If you don't see your institution, add your dataset to the main dataverse named "RepOD".
Select the dataverse to which you want to add the new dataset:
You need to Sign In/Sign Up to add a dataset.
Share this dataset on your favorite social media networks.
Ludwiczak, Katarzyna; Da̧browska, Aleksandra; Binder, Johannes; Tokarczyk, Mateusz; Iwański, Jakub; Kurowska, Bogusława; Turczyński, Jakub; Kowalski, Grzegorz; Bożek, Rafał; Stępniewski, Roman; Pacuski, Wojciech; Wysmołek, Andrzej, 2023, "Heteroepitaxial Growth of High Optical Quality, Wafer-Scale van der Waals Heterostrucutres", https://doi.org/10.18150/0OGN71, RepOD, V1
Learn about Data Citation Standards.
The experimental data presented is related to the article “Heteroepitaxial Growth of High Optical Quality, Wafer-Scale van der Waals Heterostrucutres”.
Transition metal dichalcogenides (TMDs) are materials that can exhibit intriguing optical properties like a change of the bandgap from indirect to direct when being thinned down to a monolayer. Well-resolved narrow excitonic resonances can be observed for such monolayers although only for materials of sufficient crystalline quality and so far mostly available in the form of micrometer-sized flakes. A further significant improvement of optical and electrical properties can be achieved by transferring the TMD on hexagonal boron nitride (hBN). To exploit the full potential of TMDs in future applications, epitaxial techniques have to be developed that not only allow the growth of large-scale, high-quality TMD monolayers but also allow the growth to be performed directly on large-scale epitaxial hBN. This work addresses this problem and demonstrates that MoSe2 of high optical quality can be directly grown on epitaxial hBN on an entire 2 in. wafer. We developed a combined growth theme for which hBN is first synthesized at high temperature by metal-organic vapor phase epitaxy (MOVPE) and as a second step MoSe2 is deposited on top by molecular beam epitaxy (MBE) at much lower temperatures. We show that this structure exhibits excellent optical properties, manifested by narrow excitonic lines in the photoluminescence spectra. Moreover, the material is homogeneous on the area of the whole 2 in. wafer with only ± 0.14 meV deviation of excitonic energy. Our mixed growth technique may guide the way for future large-scale production of high-quality TMD/hBN heterostructures.
layered materials, transition metal dichalcogenides, epitaxy, metalorganic vapor phase epitaxy, molecular beam epitaxy, Raman spectroscopy
K. Ludwiczak, A. K. Da̧browska, J. Binder, M. Tokarczyk, J. Iwański, B. Kurowska, J. Turczyński, G. Kowalski, R. Bożek, R. Stȩpniewski, W. Pacuski, A.Wysmołek "Heteroepitaxial Growth of High Optical Quality, Wafer-Scale van der Waals Heterostrucutres" ACS Appl. Mater. Interfaces 2021, 13, 47904 − 47911 https://doi.org/10.1021/acsami.1c11867 doi: 10.1021/acsami.1c11867
CC BY - Creative Commons Attribution 4.0
Please select a file or files to be deleted.
The file(s) will be deleted after you click on the Delete button.
Files will not be removed from previously published versions of the dataset.
Please select a file or files to be edited.
For selected file(s) set a license to
Please select a file or files to be downloaded.
Please select a file or files for access request.
Please select restricted file(s) to be unrestricted.
You need to Log In/Sign Up to request access to this file.
Please confirm and/or complete the information needed below in order to continue.
Asterisks indicate required fields
Access to file(s) subject to additional consent under following conditions:
The restricted file(s) selected may not be downloaded because you have not been granted access.
Click Continue to download the files you have access to download.
Are you sure you want to delete this dataset and all of its files? You cannot undelete this dataset.
Are you sure you want to lift the embargo?
Once you lift the embargo, you will not be able to set it again.
Are you sure you want to delete this draft version? Files will be reverted to the most recently published version. You cannot undelete this draft.
Use a Private URL to allow those without Dataverse accounts to access your dataset. For more information about the Private URL feature, please refer to the User Guide.
Private URL has not been created.
Are you sure you want to disable the Private URL? If you have shared the Private URL with others they will no longer be able to use it to access your dataset.
You will not be able to make changes to this dataset while it is in review.
This dataset cannot be published until RepOD is published. Would you like to publish both right now?
Once you publish this dataset it must remain published.
Are you sure you want to republish this dataset?
Select if this is a minor or major version update.
This dataset cannot be published until RepOD is published by its administrator.
This dataset cannot be published until RepOD and are published.
Are you sure you want to deaccession? The selected version(s) will no longer be viewable by the public.
Contact person for this dataset, having substantive knowledge of the data
Please fill this out to prove you are not a robot.
