Room-temperature air-stable spin transport in bathocuproine-based spin valves

Sun, Xiangnan; Gobbi, Marco; Bedoya-Pinto, Amílcar; Txoperena, Oihana; Golmar, F.; Llopis, Roger; Chuvilin, Andrey; Casanova, Fèlix; Hueso, Luis E.

doi:10.1038/ncomms3794

Cited by 78 publications

(103 citation statements)

References 32 publications

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“…[ 5,15,16 ] However, to develop new physical properties in organic spin valves, the (spin) charge carrier transport should really occur in and be dominated by the organic semiconductor (via hopping) rather than by metallic fi laments or the injection barrier. [ 14 ] From the molecular side, an obvious choice for improving spin charge carrier injection would be a compound whose energy level responsible for electronic transport matches well the Fermi level of the ferromagnetic electrodes used.…”

Section: Doi: 101002/adma201503831mentioning

confidence: 99%

“…[ 2,21 ] Besides, F 16 CuPc is an air-stable organic semiconductor, [ 25 ] being this property crucial for any application of organic spintronic devices. [ 5,27 ] Our vertical OSV devices have a typical vertical cross-bar structure with the following layers: Co (11 nm)/AlO x (1.5 nm)/ F 16 CuPc (15-180 nm)/Ni 80 Fe 20 (NiFe, 11 nm) (see Figure 1 ). Co and NiFe electrodes act as the source and detector of the spinpolarized transport in the F 16 CuPc spacer.…”

Section: Communicationmentioning

confidence: 99%

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Active Morphology Control for Concomitant Long Distance Spin Transport and Photoresponse in a Single Organic Device

et al. 2016

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Long distance spin transport and photoresponse are demonstrated in a single F16 CuPc spin valve. By introducing a low-temperature strategy for controlling the morphology of the organic layer during the fabrication of a molecular spin valve, a large spin-diffusion length up to 180 nm is achieved at room temperature. Magnetoresistive and photoresponsive signals are simultaneously observed even in an air atmosphere.

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Section: Doi: 101002/adma201503831mentioning

confidence: 99%

Section: Communicationmentioning

confidence: 99%

Active Morphology Control for Concomitant Long Distance Spin Transport and Photoresponse in a Single Organic Device

et al. 2016

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“…3 Until now, the spin transport properties of some molecular materials have been investigated. [4][5][6][7][8][9] We have focused on pentacene molecular films prepared by thermal evaporation as one candidate material for the spin transport, in terms of the good crystallinity even in the thermally evaporated films, and the high electrical conductivity without any dopants. 10 Moreover, pentacene shows the photo-conductivity for visible light, 11 where the spin transport properties of pentacene can be controlled through visible light irradiation.…”

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confidence: 99%

Spin current relaxation time in thermally evaporated pentacene films

et al. 2017

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The spin current relaxation time (τ) in thermally evaporated pentacene films was evaluated with the spin-pump-induced spin transport properties and the charge current transport properties in pentacene films. Under an assumption of a diffusive transport of the spin current in pentacene films, the zero-field mobility and the diffusion constant of holes in pentacene films were experimentally obtained to be ~8.0× 10 -7 m 2 /Vs and ~2.0× 10 -8 m 2 /s, respectively. Using those values and the previously obtained spin diffusion length in pentacene films of 42±10 nm, the τ in pentacene films was estimated to be 150±120 ns at room temperature. This estimated τ in pentacene films is long enough for practical use as a spintronic material.

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“…For some systems, MR is observed in the tunneling regime while it is absent in the thermally activated transport regime [58], supporting the view that MR in organic spin valves may generally be associated with tunneling effects. On the other hand, other systems have been reported that do exhibit significant MR in combination with a strong temperature dependence of the conductivity [59,60]. In addition, strong isotope effects have been reported in organic spin valves based on deuterated and hydrogenated versions of the same conjugated polymer [28], supporting the idea that spin-polarized transport in the organic layer plays a dominant role.…”

Section: Organic Spin Valves With "Thick" Organic Spacersmentioning

confidence: 58%

“…This strongly limits the freedom for tuning injection barrier heights. A recent study on Co/AlOx/bathocuproine(BCP)/Ni 80 Fe 20 spin valves [59], where the properties of the AlOx barriers were varied and different barrier heights were found, suggests that this might nevertheless be of considerable importance. For a BCP thickness up to 60 nm, room-temperature MR of a few percent, in combination with a strongly temperature dependent conductivity consistent with thermally activated hopping, was observed for devices with low injection-barrier heights (determined from ln(I/V 2 )…”

Section: Organic Spin Valves With "Thick" Organic Spacersmentioning

confidence: 99%

Recent progress in organic spintronics

Jong

2016

Open Physics

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Abstract:The field of organic spintronics deals with spin dependent phenomena occurring in organic semiconductors or hybrid inorganic/organic systems that may be exploited for future electronic applications. This includes magnetic field effects on charge transport and luminescence in organic semiconductors, spin valve action in devices comprising organic spacers, and magnetic effects that are unique to hybrid interfaces between (ferromagnetic) metals and organic molecules. A brief overview of the current state of affairs in the field is presented.

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Room-temperature air-stable spin transport in bathocuproine-based spin valves

Cited by 78 publications

References 32 publications

Active Morphology Control for Concomitant Long Distance Spin Transport and Photoresponse in a Single Organic Device

Active Morphology Control for Concomitant Long Distance Spin Transport and Photoresponse in a Single Organic Device

Spin current relaxation time in thermally evaporated pentacene films

Recent progress in organic spintronics

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