Oxide-induced grain growth in CZTS nanoparticle coatings

Exarhos, Stephen; Palmes, E.; Xu, Rui; Mangolini, Lorenzo

doi:10.1039/c7ra04128d

Cited by 5 publications

(3 citation statements)

References 46 publications

(27 reference statements)

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“…Several studies have reported an enhancement in grain size under oxygen-annealing conditions, e.g. by employing open air oxidation of CZTS nanoparticles [33], by adding a MoO2 layer on the back contact [34], or by adding a Na2MoO4 layer on the back contact [35]. The SnOxSy layer at the CZTS/Mo interface is present in oxide and oxy-sulfide samples.…”

Section: Comparison Between Sulfurization Of Oxide Oxy-sulfide and Su...mentioning

confidence: 99%

Oxide route for production of Cu2ZnSnS4 solar cells by pulsed laser deposition

Gansukh

Mariño

Rodriguez

et al. 2020

Solar Energy Materials and Solar Cells

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Section: Comparison Between Sulfurization Of Oxide Oxy-sulfide and Su...mentioning

confidence: 99%

Oxide route for production of Cu2ZnSnS4 solar cells by pulsed laser deposition

Gansukh

Mariño

Rodriguez

et al. 2020

Solar Energy Materials and Solar Cells

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“…There are many methods by which CZTS can be manufactured. [156], screen printing [157], doctor blade coating [158], slot-die coating [159], roller coating [160] (if flexible substrates are used), and, for lab-scale PV devices, spin-coating [161]. The pre-prepared CZTS that is deposited can come in the form of a nanocrystal ink or paste.…”

Section: Deposition Techniquesmentioning

confidence: 99%

“…Once cooled, the CZTS nanocrystals are extracted using a centrifuge, and washed and re-suspended in an organic solvent [164]. Alternative methods of manufacturing CZTS inks include using a spray pyrolysis method, where the dissolved metallic compounds are sprayed through a tube furnace [156], a microwave solution heating method [158,165], and the solid state reaction of copper, zinc, tin and sulphur powders in a furnace followed by ball milling and re-suspension in a solvent [166]. CZTS deposited from inks and pastes still requires sulphurisation or selenisation in order to facilitate grain growth, and selenised films have achieved efficiencies of up to 9.0% [167].…”

Section: The Manufacture Of Nanocrystal Inksmentioning

confidence: 99%

Fabrication of CZTS Solar Cells Using Electrodeposition Techniques

Riches¹

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Copper zinc tin sulphide (CZTS) is a p-type semiconductor that can be used as the light absorbing layer in thin-film heterojunction solar cells, with the specific advantage of being comprised only of non-toxic, earth abundant elements. There are many methods through which CZTS can by synthesised, one of which is electrodeposition, which is an industrially scalable process used extensively in the steel industry. This thesis details a study of the electrodeposition of stacked elemental layers and their subsequent sulphurisation in the manufacture of CZTS. A range of electrodeposition parameters are tested for each elemental layer, each of which is characterised through a range of techniques, including scanning electron microscopy (SEM) and energy dispersive spectroscopy (EDS), which enables the development of optimised conditions. It was found that the deposition of copper favoured potentiostatic deposition, with a smooth granular structure being deposited onto molybdenum at -0.98V vs Hg|HgO from a sodium hydroxide based electrolyte, while tin required galvanostatic deposition from a methanesulfonic acid electrolyte in order to return consistent results. This was optimised to an initial high current density period of -20 mA cm-2 for 1.2 s to nucleate grains, falling to -5 mA cm-2 to minimise hydrogen evolution thereafter. Trial of numerous electrolyte formulae found that an acid-sulphate electrolyte gave the most promising results, with galvanostatic deposition at -50 mA cm-2 being found to be suitable. Optimised stacked elemental layer precursors are then progressed to the annealing and sulphurisation stage for conversion into CZTS. One key area of study is the inclusion of a pre-alloying annealing step prior to sulphurisation, and its effect on the morphology of the CZTS films and subsequent solar cell device performance. Pre-alloyed metallic films are extensively characterised by means of X-ray photoelectron spectroscopy (XPS) depth profiling, X-ray diffractometry (XRD) and EDS elemental mapping as part of an optimisation process, and Raman spectroscopy is used in conjunction with XRD and EDS in the analysis of CZTS films sulphurised in a rapid thermal processing (RTP) furnace. A pre-alloying step at 300 °C for 10 minutes was found to be sufficient for the deposited elements to fully intermix. It was discovered that not only does the inclusion of an optimised pre-alloying step improve the morphology of the CZTS films and the subsequent solar cell performance, but the integration of a pre-alloying stage with the sulphurisation in a single furnace operation does not lead to any evidence of disadvantage when compared with pre-alloying and sulphurisation processes conducted separately. In fact, 8 out of 45 cells with an integrated pre-alloying process achieved 0.1% efficiency or greater, compared to 5 out of 45 for those that underwent a separate pre-alloying process, and 0 out of 45 for those that received no pre-alloying process. This positive result for the integration of the pre-alloy offers simplification of the manufacturing process for a potential future scaled-up CZTS solar cell device.

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