Incomplete elimination of precursor ligands during atomic layer deposition of zinc-oxide, tin-oxide, and zinc-tin-oxide

Mackus, Adriaan J. M.; MacIsaac, Callisto; Kim, Woo‐Hee; Bent, Stacey F.

doi:10.1063/1.4961459

Cited by 69 publications

(80 citation statements)

References 39 publications

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“…The commonly made assumption that all the surface ethyl ligands are removed from the surface after the water pulse has been shown to be incorrect by Mackus et al 11 The authors conducted an in situ gas-phase and surface FTIR spectroscopy measurements on the ALD of zinc tin oxide (ZTO) thin films and note that after a typical water exposure 30–50% of the surface ethyl ligands remain on the surface during the growth of a ZnO thin film. Even after extended periods of water exposure, approximately 16% of surface ethyl ligands remain on the surface at 150 °C temperature, and only at elevated temperatures around 200 °C have virtually all the ligands been removed from the surface.…”

Section: Introductionmentioning

confidence: 99%

Atomic Layer Deposition of Zinc Oxide: Study on the Water Pulse Reactions from First-Principles

Weckman

Laasonen

2018

J. Phys. Chem. C

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Atomic layer deposition (ALD) of zinc oxide thin films has been under intense research in the past few years. The most common precursors used in this process are diethyl zinc (DEZ) and water. The surface chemistry related to the growth of a zinc oxide thin film via atomic layer deposition is not entirely clear, and the ideal model of the process has been contradicted by experimental data, e.g., the incomplete elimination of the ethyl ligands from the surface and the non-negative mass change during the water pulse. In this work we investigate the surface reactions of water during the atomic layer deposition of zinc oxide. The adsorption and ligand-exchange reactions of water are studied on ethyl-saturated surface structures to grasp the relevant surface chemistry contributing to the deposition process. The complex ethyl-saturated surface structures are adopted from a previous publication on the DEZ/H2O-process, and different configurations are sampled using ab initio molecular dynamics in order to find a suitable minimum structure. Water molecules are found to adsorb exothermically onto the ethyl-covered surface at all the ethyl concentrations considered. We do not observe an adsorption barrier for water at 0 K; however, the adsorption energy for any additional water molecules decreases rapidly at high ethyl concentrations. Ligand-exchange reactions are studied at various surface ethyl coverages. The water pulse ligand-exchange reactions have overall larger activation energies than surface reactions for diethyl zinc pulse. For some of the configurations considered, the reaction barriers may be inaccessible at the process conditions, suggesting that some ligands may be inert toward ligand-exchange with water. The activation energies for the surface reactions show only a weak dependence on the surface ethyl concentration. The sensitivity of the adsorption of water at high ethyl coverages suggests that at high ligand-coverages the kinetics may be somewhat hindered due to steric effects. Calculations on the ethyl-covered surfaces are compared to a simple model containing a single monoethyl zinc group. The calculated activation energy for this model is in line with calculations done on the complex model, but the adsorption of water is poorly described. The weak adsorption bond onto a single monoethyl zinc is probably due to a cooperative effect between the surface zinc atoms. A cooperative effect between water molecules is also observed; however, the effect on the activation energies is not as significant as has been reported for other ALD processes.

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Section: Introductionmentioning

confidence: 99%

Atomic Layer Deposition of Zinc Oxide: Study on the Water Pulse Reactions from First-Principles

Weckman

Laasonen

2018

J. Phys. Chem. C

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“…It is seen that the weight loss occurs rapidly in a range between 70 and 150 °C, with a total weight loss of ≈92%. The DSC result shows one endothermic peak at 230 °C, indicating that the decomposition of the precursor and the residual precursor can coexist with SnO 2 below the temperature 23, 24. From our observation, we can draw a probable structure of the SnO 2 ETL as depicted in Figure 2g.…”

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confidence: 99%

Efficient Planar Perovskite Solar Cells Using Passivated Tin Oxide as an Electron Transport Layer

et al. 2018

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Planar perovskite solar cells using low‐temperature atomic layer deposition (ALD) of the SnO2 electron transporting layer (ETL), with excellent electron extraction and hole‐blocking ability, offer significant advantages compared with high‐temperature deposition methods. The optical, chemical, and electrical properties of the ALD SnO2 layer and its influence on the device performance are investigated. It is found that surface passivation of SnO2 is essential to reduce charge recombination at the perovskite and ETL interface and show that the fabricated planar perovskite solar cells exhibit high reproducibility, stability, and power conversion efficiency of 20%.

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“…The slow reaction kinetics at low temperatures suggests the possibility of unreacted ligands after the SnO 2 cycles, which reduce the available reactive sites for subsequent ZnO growth. A similar contention was made for ZTO films prepared by ALD using DEZ, tetrakis(dimethylamino)tin, and H 2 O where dimethylamine ligands were still detected on the reaction surface even after extremely long H 2 O pulses (900 s) 24. The report however argued that unremoved ligands only exist on the immediate growing surface and therefore are not incorporated in the films, as a consequence resulting in impurity free SnO 2 films.…”

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confidence: 54%

Band gap engineering of atomic layer deposited Zn_xSn_1‐xO buffer for efficient Cu(In,Ga)Se₂ solar cell

Agbenyeke

Song

Park

et al. 2018

Progress in Photovoltaics

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Ternary zinc tin oxide (ZTO) is one of the few environmental compatible buffer materials with the potential of replacing the n‐CdS buffer in Cu(In,Ga)Se2 (CIGS) solar cells and other photovoltaic systems once its properties are fully understood and optimized. In this work, ZTO films were grown by atomic layer deposition and were logically characterized with the aim of understanding the correlations between compositional changes and film properties. The ZnO:SnO2 pulse ratio significantly affected the growth rate, crystal structure, morphology, and band gap of the ZTO films. By controlling the Sn/(Sn + Zn) atomic ratio, the optical band gap of the ZTO films was tuned between 3.05 and 3.36 eV. Integrating the ZTO films as buffer layers in CIGS solar cells, we observed that films with Sn concentrations of 9 to 16 at.% yielded photo‐conversion efficiency close to 14%, which was very comparable to efficiency attained with the commonly used CdS buffer. Furthermore, using X‐ray photoelectron spectroscopy analysis, we correlated the current‐voltage behavior of the cells to the conduction band offset at the ZTO/ CIGS interface.

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Incomplete elimination of precursor ligands during atomic layer deposition of zinc-oxide, tin-oxide, and zinc-tin-oxide

Cited by 69 publications

References 39 publications

Atomic Layer Deposition of Zinc Oxide: Study on the Water Pulse Reactions from First-Principles

Atomic Layer Deposition of Zinc Oxide: Study on the Water Pulse Reactions from First-Principles

Efficient Planar Perovskite Solar Cells Using Passivated Tin Oxide as an Electron Transport Layer

Band gap engineering of atomic layer deposited Zn_xSn_1‐xO buffer for efficient Cu(In,Ga)Se₂ solar cell

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Incomplete elimination of precursor ligands during atomic layer deposition of zinc-oxide, tin-oxide, and zinc-tin-oxide

Cited by 69 publications

References 39 publications

Atomic Layer Deposition of Zinc Oxide: Study on the Water Pulse Reactions from First-Principles

Atomic Layer Deposition of Zinc Oxide: Study on the Water Pulse Reactions from First-Principles

Efficient Planar Perovskite Solar Cells Using Passivated Tin Oxide as an Electron Transport Layer

Band gap engineering of atomic layer deposited ZnxSn1‐xO buffer for efficient Cu(In,Ga)Se2 solar cell

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Band gap engineering of atomic layer deposited Zn_xSn_1‐xO buffer for efficient Cu(In,Ga)Se₂ solar cell