title=\"\">Topics for thesis and master&#8217;s thesis are available <\/span><\/span>(info: <a href=\"mailto:fabrizio.odorici@bo.infn.it\">fabrizio. odorici@bo.infn.it<\/a>).<\/span><\/p>\n","protected":false},"excerpt":{"rendered":"<p>NANOTECHNOLOGIES Coordinator: &nbsp; In 2001 the Bologna Section was the initiator, within INFN, of research and development in the field of nanotechnologies. The aim is to exploit the properties of nanostructured materials for applications of specific interest for the research of the Institute as well as of potential industrial interest. In fact, nanotechnologies allow the [&hellip;]<\/p>\n","protected":false},"author":61,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"template-page-builder-no-sidebar.php","meta":{"_lmt_disableupdate":"no","_lmt_disable":"","footnotes":""},"class_list":["post-37592","page","type-page","status-publish","hentry"],"_links":{"self":[{"href":"\/gruppo5\/wp-json\/wp\/v2\/pages\/37592","targetHints":{"allow":["GET"]}}],"collection":[{"href":"\/gruppo5\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"\/gruppo5\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"\/gruppo5\/wp-json\/wp\/v2\/users\/61"}],"replies":[{"embeddable":true,"href":"\/gruppo5\/wp-json\/wp\/v2\/comments?post=37592"}],"version-history":[{"count":44,"href":"\/gruppo5\/wp-json\/wp\/v2\/pages\/37592\/revisions"}],"predecessor-version":[{"id":38271,"href":"\/gruppo5\/wp-json\/wp\/v2\/pages\/37592\/revisions\/38271"}],"wp:attachment":[{"href":"\/gruppo5\/wp-json\/wp\/v2\/media?parent=37592"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}