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Copper zinc oxide: Investigation into a p-type mixed metal oxide system
Accepted Manuscript Copper zinc oxide: Investigation into a P-type mixed metal oxide system P.J.M. Isherwood PII:
S0042-207X(16)30626-1
DOI:
10.1016/j.vacuum.2016.09.026
Reference:
VAC 7147
To appear in:
Vacuum
Received Date: 24 June 2016 Revised Date:
1 August 2016
Accepted Date: 28 September 2016
Please cite this article as: Isherwood PJM, Copper zinc oxide: Investigation into a P-type mixed metal oxide system, Vaccum (2016), doi: 10.1016/j.vacuum.2016.09.026. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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P. J. M. Isherwood
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Copper Zinc Oxide: Investigation into a P-type Mixed Metal Oxide System
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Centre for Renewable Energy Systems Technology, Wolfson School of Mechanical Electrical and Manufacturing Engineering, Loughborough University, Loughborough, Leicestershire, LE11 3TU UK
Abstract
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In photovoltaics, ZnO is widely used both as an n-type window and buffer layer and as the basis for a range of transparent conducting oxide (TCO) top contact materials. Whilst there are reports of p-type doping, there have been no successful attempts to create a p-type ZnO-based TCO. Synthesis of an effective p-type TCO could be of significant benefit, enabling further development of technologies such as bifacial and multijunction devices. This study investigates
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the effects of combining ZnO with CuO, an intrinsically p-type narrow band
p-type alloys.
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gap metal oxide, with the aim of synthesising a range of mid to wide band gap
Alloying ZnO with CuO gave a range of p-type films with varying electrical, optical and structural characteristics. XRD patterns show that as copper
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content was increased above 24.5 % of the total metal content, crystal structure changed from a typical ZnO wurtzite structure to a CuO tenorite structure. A second change occured at 35 % copper with the emergence of two further tenorite
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peaks. These structural changes correlate to significant local increases in band gap, visible and infrared transmission, and resistivity. These dramatic changes correspond to relatively minor compositional variations. Through careful control of the alloy composition it is therefore theoretically possible to tailor the material properties to suit a wide range of applications, both in photovoltaics and in other fields. Keywords: p-type TCOs, p-type zinc oxide, p-type metal oxide
Preprint submitted to Vacuum
September 29, 2016
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semiconductors, cupric oxide, metal oxide alloy
1. Introduction
Transparent conducting oxides (TCOs) are the dominant class of transparent conductive material [1, 2]. Their uses are enormously varied and extremely
widespread, from computer screens, flat-screen televisions and smartphone dis-
plays to thin-film photovoltaics, smart windows and transparent electronics
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[1, 2, 3, 4]. They are wide band-gap metal oxide semiconductor materials which have been doped to such a high level that they become degenerate, exhibiting
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metallic conductivity [2].
The vast majority of metal oxide semiconductors are natively n-type [2, 5]. 10
Over the years, many groups have looked at ways of changing the primary carrier type in materials such as zinc oxide, tin dioxide and indium oxide with mixed success [6]. Others have worked with some of the few intrinsically p-type metal oxide materials, particularly the copper oxides (Cu2O and CuO). These latter
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materials have relatively narrow band gaps, making them of interest as solar absorbers (Cu2O is one of the most studied photoactive semiconductors) and
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solar cell back contact materials, but of limited use as TCOs [5, 7, 8, 9, 10, 11, 12]. Other p-type oxides that have shown some promise include ZnRh2 O4 , NiO, CuAlO2 , CuSrO2 and Cr2 O3 [5, 13, 14, 15].
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Zinc oxide (ZnO) is a commonly used wide band gap n-type semiconductor [16, 17]. In photovoltaics, it is typically used as a buffer layer in its intrinsic form or as the transparent top contact when doped with aluminium [18, 19].
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P-type ZnO could have uses as a p-type transparent conductor and as a back contact electron reflector layer, and could enable development of n-type absorber layers by acting as a transparent donor layer in a heterojunction device. It has
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also been suggested for use in other fields such as transparent electronics, UV resistant materials and the synthesis of all-oxide UV lasers and LEDs [6, 17, 20]. In common with most other metal oxides however synthesis of p-type ZnO is challenging [16, 17].
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P-type ZnO has been synthesised using a wide range of dopants and doping techniques [17, 20, 21, 22, 23]. The most successful results have largely been
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obtained using nitrogen as a dopant, which is in agreement with density functional theory (DFT) calculations [16, 17]. Several groups have reported p-type ZnO doped with copper (eg, [23, 24]).
Because the copper 3d subshell is energetically close to the oxygen 2p subshell, it has the effect of spreading the valence band and reducing the hole local-
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isation effect typically exhibited by oxygen atoms in metal oxides. The result is a reduced hole effective mass, and hence increased hole mobility [5, 10, 25]. By
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alloying copper oxides with wider band gap metal oxides, it is thought that synthesis of p-type materials with increased band gaps could be achievable. This 40
study investigates co-sputtering ZnO with cupric oxide (CuO).
2. Experimental details
CuO and ZnO were co-sputtered using an AJA International Orion 8HV
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sputter coater. CuO was deposited using an AJA International 600 series RF power supply, and ZnO was deposited using an Advanced Energy pulsed DC supply. Pressure was maintained at 1 mTorr (0.133 Pa). Films were deposited
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at room temperature. Argon flow rate was maintained at 7 standard cubic centimetres per minute (SCCM) and pure oxygen input was maintained at 4
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SCCM, resulting in an oxygen partial pressure of 0.048 Pa. ZnO power was varied from 105 W to 180 W, and CuO power was varied from 120 W to 60 W. 50
Characterisation of deposited films involved measuring film thickness, sheet
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resistance, transmission and Hall mobility, analysis of material composition and crystal structure, and observation of the film surface using SEM. Transmission was measured using a Varian Cary 5000 spectrophotometer, and film band gaps were calculated from transmission data using the Tauc method [26]. Thick-
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ness was measured using an Ambios XP2 stylus profilometer, and Hall mobility measurements were carried out using an Ecopia HMS 3000 Hall effect device. Carrier type was confirmed by exploiting the Seebeck effect and measuring the
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output voltage. Sheet resistance was measured using a four-point probe, and
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these data were used to verify the resistivities measured using the Hall effect system. SEM was carried out using a Carl Zeiss Leo 1530 VP field emission gun scanning electron microscope. The aperture size was 30 µm and the operating
voltage was 5 kV. Images were taken using a secondary electron detector at 50,000 times magnification.
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Crystal structure was examined by X-ray diffraction (XRD) using a Brucker D2 Phaser benchtop diffractometer equipped with a Cu-Kα X-ray gun and a Lynxeye
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detector. The beam slit was 1 mm wide, and the antiscatter plate
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was positioned 3 mm above the sample. Samples were rotated at 15 rpm. Compositional data were obtained using a Thermo Scientific K-Alpha
TM
X-ray
photoelectron spectrometer equipped with a monochromated Al-Kα X-ray gun 70
(hv = 1486.6 eV), an EX06 ion source, and a 180
◦
double focussing hemi-
spherical 128 channel analyser. Measurements were run at a base pressure of 3 x 10−7 mBar. The survey scan range was 0 to 1350 eV, with a pass energy of 200 eV. Step size was 1 eV. Data were collected over 10 scans, with 10 ms
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dwell time per step. High-resolution scans were run with a pass energy of 50 eV. Step size was 0.1 eV, and data were collected over 5 scans with 50 ms dwell
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time per step. Samples were subjected to a 60 second low power Ar+ etch (200 eV beam energy) prior to measurement so as to remove adventitious surface
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contamination. Peaks were identified and fitted using the Thermo Advantage analysis suite, using Smart (a Shirley variant) background subtraction.
3. Results and discussion
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Crystal structure was found to change significantly as the film composition
changed. Films with a high zinc content show XRD patterns characteristic of sputtered ZnO, with a single prominent peak at a 2Θ angle of 34 ◦ corresponding
to the ZnO wurtzite structure (002) plane. As the proportion of copper present
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in the film increases this peak is reduced, and disappears at copper contents above 23 % (as a percentage of total metal content). More copper rich films
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instead show a single small, broad CuO (111) peak at a 2Θ angle of around
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39 to 40 ◦ . A second change in crystal structure is seen as copper content is increased beyond 35 %. The single broad peak increases in size and two smaller 90
secondary peaks begin to emerge, which correspond to CuO (-111) and (110)
Intensity (arb. units)
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planes (Figure 1).
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13 % Cu
22 % Cu
ZnO (002)
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CuO (111)
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40
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Intensity (arb. units)
CuO (110)
50 2Θ (◦ )
26 % Cu
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35 % Cu
CuO (111)
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50 2Θ (◦ )
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40 % Cu
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CuO (-111)
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26 % Cu 60
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Figure 1: XRD patterns showing the change in crystal structure with decreasing copper content. (Upper) Zinc-rich films show typical ZnO patterns. This changes at around 22-25 %, becoming a single CuO peak. (Lower) As the copper content is increased above 35 % of total metal content two alternative CuO peaks emerge
The crystal structure could not be observed using SEM, indicating that
whilst the films clearly are crystalline the grain size is extremely small. Film surfaces do however show a number of patterns and undulations, the causes of
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which are unknown (Figure 2).
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Figure 2: SEM images of films with copper contents of 13 % (a), 26.5 % (b), 35 % (c) and 40
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% (d)
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The observed changes in crystal structure were found to correspond to significant changes in both optical and electrical properties. As the proportion of copper in the films increased the band gap was found to show a rapid reduction,
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up to a copper content of around 24.5 %. Further increases caused a slight increase in band gap, after which it decreased again at a reduced rate. A second
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shift occurs at a copper content of around 40 % (Figure 3). Changes in band gap with increased copper content were expected to produce either a straight line decrease, or more likely a curve as shown by amorphous alloy systems such as Ga(As,N) and (In,Ga)As [27, 28]. The overall trend is very clearly a general
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decrease in band gap with increased copper content, disrupted only at those points which correlate with the observed structural changes. When tested using the Seebeck effect, all films apart from pure ZnO were found to show p-type behaviour. Carrier concentration and mobility measure6
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ments carried out using the Hall effect system were found to be highly variable, making the resulting data unreliable. This is thought to be caused by the films
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110
having a mobility below that of the device’s measurement limit (less than 1 cm2 /V.s).
Resistivity was initially found to decrease roughly exponentially as copper
content is increased (Figure 3). This is thought to be caused by a combination
of increasing carrier concentration and reduced hole effective mass as the pro-
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portion of copper present increases; unfortunately this could not be confirmed because of the unreliable Hall mobility and carrier concentration data. In theory
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however the copper 3d subshell reduces the hole effective mass through having a similar energy level to that of the oxygen 2p level, which forms the valence 120
band in most metal oxides [29, 30]. This means that in copper-based oxides the valence band is both less flat and has a greater spread. Electron holes consequently have a lower effective mass, being less localised and so able to move around more freely. As copper content is reduced this effect is gradually removed, hence the increased resistivity. Although increased copper content was found to cause an overall reduction in resistivity, at two places there is a sudden
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and dramatic increase, which is counter to the general trend. These are at 24.5
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% and 35 % copper contents, and directly correlate with the observed changes in crystal structure. Furthermore, resistivity of films with high copper contents
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(>35 %) was found to be greater than those with intermediate copper contents (24.5 to 35 %). This implies that crystal structure has a significant impact on the material’s electrical properties. The resistivity of the most Zn-rich films was
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unfortunately too high to be measured reliably.
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ZnO-CuO transition
2.5
CuO-CuO transition
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1 20 30 40 50 60 Cu content (% of total metal content)
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ZnO-CuO transition
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Resistivity (Ω.cm)
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Band gap (eV)
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CuO-CuO transition
105 104 103 102
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20 30 40 50 Cu content (% of total metal content)
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Figure 3: (Upper) Band gap against film copper content (as a percentage of total metal content). (Lower) Resistivity against copper content as a percentage of total film metal
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content
In general, transmission was found to decrease with increasing copper content. The overall trend is the same as for band gap, with marked increases at copper contents of 24.5 % and 35 %. It was thought that this trend might
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be influenced by the position of the band gap for more copper-rich samples, but analysis of the average near-infrared transmission produces the same trend. Average infrared transmission was however typically found to be around 10 to 12 % higher than total average transmission (Figure 4).
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ZnO-CuO transition 80
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Total transmission IR transmission
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CuO-CuO transition
70 60 50
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20 30 40 50 Cu content (% of total metal content)
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Average transmission (%)
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Figure 4: Total and IR average transmission against copper content
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It is clear from these data that there is a strong correlation between crystal structure and optical and electrical properties. The significant increase in resistivity corresponding to the emergence of two further CuO peaks however is markedly larger than any of the changes seen in band gap or transmission, and
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is arguably greater than that exhibited at the change from ZnO-dominated to CuO-dominated structure. It is thought likely that the changes in crystal struc-
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ture have a direct causal effect on the optical and electrical properties, as has been observed in other materials (eg, [1, 31, 32]). This may be purely coincidental with the actual cause being as yet unidentified, however given how closely
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the changes correlate this seems unlikely. As crystallinity and crystal structure are heavily affected by deposition temperature, any further investigation into this system should also endeavour to examine the impact of heat. Identification
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of a method for successfully analysing the carrier concentration and mobility of p-type metal oxide films would also be of use in further confirming the cause of the observed behaviour.
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The overall increase in resistivity at wider band gaps and higher optical
transmissions mean that this material is unlikely to be suitable for use as a potential p-type TCO. Nonetheless, other possible applications for thin-film photovoltaics include back contact, p-type window and electron reflector layers.
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The changing crystal structure with compositional variation mean that it is theoretically possible to optimise the crystal lattice and hence reduce mismatch
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issues through careful compositional control. This ability to tailor material behaviour through simple alteration of the composition could also be of value in the design of other thin film optoelectronics devices such as LEDs and lasers.
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4. Conclusions
This study demonstrates that alloying ZnO with even a small quantity of CuO produces p-type behaviour.
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Unlike other mixed semiconductor alloys, this suite of materials shows crystalline behaviour. Crystal structure was found to show two significant changes within the range investigated, at copper contents of 24.5 % and 35 % (relative 170
to the total metal content). The former equates to a change from a ZnOdominated film with a (002) peak to a CuO dominated film with a broad (111) peak. The latter change is from the emergence of two further CuO peaks ((-
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111) and (110)). These changes correspond to significant variations in material band gap and transmission (both total and infrared), and to significant local increases in resistivity. With the exception of these variations, both band gap
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and resistivity decrease approximately linearly with increased copper content. It is likely that the optical and electrical effects are caused by the change
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in crystal structure, but further work is required to demonstrate this with certainty. Nonetheless, it is very clear that by tweaking the film composition, the 180
optical, electrical and structural properties of the material can be controlled.
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The material could therefore be tailored to meet the requirements for a range of applications, including p-type window and electron reflector layers and nontransparent p-type back contacts.
Acknowledgements
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The author would like to acknowledge the invaluable support and assistance of the Photovoltaics Materials group at CREST, Loughborough University, in 10
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S0042-207X(16)30626-1
DOI:
10.1016/j.vacuum.2016.09.026
Reference:
VAC 7147
To appear in:
Vacuum
Received Date: 24 June 2016 Revised Date:
1 August 2016
Accepted Date: 28 September 2016
Please cite this article as: Isherwood PJM, Copper zinc oxide: Investigation into a P-type mixed metal oxide system, Vaccum (2016), doi: 10.1016/j.vacuum.2016.09.026. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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P. J. M. Isherwood
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Copper Zinc Oxide: Investigation into a P-type Mixed Metal Oxide System
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Centre for Renewable Energy Systems Technology, Wolfson School of Mechanical Electrical and Manufacturing Engineering, Loughborough University, Loughborough, Leicestershire, LE11 3TU UK
Abstract
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In photovoltaics, ZnO is widely used both as an n-type window and buffer layer and as the basis for a range of transparent conducting oxide (TCO) top contact materials. Whilst there are reports of p-type doping, there have been no successful attempts to create a p-type ZnO-based TCO. Synthesis of an effective p-type TCO could be of significant benefit, enabling further development of technologies such as bifacial and multijunction devices. This study investigates
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the effects of combining ZnO with CuO, an intrinsically p-type narrow band
p-type alloys.
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gap metal oxide, with the aim of synthesising a range of mid to wide band gap
Alloying ZnO with CuO gave a range of p-type films with varying electrical, optical and structural characteristics. XRD patterns show that as copper
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content was increased above 24.5 % of the total metal content, crystal structure changed from a typical ZnO wurtzite structure to a CuO tenorite structure. A second change occured at 35 % copper with the emergence of two further tenorite
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peaks. These structural changes correlate to significant local increases in band gap, visible and infrared transmission, and resistivity. These dramatic changes correspond to relatively minor compositional variations. Through careful control of the alloy composition it is therefore theoretically possible to tailor the material properties to suit a wide range of applications, both in photovoltaics and in other fields. Keywords: p-type TCOs, p-type zinc oxide, p-type metal oxide
Preprint submitted to Vacuum
September 29, 2016
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semiconductors, cupric oxide, metal oxide alloy
1. Introduction
Transparent conducting oxides (TCOs) are the dominant class of transparent conductive material [1, 2]. Their uses are enormously varied and extremely
widespread, from computer screens, flat-screen televisions and smartphone dis-
plays to thin-film photovoltaics, smart windows and transparent electronics
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[1, 2, 3, 4]. They are wide band-gap metal oxide semiconductor materials which have been doped to such a high level that they become degenerate, exhibiting
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metallic conductivity [2].
The vast majority of metal oxide semiconductors are natively n-type [2, 5]. 10
Over the years, many groups have looked at ways of changing the primary carrier type in materials such as zinc oxide, tin dioxide and indium oxide with mixed success [6]. Others have worked with some of the few intrinsically p-type metal oxide materials, particularly the copper oxides (Cu2O and CuO). These latter
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materials have relatively narrow band gaps, making them of interest as solar absorbers (Cu2O is one of the most studied photoactive semiconductors) and
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solar cell back contact materials, but of limited use as TCOs [5, 7, 8, 9, 10, 11, 12]. Other p-type oxides that have shown some promise include ZnRh2 O4 , NiO, CuAlO2 , CuSrO2 and Cr2 O3 [5, 13, 14, 15].
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Zinc oxide (ZnO) is a commonly used wide band gap n-type semiconductor [16, 17]. In photovoltaics, it is typically used as a buffer layer in its intrinsic form or as the transparent top contact when doped with aluminium [18, 19].
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P-type ZnO could have uses as a p-type transparent conductor and as a back contact electron reflector layer, and could enable development of n-type absorber layers by acting as a transparent donor layer in a heterojunction device. It has
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also been suggested for use in other fields such as transparent electronics, UV resistant materials and the synthesis of all-oxide UV lasers and LEDs [6, 17, 20]. In common with most other metal oxides however synthesis of p-type ZnO is challenging [16, 17].
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P-type ZnO has been synthesised using a wide range of dopants and doping techniques [17, 20, 21, 22, 23]. The most successful results have largely been
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obtained using nitrogen as a dopant, which is in agreement with density functional theory (DFT) calculations [16, 17]. Several groups have reported p-type ZnO doped with copper (eg, [23, 24]).
Because the copper 3d subshell is energetically close to the oxygen 2p subshell, it has the effect of spreading the valence band and reducing the hole local-
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isation effect typically exhibited by oxygen atoms in metal oxides. The result is a reduced hole effective mass, and hence increased hole mobility [5, 10, 25]. By
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alloying copper oxides with wider band gap metal oxides, it is thought that synthesis of p-type materials with increased band gaps could be achievable. This 40
study investigates co-sputtering ZnO with cupric oxide (CuO).
2. Experimental details
CuO and ZnO were co-sputtered using an AJA International Orion 8HV
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sputter coater. CuO was deposited using an AJA International 600 series RF power supply, and ZnO was deposited using an Advanced Energy pulsed DC supply. Pressure was maintained at 1 mTorr (0.133 Pa). Films were deposited
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at room temperature. Argon flow rate was maintained at 7 standard cubic centimetres per minute (SCCM) and pure oxygen input was maintained at 4
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SCCM, resulting in an oxygen partial pressure of 0.048 Pa. ZnO power was varied from 105 W to 180 W, and CuO power was varied from 120 W to 60 W. 50
Characterisation of deposited films involved measuring film thickness, sheet
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resistance, transmission and Hall mobility, analysis of material composition and crystal structure, and observation of the film surface using SEM. Transmission was measured using a Varian Cary 5000 spectrophotometer, and film band gaps were calculated from transmission data using the Tauc method [26]. Thick-
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ness was measured using an Ambios XP2 stylus profilometer, and Hall mobility measurements were carried out using an Ecopia HMS 3000 Hall effect device. Carrier type was confirmed by exploiting the Seebeck effect and measuring the
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output voltage. Sheet resistance was measured using a four-point probe, and
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these data were used to verify the resistivities measured using the Hall effect system. SEM was carried out using a Carl Zeiss Leo 1530 VP field emission gun scanning electron microscope. The aperture size was 30 µm and the operating
voltage was 5 kV. Images were taken using a secondary electron detector at 50,000 times magnification.
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Crystal structure was examined by X-ray diffraction (XRD) using a Brucker D2 Phaser benchtop diffractometer equipped with a Cu-Kα X-ray gun and a Lynxeye
TM
detector. The beam slit was 1 mm wide, and the antiscatter plate
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was positioned 3 mm above the sample. Samples were rotated at 15 rpm. Compositional data were obtained using a Thermo Scientific K-Alpha
TM
X-ray
photoelectron spectrometer equipped with a monochromated Al-Kα X-ray gun 70
(hv = 1486.6 eV), an EX06 ion source, and a 180
◦
double focussing hemi-
spherical 128 channel analyser. Measurements were run at a base pressure of 3 x 10−7 mBar. The survey scan range was 0 to 1350 eV, with a pass energy of 200 eV. Step size was 1 eV. Data were collected over 10 scans, with 10 ms
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dwell time per step. High-resolution scans were run with a pass energy of 50 eV. Step size was 0.1 eV, and data were collected over 5 scans with 50 ms dwell
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time per step. Samples were subjected to a 60 second low power Ar+ etch (200 eV beam energy) prior to measurement so as to remove adventitious surface
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contamination. Peaks were identified and fitted using the Thermo Advantage analysis suite, using Smart (a Shirley variant) background subtraction.
3. Results and discussion
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Crystal structure was found to change significantly as the film composition
changed. Films with a high zinc content show XRD patterns characteristic of sputtered ZnO, with a single prominent peak at a 2Θ angle of 34 ◦ corresponding
to the ZnO wurtzite structure (002) plane. As the proportion of copper present
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in the film increases this peak is reduced, and disappears at copper contents above 23 % (as a percentage of total metal content). More copper rich films
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instead show a single small, broad CuO (111) peak at a 2Θ angle of around
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39 to 40 ◦ . A second change in crystal structure is seen as copper content is increased beyond 35 %. The single broad peak increases in size and two smaller 90
secondary peaks begin to emerge, which correspond to CuO (-111) and (110)
Intensity (arb. units)
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planes (Figure 1).
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13 % Cu
22 % Cu
ZnO (002)
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CuO (111)
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40
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Intensity (arb. units)
CuO (110)
50 2Θ (◦ )
26 % Cu
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35 % Cu
CuO (111)
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50 2Θ (◦ )
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40 % Cu
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CuO (-111)
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26 % Cu 60
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Figure 1: XRD patterns showing the change in crystal structure with decreasing copper content. (Upper) Zinc-rich films show typical ZnO patterns. This changes at around 22-25 %, becoming a single CuO peak. (Lower) As the copper content is increased above 35 % of total metal content two alternative CuO peaks emerge
The crystal structure could not be observed using SEM, indicating that
whilst the films clearly are crystalline the grain size is extremely small. Film surfaces do however show a number of patterns and undulations, the causes of
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which are unknown (Figure 2).
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Figure 2: SEM images of films with copper contents of 13 % (a), 26.5 % (b), 35 % (c) and 40
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% (d)
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The observed changes in crystal structure were found to correspond to significant changes in both optical and electrical properties. As the proportion of copper in the films increased the band gap was found to show a rapid reduction,
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up to a copper content of around 24.5 %. Further increases caused a slight increase in band gap, after which it decreased again at a reduced rate. A second
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shift occurs at a copper content of around 40 % (Figure 3). Changes in band gap with increased copper content were expected to produce either a straight line decrease, or more likely a curve as shown by amorphous alloy systems such as Ga(As,N) and (In,Ga)As [27, 28]. The overall trend is very clearly a general
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decrease in band gap with increased copper content, disrupted only at those points which correlate with the observed structural changes. When tested using the Seebeck effect, all films apart from pure ZnO were found to show p-type behaviour. Carrier concentration and mobility measure6
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ments carried out using the Hall effect system were found to be highly variable, making the resulting data unreliable. This is thought to be caused by the films
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110
having a mobility below that of the device’s measurement limit (less than 1 cm2 /V.s).
Resistivity was initially found to decrease roughly exponentially as copper
content is increased (Figure 3). This is thought to be caused by a combination
of increasing carrier concentration and reduced hole effective mass as the pro-
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portion of copper present increases; unfortunately this could not be confirmed because of the unreliable Hall mobility and carrier concentration data. In theory
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however the copper 3d subshell reduces the hole effective mass through having a similar energy level to that of the oxygen 2p level, which forms the valence 120
band in most metal oxides [29, 30]. This means that in copper-based oxides the valence band is both less flat and has a greater spread. Electron holes consequently have a lower effective mass, being less localised and so able to move around more freely. As copper content is reduced this effect is gradually removed, hence the increased resistivity. Although increased copper content was found to cause an overall reduction in resistivity, at two places there is a sudden
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and dramatic increase, which is counter to the general trend. These are at 24.5
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% and 35 % copper contents, and directly correlate with the observed changes in crystal structure. Furthermore, resistivity of films with high copper contents
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(>35 %) was found to be greater than those with intermediate copper contents (24.5 to 35 %). This implies that crystal structure has a significant impact on the material’s electrical properties. The resistivity of the most Zn-rich films was
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unfortunately too high to be measured reliably.
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ZnO-CuO transition
2.5
CuO-CuO transition
2 1.5
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1 20 30 40 50 60 Cu content (% of total metal content)
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ZnO-CuO transition
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Resistivity (Ω.cm)
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Band gap (eV)
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CuO-CuO transition
105 104 103 102
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20 30 40 50 Cu content (% of total metal content)
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Figure 3: (Upper) Band gap against film copper content (as a percentage of total metal content). (Lower) Resistivity against copper content as a percentage of total film metal
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content
In general, transmission was found to decrease with increasing copper content. The overall trend is the same as for band gap, with marked increases at copper contents of 24.5 % and 35 %. It was thought that this trend might
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be influenced by the position of the band gap for more copper-rich samples, but analysis of the average near-infrared transmission produces the same trend. Average infrared transmission was however typically found to be around 10 to 12 % higher than total average transmission (Figure 4).
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ZnO-CuO transition 80
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Total transmission IR transmission
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CuO-CuO transition
70 60 50
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20 30 40 50 Cu content (% of total metal content)
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Average transmission (%)
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Figure 4: Total and IR average transmission against copper content
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It is clear from these data that there is a strong correlation between crystal structure and optical and electrical properties. The significant increase in resistivity corresponding to the emergence of two further CuO peaks however is markedly larger than any of the changes seen in band gap or transmission, and
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is arguably greater than that exhibited at the change from ZnO-dominated to CuO-dominated structure. It is thought likely that the changes in crystal struc-
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ture have a direct causal effect on the optical and electrical properties, as has been observed in other materials (eg, [1, 31, 32]). This may be purely coincidental with the actual cause being as yet unidentified, however given how closely
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the changes correlate this seems unlikely. As crystallinity and crystal structure are heavily affected by deposition temperature, any further investigation into this system should also endeavour to examine the impact of heat. Identification
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of a method for successfully analysing the carrier concentration and mobility of p-type metal oxide films would also be of use in further confirming the cause of the observed behaviour.
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The overall increase in resistivity at wider band gaps and higher optical
transmissions mean that this material is unlikely to be suitable for use as a potential p-type TCO. Nonetheless, other possible applications for thin-film photovoltaics include back contact, p-type window and electron reflector layers.
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The changing crystal structure with compositional variation mean that it is theoretically possible to optimise the crystal lattice and hence reduce mismatch
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issues through careful compositional control. This ability to tailor material behaviour through simple alteration of the composition could also be of value in the design of other thin film optoelectronics devices such as LEDs and lasers.
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4. Conclusions
This study demonstrates that alloying ZnO with even a small quantity of CuO produces p-type behaviour.
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Unlike other mixed semiconductor alloys, this suite of materials shows crystalline behaviour. Crystal structure was found to show two significant changes within the range investigated, at copper contents of 24.5 % and 35 % (relative 170
to the total metal content). The former equates to a change from a ZnOdominated film with a (002) peak to a CuO dominated film with a broad (111) peak. The latter change is from the emergence of two further CuO peaks ((-
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111) and (110)). These changes correspond to significant variations in material band gap and transmission (both total and infrared), and to significant local increases in resistivity. With the exception of these variations, both band gap
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and resistivity decrease approximately linearly with increased copper content. It is likely that the optical and electrical effects are caused by the change
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in crystal structure, but further work is required to demonstrate this with certainty. Nonetheless, it is very clear that by tweaking the film composition, the 180
optical, electrical and structural properties of the material can be controlled.
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The material could therefore be tailored to meet the requirements for a range of applications, including p-type window and electron reflector layers and nontransparent p-type back contacts.
Acknowledgements
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The author would like to acknowledge the invaluable support and assistance of the Photovoltaics Materials group at CREST, Loughborough University, in 10
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particular Prof. Walls and Dr. Bowers, and also RCUK for financial support
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