{"id":122,"date":"2019-12-12T16:03:35","date_gmt":"2019-12-12T15:03:35","guid":{"rendered":"https:\/\/nanociencia.imdea.org\/sographmem\/?page_id=122"},"modified":"2020-04-24T11:24:43","modified_gmt":"2020-04-24T09:24:43","slug":"servicios","status":"publish","type":"page","link":"https:\/\/nanociencia.imdea.org\/sographmem\/servicios\/","title":{"rendered":"ABOUT"},"content":{"rendered":"\n[et_pb_section fb_built=\u00bb1″ fullwidth=\u00bbon\u00bb admin_label=\u00bbCall to Action\u00bb _builder_version=\u00bb3.22″ animation_style=\u00bbslide\u00bb animation_direction=\u00bbbottom\u00bb animation_intensity_slide=\u00bb6%\u00bb animation_starting_opacity=\u00bb100%\u00bb locked=\u00bboff\u00bb][et_pb_fullwidth_header title=\u00bbABOUT\u00bb content_max_width=\u00bb800px\u00bb _builder_version=\u00bb4.4.3″ title_level=\u00bbh2″ title_font=\u00bbLato||||||||\u00bb title_font_size=\u00bb60px\u00bb title_line_height=\u00bb1.2em\u00bb content_font=\u00bb||||||||\u00bb content_font_size=\u00bb20px\u00bb content_line_height=\u00bb1.8em\u00bb background_color=\u00bbrgba(255, 255, 255, 0)\u00bb use_background_color_gradient=\u00bbon\u00bb background_color_gradient_start=\u00bbrgba(0,0,0,0.75)\u00bb background_color_gradient_end=\u00bbrgba(0,0,0,0)\u00bb background_color_gradient_direction=\u00bb90deg\u00bb background_color_gradient_overlays_image=\u00bbon\u00bb background_image=\u00bbhttps:\/\/nanociencia.imdea.org\/sographmem\/wp-content\/uploads\/2020\/04\/IMG_1982-scaled.jpg\u00bb custom_button_one=\u00bbon\u00bb button_one_text_size=\u00bb18px\u00bb button_one_bg_color=\u00bb#02d002″ button_one_border_width=\u00bb8px\u00bb button_one_border_color=\u00bb#02d002″ button_one_border_radius=\u00bb0px\u00bb button_one_letter_spacing=\u00bb1px\u00bb button_one_font=\u00bbLato|700|||||||\u00bb button_one_use_icon=\u00bboff\u00bb custom_button_two=\u00bbon\u00bb button_two_text_size=\u00bb18px\u00bb button_two_text_color=\u00bb#353740″ button_two_bg_color=\u00bb#ffffff\u00bb button_two_border_width=\u00bb8px\u00bb button_two_border_color=\u00bb#ffffff\u00bb button_two_border_radius=\u00bb0px\u00bb button_two_letter_spacing=\u00bb1px\u00bb button_two_font=\u00bbLato|700|||||||\u00bb button_two_use_icon=\u00bboff\u00bb min_height=\u00bb234px\u00bb custom_margin=\u00bb|||\u00bb custom_padding=\u00bb8%||8%|\u00bb border_width_top=\u00bb12px\u00bb border_color_top=\u00bb#0c71c3″ border_width_bottom=\u00bb5px\u00bb border_color_bottom=\u00bb#0c71c3″ text_shadow_style=\u00bbpreset2″ button_one_letter_spacing_hover=\u00bb1px\u00bb button_two_letter_spacing_hover=\u00bb1px\u00bb button_one_text_size__hover_enabled=\u00bboff\u00bb button_two_text_size__hover_enabled=\u00bboff\u00bb button_one_text_color__hover_enabled=\u00bboff\u00bb button_two_text_color__hover_enabled=\u00bboff\u00bb button_one_border_width__hover_enabled=\u00bboff\u00bb button_two_border_width__hover_enabled=\u00bboff\u00bb button_one_border_color__hover_enabled=\u00bboff\u00bb button_two_border_color__hover_enabled=\u00bboff\u00bb button_one_border_radius__hover_enabled=\u00bboff\u00bb button_two_border_radius__hover_enabled=\u00bboff\u00bb button_one_letter_spacing__hover_enabled=\u00bbon\u00bb button_one_letter_spacing__hover=\u00bb1px\u00bb button_two_letter_spacing__hover_enabled=\u00bbon\u00bb button_two_letter_spacing__hover=\u00bb1px\u00bb button_one_bg_color__hover_enabled=\u00bboff\u00bb button_two_bg_color__hover_enabled=\u00bboff\u00bb][\/et_pb_fullwidth_header][\/et_pb_section][et_pb_section fb_built=\u00bb1″ admin_label=\u00bbEvent Section\u00bb _builder_version=\u00bb4.0.9″ custom_padding=\u00bb10px||100px||false|false\u00bb animation_style=\u00bbzoom\u00bb animation_intensity_zoom=\u00bb6%\u00bb animation_starting_opacity=\u00bb100%\u00bb][et_pb_row _builder_version=\u00bb4.4.3″ custom_padding=\u00bb68px|||||\u00bb][et_pb_column type=\u00bb4_4″ _builder_version=\u00bb4.4.3″][et_pb_text _builder_version=\u00bb4.4.3″ text_font_size=\u00bb20px\u00bb]

SOgraphMEM<\/strong> – S<\/strong>pin O<\/strong>rbit\u00a0functionalized GRAPH<\/strong>ene for resistive-magnetic MEM<\/strong>ories<\/p>[\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row _builder_version=\u00bb4.4.3″][et_pb_column type=\u00bb4_4″ _builder_version=\u00bb4.4.3″][et_pb_text _builder_version=\u00bb4.4.3″]

Funding organism:<\/strong> National research agencies, MINECO Spain, ANR France, DPG Germany, FNRS Belgium, upon recommendation\/evaluation from European Union<\/p>\n

Participating organisms:<\/strong> IMDEA Nanociencia<\/a> (Spain), CNRS-UMPHY<\/a> (France), Soleil<\/a> (France), ALBA-CELLS<\/a> (Spain), NaMLab gGmbH<\/a> <\/strong>(Germany), Peter Gr\u00fcnberg Institute (PGI) & Institute for Advanced Simulation (IAS) – Forschungszentrum J\u00fclich<\/a> (Germany), Universit\u00e9 Catholique de Louvain<\/a> (Belgium).<\/p>\n

Coordination<\/strong>: Dr. Paolo Perna<\/p>\n

Total budget<\/strong>: 1.1 M\u20ac from: 1st<\/sup> January 2020 to 31st<\/sup> December 2022<\/p>\n

 <\/p>[\/et_pb_text][\/et_pb_column][\/et_pb_row][et_pb_row column_structure=\u00bb1_5,1_5,1_5,1_5,1_5″ _builder_version=\u00bb4.4.3″][et_pb_column type=\u00bb1_5″ _builder_version=\u00bb4.4.3″][et_pb_image src=\u00bbhttps:\/\/nanociencia.imdea.org\/sographmem\/wp-content\/uploads\/2020\/04\/logo-flagera.png\u00bb _builder_version=\u00bb4.4.3″ width=\u00bb120%\u00bb][\/et_pb_image][\/et_pb_column][et_pb_column type=\u00bb1_5″ _builder_version=\u00bb4.4.3″][et_pb_image src=\u00bbhttps:\/\/nanociencia.imdea.org\/sographmem\/wp-content\/uploads\/2020\/04\/graphene_flagship_logo_blue.png\u00bb _builder_version=\u00bb4.4.3″ width=\u00bb120%\u00bb custom_margin=\u00bb14px|||14px|false|false\u00bb][\/et_pb_image][\/et_pb_column][et_pb_column type=\u00bb1_5″ _builder_version=\u00bb4.4.3″][et_pb_image src=\u00bbhttps:\/\/nanociencia.imdea.org\/sographmem\/wp-content\/uploads\/2020\/04\/aei.jpg\u00bb _builder_version=\u00bb4.4.3″ width=\u00bb110%\u00bb custom_margin=\u00bb-40px||||false|false\u00bb][\/et_pb_image][\/et_pb_column][et_pb_column type=\u00bb1_5″ _builder_version=\u00bb4.4.3″][et_pb_image src=\u00bbhttps:\/\/nanociencia.imdea.org\/sographmem\/wp-content\/uploads\/2020\/04\/miccin.png\u00bb _builder_version=\u00bb4.4.3″ width=\u00bb84%\u00bb custom_margin=\u00bb-5px||||false|false\u00bb][\/et_pb_image][\/et_pb_column][et_pb_column type=\u00bb1_5″ _builder_version=\u00bb4.4.3″][et_pb_image src=\u00bbhttps:\/\/nanociencia.imdea.org\/sographmem\/wp-content\/uploads\/2020\/04\/unnamed-1.png\u00bb _builder_version=\u00bb4.4.3″ width=\u00bb105%\u00bb custom_margin=\u00bb-7px|||-17px|false|false\u00bb][\/et_pb_image][\/et_pb_column][\/et_pb_row][et_pb_row _builder_version=\u00bb4.4.3″][et_pb_column type=\u00bb4_4″ _builder_version=\u00bb4.4.3″][et_pb_text _builder_version=\u00bb4.4.3″ text_text_color=\u00bb#0c71c3″ text_font_size=\u00bb18px\u00bb]

Summary of the proyect<\/strong><\/p>[\/et_pb_text][et_pb_text _builder_version=\u00bb4.4.3″ min_height=\u00bb91px\u00bb custom_padding=\u00bb||0px|||\u00bb]

The demand for high density, low power and fast spin logic devices requires the combination of materials that can provide suitable spin transport channels with long spin lifetime and spin propagation, as well as topologically stable spin textures that can act as fast information carriers. These prerequisites for the development of spintronic technology in next years can be fulfilled by exploiting the spin and momentum degrees of freedom of electrons (Spin-Orbitronics, SO) in specific multi-layered structures. In addition, the discovery of a strong Dzyaloshinskii\u2212Moriya Interaction (DMI) at the Graphene (Gr)\/Ferromagnetic (FM) interface is a crucial step to promote SO technology enabling the electrical control of the transport and manipulation of (topologically protected) magnetic structures.<\/p>\n

The integration of graphene as efficient spin transport channel in the technology based on chiral spin textures depends, however, on our ability to fabricate Gr-based perpendicular magnetic anisotropy (PMA) systems with tailored interfacial Spin Orbit Coupling (SOC). The partners of the consortium have already demonstrated the ability to tune the SOC by metal intercalation and the important magnetic interactions including the perpendicular anisotropy, the interlayer dipolar fields or the interfacial DMI by layer engineering, in order to control the chirality of the magnetic domain walls and skyrmions, to detect electrically nanometer spin textures, to realize graphene mediated antiferromagnetic coupling (AFC) between FMs, and finally to engineer ferroelectricity for application in various flavours of ferroelectric memories.<\/p>[\/et_pb_text][et_pb_text _builder_version=\u00bb4.4.3″ text_text_color=\u00bb#0c71c3″ text_font_size=\u00bb18px\u00bb min_height=\u00bb9px\u00bb]

Main objectives\u00a0<\/strong><\/p>[\/et_pb_text][et_pb_text _builder_version=\u00bb4.4.3″ hover_enabled=\u00bb0″]

SOgraphMEM project aims to i) functionalize the SOC induced parameters, ii) characterize, and iii) test the graphene based Spin-Orbitronic systems\/devices operating at room temperature by exploiting the advantages of combining FM ultrathin films underneath of a Gr layer, non-magnetic films of heavy metals (HM), and ferroelectric (FE) compounds (doped-HfO2, HfZrO2). We aim at exploiting the polarization of the FE in order to ultimately realize voltage-controlled resistive and magnetic switching devices. We will adopt a specific methodology to fabricate the stacks, which will have the following sequence FE \/ Gr \/ FM \/ HM onto insulating oxides. In order to stabilize the spin textures, we will also explore the use of AFC through Gr in synthetic antiferromagnetic (SAF) stack, i.e. FM2 \/ Gr \/ FM1.<\/p>\n

In view of practical applications, SOgraphMEM will open the way for the development of the next generation of spintronics devices beyond the Moore\u2019s law, exhibiting low power, high velocity and large density, as well as efficient spin injection\/detection.<\/p>[\/et_pb_text][et_pb_text _builder_version=\u00bb4.4.3″ hover_enabled=\u00bb0″ min_height=\u00bb121px\u00bb custom_padding=\u00bb0px|||||\u00bb]