How reliable are Hanle measurements in metals in a three-terminal geometry?
Oihana Txoperena, Marco Gobbi, Amilcar Bedoya-Pinto, Federico Golmar, Xiangnan Sun et al. Citation: Appl. Phys. Lett. 102, 192406 (2013); doi: 10.1063/1.4806987 View online: http://dx.doi.org/10.1063/1.4806987 View Table of Contents: http://apl.aip.org/resource/1/APPLAB/v102/i19 Published by the American Institute of Physics.
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APPLIED PHYSICS LETTERS 102, 192406 (2013)
How reliable are Hanle measurements in metals in a three-terminal geometry?
Oihana Txoperena,1 Marco Gobbi,1 Amilcar Bedoya-Pinto,1 Federico Golmar,1,2 Xiangnan Sun,1 Luis E. Hueso,1,3 and Fe` lix Casanova1,3,a)
1CIC nanoGUNE, 20018 Donostia-San Sebastian, Basque Country, Spain 2I.N.T.I.-CONICET, Av. Gral. Paz 5445, Ed. 42, B1650JKA, San Martın, Bs As, Argentina 3IKERBASQUE, Basque Foundation for Science, 48011 Bilbao, Basque Country, Spain
(Received 26 February 2013; accepted 12 April 2013; published online 15 May 2013)
We test the validity of Hanle measurements in three-terminal devices by using aluminum (Al) and gold (Au). The obtained Hanle and inverted Hanle-like curves show an anomalous behavior. First, we measure Hanle signals 8 orders of magnitude larger than those predicted by standard theory. Second, the temperature and voltage dependences of the signal do not match with the tunneling spin polarization of the ferromagnetic contact. Finally, the spin relaxation times obtained with this method are independent of the choice of the metallic channel. These results are not compatible with spin accumulation in the metal. Furthermore, a scaling of the Hanle signal with the interface resistance of the devices suggests that the measured signal is originated in the tunnel junction. VC 2013 AIP Publishing LLC. [http://dx.doi.org/10.1063/1.4806987]
Spintronics is a rapidly growing research area that aims to use and manipulate not only the charge, but also the spin of the electron.1 A spintronic device capable of creating, transporting, manipulating, and detecting spins is a longsought goal. There is special interest in purely electrical spin injection and detection devices with long, active semiconductor channels, to integrate the spin functionality into conventional electronics. A simple device to study spin injection and transport in semiconductors uses a three-terminal (3 T) geometry, in which spin accumulation is induced and probed by a single magnetic tunnel contact.2,3 The detection is possible because a transverse magnetic field reduces the spin accumulation due to dephasing during the precession, the socalled Hanle effect.3,4 Since the 3 T geometry does not require submicron-sized fabrication processes, this type of devices has become very popular.2,3,5–16
However, many of the results associated to this method are still controversial. For example, large disagreements between the theoretically predicted and experimentally measured spin accumulation have been found.5 Experimental values well above the theoretical ones were first reported in Fe/ Al2O3/GaAs structures.6 Since then, similar results have been observed in various semiconductors.3,5,7–11 Moreover, some other reported features such as an anomalous bias dependence of the Hanle signal7,8,12,13 or the unclear origin of the inverted Hanle effect,11,14 put the 3 T measurements strongly into question.
In order to gain insight about the reliability of this method, we have applied it to metals with well-known spin transport properties such as aluminum (Al)4,17–21 and gold (Au).21–24 In this letter, we report that measurements done with a 3 T geometry lead to Hanle- and inverted Hanle-like features which are not compatible with spin accumulation in the studied metals. In addition, the measured signals scale with the interface resistance of the tunnel barrier of the
a)Electronic mail: f.casanova@nanogune.eu
devices, suggesting that the origin of these anomalous sig-
nals might arise from the tunnel barrier itself.
We produced devices with different non-magnetic metals: samples 1–3 with the structure Al/AlOx/Py, where the Al (Py) thickness is 15 nm (10 nm), and samples 4–6 with the
ferromagnetic metal at the bottom Py/AlOx/Au, with 10 nm of Py and 12 nm of Au. The devices were fabricated in a UHV e-beam evaporation chamber (base pressure <1 Â 10À9 millibars), using an integrated shadow masking system. The device geometry is sketched in Fig. 1(a). We used two differ-
ent strategies for the tunnel barrier fabrication: 2 min of O2 plasma exposure at 30 W and 10À1 millibars to oxidize the Al in a single run (sample 1); and a two-step (three-step) deposition of a 6 A˚ Al layer with subsequent oxidation of 20 min at 10À1 millibars of O2 pressure without plasma for samples 2–4 (samples 5 and 6). The contact area ranged between 250 Â 250 lm2 and 250 Â 500 lm2. Electrical measurements were performed by a dc method using a dc current source and a nanovoltmeter,17 while the temperature and field con-
trol is done in a commercial Quantum Design PPMS cryo-
stat. Positive sign of the current corresponds to the extraction of electrons from Al, whereas negative current means injec-
tion into Al.
First, we characterize the tunnel junctions obtained by different fabrication processes. In Fig. 1(b), we show the
current-voltage data of the tunnel junctions of Al samples
(samples 1 and 2) measured at 10 K. The measured data are fitted following the standard Simmons model for tunneling.25
From the fittings (red curves in Fig. 1(b)), we obtain both the height of the tunnel barriers and their thickness: / ¼ 2.8 V and d ¼ 1.5 nm for sample 1, and / ¼ 0.8 V and d ¼ 2.7 nm in the case of sample 2. The difference in the barrier parame-
ters is due to the different fabrication strategy of the junctions, as expected.26,27 Samples 3–6 show barrier parameters
similar to sample 2 (not shown). Fig. 1(c) shows the resist-
ance of the tunnel junction (Rint) measured at zero bias and multiplied by its total area (A) as a function of temperature
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Appl. Phys. Lett. 102, 192406 (2013)
FIG. 2. (a) Hanle and inverted Hanle-like curves (solid and open circles, respectively) for sample 1, measured at 10 K and À100 lA. Red solid line is the Lorentzian fit of the data to Eq. (1). Hanle (DRHANLE), inverted Hanle (DRINV) and total Hanle (DRTOT) signals are defined. (b) Same as (a) for sample 2, measured at 10 K and À5 lA. The device scheme is shown as an inset.
FIG. 1. (a) Scheme and dimensions of the device used for the Hanle measurements. The electrical configuration and the magnetic field direction for both Hanle (B?) and inverted Hanle (B||) effect are shown. The magnetization vector of Py strip (M), parallel to its easy axis, is also shown. (b) I-V data for sample 1 (open circles) and sample 2 (solid triangles), measured at 10 K. Red solid lines are best fits to the standard Simmons model. (c) Zero bias resistance of the tunnel junction, multiplied by its area A ¼ wFwN, as a function of temperature for sample 1 (open circles) and sample 2 (solid triangles).
for samples 1 and 2. In both cases, we observe a weak decrease with increasing temperature, as expected from a tunnel junction with no pinholes.27 The values of resistivity of the metal stripes at 10 K, measured with four probes, are 11.3 lXÁcm (sample 1, Al), 20.2 lXÁcm (sample 2, Al), and 3.5 lXÁcm (sample 5, Au).
With the measurement configuration shown in Fig. 1(a), we should observe the Hanle effect when a transverse magnetic field (B?) is applied. The spins, accumulated at the interface due to electrical injection from the Py contact into the metal, start to precess around the transverse magnetic field. Due to the dephasing during this precession, the spin accumulation is gradually reduced with an approximate Lorentzian shape.3,4 The extra voltage at the interface associated to the spin accumulation (spin voltage) can be written as
DVðB?Þ
¼
1
DVHANLE þ ðxLsSFÞ2
:
(1)
DVHANLE is the value of spin voltage in the absence of B?, sSF the spin relaxation time, and xL ¼ glBB?=h is the Larmor frequency, where g is the Lande g-factor, lB is the Bohr magneton, and h is the reduced Planck’s constant.
Commonly, the spin voltage is normalized to the injected current and, thus, DRHANLE ¼ DVHANLE=I. In Fig. 2 (solid symbols), we show two examples of a Hanle-like curve
measured at 10 K. Fig. 2(a) corresponds to sample 1 (measurements done at I ¼ À100 lA), whereas Fig. 2(b) shows the same experiment on sample 2 (I ¼ À5 lA). We should also observe a change in the measured voltage if we apply an inplane magnetic field (B||).11 It has been reported that, due to the roughness of the interface, local magnetic fields appear
on the non-magnetic material and make the injected spins
precess even in the absence of B?. Therefore, the precession is suppressed by applying B|| and the spin accumulation
increases until it saturates for large enough fields.11 This is
the so-called inverted Hanle effect, with associated signal
DRINV. The data measured at 10 K on sample 1 (performed at I ¼ À100 lA) and sample 2 (I ¼ À5 lA) are represented by
the open symbols in Figs. 2(a) and 2(b), respectively.
According to Ref. 11, the total spin accumulation is propor-
tional to the difference between the saturation value in the
inverted Hanle effect curve and the minimum value of the
Hanle effect curve. We call this difference the total Hanle
signal, DRTOT ¼ DRHANLE þ DRINV. At 10 K and previously described biases, DRHANLE values are 26% and 21% of DRTOT for samples 1 and 2, respectively. These percentages
are in agreement with those reported in Ref. 11. Fig. 2 shows
that very similar results are obtained for both samples, sug-
gesting that properties of the tunnel oxide barrier are not
relevant.
The standard theory of spin injection and accumulation in the diffusive regime28,29 states that the total spin signal associ-
ated to spin accumulation at the interface is given by
DRTOT ¼ c2 RN, in the limit Rint ) RN ) RF, which is our
case. c is the tunneling spin polarization and RNðFÞ ¼ qNðFÞ k2NðFÞ=ðVNS ðFÞð1 À P2ÞÞ is the spin resistance of the non-
magnetic (ferromagnetic) side of the interface, where qNðFÞ
are the resistivities, kNðFÞ the spin diffusion lengths, effective volumes of spin relaxation,30 and P the
VNS ðFÞ the bulk spin
polarization (P ¼ 0 for the non-magnetic material). Assuming
that the spin injection occurs homogeneously along all the
contact area, and since for the device sketched in Fig. 1(a)
wF; wN ) kN ) d is satisfied, then VNS ¼ wF Á wN Á d. Therefore, the total spin signal can be expressed as
DRTOT
¼
c2 qN k2N wF wN d
:
(2)
Taking into account the kN values obtained from the fitting to Eq. (1) (see below) and that typical c values for Py/ Al2O3 interfaces are 0.02-0.25,18,19 the total spin signal should be of the order of 10À8 X, whereas the measured val-
ues are at least 8 orders of magnitude higher (see Fig. 2).
Discrepancies between theoretical and experimental val-
ues of spin signal have previously been observed and discussed for semiconductors.3,5–11 The small theoretical spin
signal could be caused by the decrease of sSF due to the broadening of the Hanle curve,3,11 although, in our case, this
effect is by far not enough to explain the discrepancy. The
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192406-3 Txoperena et al.
Appl. Phys. Lett. 102, 192406 (2013)
role of localized states near the tunnel junction/semiconductor interface has also been deeply debated lately.3,5–11 In our
samples, since Al is a conductor, such states could only be
created within the oxide tunnel junction due to fabrication
conditions. However, evidences of the existence of localized states, such as an strong temperature dependence of Rint Á A, or a barrier height / larger than expected are not found,31
neither in sample 1, with the tunnel barrier grown by plasma,
nor in sample 2, grown by natural oxidation. Finally, Dash et al.3 analyze the possibility of having lateral inhomogene-
ities at the tunnel junction. In this case, electrons mostly tun-
nel through the thinnest regions of the junction, so-called hot
spots. This scenario is probable in our tunnel barriers due to the inherent roughness of the AlOx surface (r.m.s. ¼ 0.7 nm for sample 1 and 0.4 nm for sample 2). In the presence of hot
spots, the effective volume of spin accumulation would be
reduced, leading to an enhancement of the theoretical spin signal. We can recalculate VNS by assuming the existence of N hot spots on the tunnel barrier. If the size of these spots is
smaller than kN, and the distance between them is longer than 2kN, then DRTOT ¼ c2 qN=Npd. In the limiting unrealistic case with N ¼ 1, which gives the smallest effective volume, we find that DRTOT % 10À2 X, and the theoretical Hanle signal is still two orders of magnitude lower than the
experimental one. Therefore, the enormous difference
between standard theory and experiments cannot be
explained by the existence of hot spots.
Next, we show that the temperature and bias dependen-
cies of the total Hanle signal cannot be explained on the
basis of Eq. (2). Fig. 3(a) shows DRTOT as a function of temperature both for samples 1 and 2. Since the spin diffusion length is inversely proportional to the resistivity,21 then DRTOT / c2qÀN1, where c can be expressed as32 c ¼ c0ð1 À aT3=2Þ, being a a constant that depends on the ferromagnetic material. Using this expression for c and the experimental values for qNÀ1, we fitted DRTOTðTÞ to extract a for samples 1 and 2 (Fig. 3(a)). For sample 1, we obtain a ¼ ð8:560:3Þ Á 10À5 KÀ3=2, which could be in agreement with literature values for Py.32 However, for sample 2, we obtain a ¼ ð5063Þ Á 10À5 KÀ3=2, in disagreement with a tun-
neling spin injection from Py. Fig. 3(b) shows the voltage-
dependent measurements of DRTOT at 10 K. For both samples 1 and 2, we observe that the signal becomes undetectable at low bias voltage (jVj 0:5 V in sample 1 and jVj 0:025 V in sample 2). This gap in DRTOTðVÞ at low bias cannot be explained by the standard theory of spin injection. Indeed,
the tunneling spin polarization c is the only bias-dependent parameter in Eq. (2), and it is largest at low bias.20,33
Concerning the spin relaxation time, the obtained Lorentzian curves have been fitted to Eq. (1) to extract the value for Al: in the case of sample 1, we obtain sSF ¼ ð80 6 2Þ ps at 10 K and ð73 6 9Þ ps at 300 K. For sample 2, the Lorentzian curve vanishes above 100 K, obtaining sSF ¼ ð82 6 3Þ ps at 10 K and ð43 6 13Þ ps at 100 K. These values are the same for all biases (including injection into Al and extraction from Al). From sSFp, sffiffipffiffiiffinffiffiffiffiffidiffusion length values kAl can be calculated as kAl ¼ DsSF, where D is the diffusion coefficient. The obtained values in sample 1 are kAl ¼ ð439 6 5Þ nm at 10 K and ð370 6 20Þ nm at 300 K, whereas in sample 2 we obtain kAl ¼ ð325 6 6Þ nm at 10 K and ð232 6 35Þ nm at 100 K. Therefore, while there is no agreement neither with the amplitude nor with temperature dependence and bias dependence of the accumulation, the spin diffusion length values obtained in the two samples seem to be in agreement with literature.4,17–21
In order to clarify this controversy, similar measurements are performed in Au, another metal whose spin transport properties are also well-known21–24 but are very different to the ones in Al. Fig. 4 shows the Hanle and inverted Hanle-like curves measured at 10 K for I ¼ À50 lA in sample 5. The spin relaxation time value extracted from the fitting of the Lorentzian curve (red solid line in Fig. 4) is (144 6 5) ps, which is two orders of magnitude higher than the expected values for Au (sSF $ 1 ps).21–24 It is worth noting that the spin relaxation time values obtained for both Al and Au are comparable to those reported in many threeterminal devices in semiconductors.14,15 Moreover, total Hanle amplitudes above the theoretically expected values (see Fig. 4) and anomalous voltage-dependence of signal amplitude (not shown) have also been measured in this sample. Although the spin relaxation times obtained for Al (samples 1 and 2) are reasonable,4,17–21 similarities between the results reported in Al and Au 3 T devices (comparable spin relaxation time, amplitude of signals above the expected values, and anomalous bias dependence of the total Hanle signal) evidence that the measured Hanle and inverted Hanle-like curves are not originated by spin accumulation in the metal.
Fig. 5 shows DRTOT multiplied by the total area of the tunnel barrier as a function of the RA product of the tunnel
FIG. 3. (a) Total Hanle signal as a function of temperature, measured at À100 lA for sample 1 (open circles) and at À5 lA for sample 2 (solid triangles). Red solid lines are fits of the data to Eq. (2). (b) Total Hanle signal as a function of the applied bias at 10 K, for sample 1 (open circles) and sample 2 (solid triangles).
FIG. 4. Hanle and inverted Hanle-like curves (solid and open circles, respectively) measured in sample 5 at 10 K and À50 lA. Red solid line is the Lorentzian fit of the data to Eq. (1). The device scheme is shown as an inset.
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192406-4 Txoperena et al.
Appl. Phys. Lett. 102, 192406 (2013)
junction (Rint Á A) of all 3 T devices used in this work, which employ different metals and tunnel barriers obtained through different fabrication processes. A clear scaling between DRTOT Á A and Rint Á A, with a power law exponent of 0.83, is observed in our Py/AlOx/metal devices with different RA products. This result, which spans over 2 orders of magnitude in RA product, is not predicted by the standard theory in the condition Rint ) RN ) RF.28,29 The scaling suggests again that the Hanle and inverted Hanle-like curves do not arise from the modulation of the spin accumulation in the metal by an external magnetic field, but from the tunnel junction itself. Recent reports on 3 T measurements in Si- and Ge-based devices have shown similar disagreements. Aoki et al.14 report a Lorentzian curve in both Hanle and inverted Hanle configurations, with a corresponding spin relaxation time of $50 ps, which cannot be associated to spin accumulation in Si when compared to non-local four-terminal measurements. Uemura et al.15 and Sharma et al.34 report a tunnel barrier thickness dependence of Hanle signals, observing a scaling of DRTOT Á A with the RA product of the junction as well. It is worth noting that the spin relaxation time obtained in Ref. 15 for n-Si is 150 ps, very close to our values both for Al and Au.
In conclusion, we have tested the reliability of threeterminal Hanle measurements in metals such as Al and Au, with well-known and different spin transport properties. Our results indicate that the obtained Hanle and inverted Hanlelike curves are not related to spin accumulation in the metal channel. First, and most important, the spin relaxation times obtained for both metals are comparable, even if much shorter values are expected for Au. Furthermore, these values are also comparable to those reported in other systems such as semiconductors using the same configuration.14,15 Second, the total Hanle signal is several orders of magnitude higher than the value predicted from the standard theory. Such a difference cannot be explained by any of the sources previously discussed in literature for semiconductors.3,5–11 Third, the temperature and voltage dependences of the signal are not in agreement with the tunneling spin polarization of the used ferromagnetic contact. Last, we show that the total Hanle signal is proportional to the interface resistance of the tunnel barrier, a dependence which cannot be explained by models proposed so far and which suggests that the observed
FIG. 5. DRTOT ÁA as a function of the RA product of the tunnel junction, for different samples measured at 10 K and their optimum bias conditions. Solid and open symbols are for Al and Au samples, respectively. Red line is the logarithmic fit to the data.
effect originates at the tunnel barrier. Although there is no
evidence of localized states inside the tunnel barrier from
our transport measurements, we cannot completely rule out
their presence and their relation to the signal. Further experi-
ments would be necessary to understand the origin of the
observed phenomena.
Finally, we would like to emphasize that great care
should be taken (e.g., use of control samples) when meas-
uring the Hanle effect using three-terminal geometries with
highly resistive tunnel barriers to extract spin injection and
transport properties from any type of materials, including
metals and semiconductors.
We would like to acknowledge Professor Casey W.
Miller for fruitful discussions. This work was supported by
the European Union 7th Framework Programme (NMP3-SL-
2011-263104-HINTS, PIRG06-GA-2009-256470 and the
European Research Council Grant 257654-SPINTROS), by
the Spanish Ministry of Science and Education under Project
No. MAT2009-08494 and by the Basque Government under
Project No. PI2011-1.
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