Stable Dopant-Free Asymmetric Heterocontact Silicon Solar Cells with Efficiencies above 20%

TL;DR: In this article, a high performance, low-temperature, electron-selective heterocontact is developed, comprised of a surface passivating a-Si:H layer, a protective TiOx interlayer, and a low work function LiFx/Al outer electrode.

Abstract: Development of new device architectures and process technologies is of tremendous interest in crystalline silicon (c-Si) photovoltaics to drive enhanced performance and/or reduced processing cost. In this regard, an emerging concept with a high-efficiency potential is to employ low/high work function metal compounds or organic materials to form asymmetric electron and hole heterocontacts. This Letter demonstrates two important milestones in advancing this burgeoning concept. First, a high-performance, low-temperature, electron-selective heterocontact is developed, comprised of a surface passivating a-Si:H layer, a protective TiOx interlayer, and a low work function LiFx/Al outer electrode. This is combined with a MoOx hole-selective heterocontact to demonstrate a cell efficiency of 20.7%, the highest value for this cell class to date. Second, we show that this cell passes a standard stability test by maintaining >95% of its original performance after 1000 h of unencapsulated damp heat exposure, indicating...

Summary

Stable Dopant-Free Asymmetric Heterocontact Silicon Solar Cells with Efficiencies Above

• 20% James Bullock1,2,‡, Yimao Wan1,2,3,‡, Zhaoran Xu1,2, Stephanie Essig4, Mark Hettick1,2, Hanchen Wang1,2, Wenbo Ji1,2, Mathieu Boccard4, Andres Cuevas3, Christophe Ballif4 and Ali Javey1,2,* 1Department of Electrical Engineering and Computer Sciences, University of California, Berkeley, California 94720, USA.
• 2Materials Sciences Division, Lawrence Berkeley National Laboratory, Berkeley, California 94720, USA.
• 3 Research School of Engineering, The Australian National University (ANU), Canberra, ACT 0200, Australia 4 École Polytechnique Fédérale de Lausanne (EPFL), Institute of Micro Engineering (IMT), Photovoltaics and Thin Film Electronic Laboratory , Maladière 71b, CH-200 Neuchatel, Switzerland ‡.
• These authors have contributed equally to this work * corresponding author: Ali Javey (ajavey@berkeley.edu).

1000 hours of unencapsulated damp-heat exposure, indicating its potential for longevity.

• In recent times, there has been a significant increase in the use of metal oxides,1–6 fluorides,7–9 sulphides,10 and organic materials11,12 as carrier selective heterocontacts for crystalline silicon (c-Si) photovoltaic (PV) devices.
• The Ta2Ox and TiOx films show the lowest conduction band offsets and hence they should present the smallest impediment to electron flow.
• 16,28 The heterocontact explored here is unique in the combination of passivation, protection and low work function from the a-Si:H, TiOx and LiFx / Al layers.
• After accounting for a contact fraction of ~3%, the integration of the EQE and the solar spectrum product gives a Jsc of 38.8 mA/cm2.
• These developments in efficiency and stability pave the way for the DASH cell design to become a viable contender for high performance, low- cost c-Si PV.

Materials characterization:

• Samples for X-ray Photoelectron Spectroscopy (XPS) and Spectroscopic Ellipsometry (SE) were fabricated by depositing thin films of TiOx, Ta2Ox, HfOx and Al2Ox on a polished n+ silicon wafer which was given a short 5% HF etch prior to deposition.
• The thin films were deposited by atomic-layer-deposition (ALD), with a chamber temperature of ≤ 150°C.
• XPS measurements were performed in a Kratos spectrometer with an Al monochromatic X-ray source.
• All measurements were performed on thin films (~15 nm) without electron gun neutralization.
• Efforts were made to minimize charging by reducing incident X-ray exposure during the secondary electron cutoff measurement, and core level and valence band spectra were referenced to a C 1s peak at 284.8eV.

Device fabrication and characterization.

• Contact structures were fabricated according to a transfer-length-method (TLM) design.
• H layers were deposited via plasma enhanced chemical vapor deposition and the TCOs via DC sputtering, also known as The a-Si.
• Next, the front-side was deposited with ~5 nm of thermally evaporated MoOx followed by ~70 nm of sputtered indium tin oxide (ITO) and finally low temperature Ag paste was screen printed and cured at 190°C.
• The external quantum efficiency and reflection were measured in an inhouse built setup.

Figures

Figure 2 | Electron contact optimization, a, structure of hybrid cell used for contact optimization, b, 1-sun light JV behaviour of hybrid cells with 3 nm protective metal oxide layers, c, 1-sun light JV behaviour of hybrid cells with different TiOx thicknesses showing an optimum thickness of 1.5 nm.

Table 1 | Deposition conditions and properties of atomic-layer-deposited metal oxide protective layers.

Table 2 | Damp heat stability. 1-sun JV characteristics of a representative DASH cell measured before and after 1000 hours of unencapsulated exposure to 85oC, 85% RH.

Figure 1 | Electron contact materials, a, Secondary electron cutoff energy (for work function), b, valence band spectrum, and c, refractive indices (top: real part n, bottom: imaginary part k) of different metal oxide protective films. d, potential band position diagram for the electron heterocontact materials using information from a-c.

Figure 4 | DASH cell record. a, structure of the DASH cell, b, 1-sun light JV behaviour of champion DASH cell, c, external quantum efficiency (EQE), internal quantum efficiency (IQE) and reflection of champion DASH cell, the inset shows a photograph of the cell design and the integrated Jsc value. The white scale bar is ~1 cm.

Figure 3 | Electron contact stability. a, ρc as a function of sequential 10 minute anneals at increasing temperatures for samples with/without a-Si:H and TiOx layers. b, Voc progression of hybrid cells after sequential 10 minute anneals at increasing temperatures for cells with/without the TiOx layer.

Full text

This document is the unedited Author’s version of a Submitted Work that was subsequently accepted
for publication in ACS Energy Letters, copyright © American Chemical Society after peer review. To
access the final edited and published work see
https://pubs.acs.org/doi/full/10.1021/acsenergylett.7b01279

Accepted: ACS Energy Letters, Jan 2018
1
Stable Dopant-Free Asymmetric Heterocontact Silicon Solar Cells with Efficiencies Above
20%
James Bullock
1,2,‡
, Yimao Wan
1,2,3,‡
, Zhaoran Xu
1,2
, Stephanie Essig
4
, Mark Hettick
1,2
, Hanchen
Wang
1,2
, Wenbo Ji
1,2
, Mathieu Boccard
4
, Andres Cuevas
3
, Christophe Ballif
4
and Ali Javey
1,2,
*
1
Department of Electrical Engineering and Computer Sciences, University of California, Berkeley, California 94720, USA.
2
Materials Sciences Division, Lawrence Berkeley National Laboratory, Berkeley, California 94720, USA.
3
Research School of Engineering, The Australian National University (ANU), Canberra, ACT 0200, Australia
4
École Polytechnique Fédérale de Lausanne (EPFL), Institute of Micro Engineering (IMT), Photovoltaics and Thin Film
Electronic Laboratory (PVLab), Maladière 71b, CH-200 Neuchatel, Switzerland
‡
These authors have contributed equally to this work
* corresponding author: Ali Javey (ajavey@berkeley.edu)

Accepted: ACS Energy Letters, Jan 2018
2
Abstract
Development of new device architectures and process technologies are of tremendous
interest in crystalline silicon (c-Si) photovoltaics to drive enhanced performance and/or
reduced processing cost. In this regard, an emerging concept with a high efficiency potential
is to employ low/high work function metal compounds or organic materials to form
asymmetric electron and hole heterocontacts. This paper demonstrates two important
milestones in advancing this burgeoning concept. Firstly, a high-performance, low-
temperature, electron-selective heterocontact is developed, comprised of a surface
passivating a-Si:H layer, a protective TiO
x
interlayer and a low work function LiF
x
/Al outer
electrode. This is combined with a MoO
x
hole-selective heterocontact to demonstrate a cell
efficiency of 20.7% – the highest value for this cell class to date. Secondly, we show that this
cell passes a standard stability test by maintaining >95% of its original performance after
1000 hours of unencapsulated damp-heat exposure, indicating its potential for longevity.
TOC Figure

Accepted: ACS Energy Letters, Jan 2018
3
In recent times, there has been a significant increase in the use of metal oxides,
1–6
fluorides,
7–9
sulphides,
10
and organic materials
11,12
as carrier selective heterocontacts for
crystalline silicon (c-Si) photovoltaic (PV) devices. This research stream has been motivated by
potential advantages associated with fabrication simplicity and cost reduction. Such materials can
be deposited at low temperature (< 200
o
C) using simple techniques, to form full-area
heterocontacts with optical characteristics tailored for either the sunward- or rear-side of a solar
cell. These heterocontacts can also overcome or reduce losses common to other c-Si cell
architectures—for example, parasitic absorption or heavy impurity doping losses
7,13–15
—
increasing the practical efficiency limit of this structure. Most efforts so far have focused on
substituting one such heterocontact into an otherwise conventional c-Si cell,
16–20
demonstrating, in
many cases, clear performance or fabrication advantages. The ultimate extension of this concept
is to use a set of asymmetric heterocontacts in a single cell structure, sometimes referred to as the
dopant-free asymmetric heterocontact or DASH cell. In our previous study, we presented a record
19.4% efficient DASH solar cell,
7
utilizing MoO
x
and LiF
x
based heterocontacts with thin
amorphous silicon (a-Si:H) interfacial passivation layers. Although promising for a first proof-of-
concept, it is important to demonstrate that higher conversion efficiencies can be achieved, in line
with the suggested higher efficiency potential of this architecture. Further, for a new technology
to be considered in a field such as c-Si PV, it must satisfy additional requirements related to thermal
steps during cell and module fabrication and to device longevity in operation. Therefore, in this
study the DASH cell structure is revisited with a particular emphasis on simultaneously improving
the device efficiency and stability. Modifications to the structure and fabrication allow us to show
for the first time that this technology is compatible with efficiencies greater than 20%. We also

Accepted: ACS Energy Letters, Jan 2018
4
show that un-encapsulated DASH devices can pass an accelerated environmental test designed to
simulate the expected damp-heat stressors presented to a solar cell over its lifetime.
To increase the DASH cell performance, improvements must be made simultaneously to
both the electron and hole heterocontacts. A recent study conducted by co-authors has shown the
thermal stability of the hole heterocontact can be improved via an additional annealing step prior
to the MoO
x
deposition.
21
In this study, we focus on the electron side, aiming to develop a
thermally robust rear heterocontact. The electron-selective heterocontact of our first-generation
DASH cell utilized a low work function (~1 nm) LiF
x
/ Al outer stack to efficiently extract
electrons. When applied to c-Si the low work function induces downward band-bending,
encouraging electrons to the surface. To improve the stability of this contact, here we integrate
thin oxide protective layers to prevent interaction between the thin a-Si:H passivation layer and
the LiF
x
/ Al layers, without causing a significant impediment to electron flow. Four candidate
oxides are trialled in this application: Titanium oxide (TiO
x
), Tantalum oxide (Ta
2
O
x
), Hafnium
oxide (HfO
x
) and Aluminium oxide (Al
2
O
x
). All are deposited via atomic layer deposition (ALD)
at temperatures ≤ 150
o
C (further details can be found in Table 1). These materials are chosen to
study the influence of conduction band offset on the electron contact performance. To firstly
quantify the conduction band offset, Figure 1 presents the measured optoelectronic properties of
TiO
x
, Ta
2
O
x
, HfO
x
and Al
2
O
x
thin films (~15 nm) deposited on polished c-Si wafers. The work
function and valence band spectrum, measured by X-ray Photoelectron Spectroscopy (XPS), are
presented in Figure 1a and b, respectively. The oxygen and metal core levels are also measured by
XPS, revealing the stoichiometry of TiO
x
(x = 2.02), Ta
2
O
x
(x = 5.0), HfO
x
(x = 1.93) and Al
2
O
x
(x = 2.98). This is accompanied by the refractive indices (n, k) presented in Figure 1c, extracted
from spectroscopic ellipsometry. Implicit within this modelling is a fitting of the optical bandgap