| Author | George, Antony | dc.contributor.author |
| Author | Neumann, Christof | dc.contributor.author |
| Author | Kaiser, David | dc.contributor.author |
| Author | Mupparapu, Rajeshkumar | dc.contributor.author |
| Author | Lehnert, Tibor | dc.contributor.author |
| Author | Hübner, Uwe | dc.contributor.author |
| Author | Tang, Zian | dc.contributor.author |
| Author | Winter, Andreas | dc.contributor.author |
| Author | Kaiser, Ute | dc.contributor.author |
| Author | Staude, Isabelle | dc.contributor.author |
| Author | Turchanin, Andrey | dc.contributor.author |
| Date of accession | 2022-12-06T15:41:52Z | dc.date.accessioned |
| Available in OPARU since | 2022-12-06T15:41:52Z | dc.date.available |
| Date of first publication | 2019-01-10 | dc.date.issued |
| Abstract | Abstract
Controlling the flow rate of precursors is essential for the growth of high quality monolayer single crystals of transition metal dichalcogenides (TMDs) by chemical vapor deposition. Thus, introduction of an excess amount of the precursors affects reproducibility of the growth process and results in the formation of TMD multilayers and other unwanted deposits. Here we present a simple method for controlling the precursor flow rates using the Knudsen-type effusion cells. This method results in a highly reproducible growth of large area and high density TMD monolayers. The size of the grown crystals can be adjusted between 10 and 200 μm. We characterized the grown MoS2 and WS2 monolayers by optical, atomic force and transmission electron microscopies as well as by x-ray photoelectron, Raman and photoluminescence spectroscopies, and by electrical transport measurements showing their high optical and electronic quality based on the single crystalline nature. | dc.description.abstract |
| Language | en | dc.language.iso |
| Publisher | Universität Ulm | dc.publisher |
| License | CC BY 3.0 | dc.rights |
| Link to license text | https://creativecommons.org/licenses/by/3.0/ | dc.rights.uri |
| Keyword | 2D materials | dc.subject |
| Keyword | transition metal dichalcogenides | dc.subject |
| Keyword | MoS2 | dc.subject |
| Keyword | WS2 | dc.subject |
| Dewey Decimal Group | DDC 620 / Engineering & allied operations | dc.subject.ddc |
| LCSH | Two-dimensional materials | dc.subject.lcsh |
| LCSH | Chemical vapor deposition | dc.subject.lcsh |
| Title | Controlled growth of transition metal dichalcogenide monolayers using Knudsen-type effusion cells for the precursors | dc.title |
| Resource type | Wissenschaftlicher Artikel | dc.type |
| SWORD Date | 2022-02-02T21:03:40Z | dc.date.updated |
| Version | publishedVersion | dc.description.version |
| DOI | http://dx.doi.org/10.18725/OPARU-46266 | dc.identifier.doi |
| URN | http://nbn-resolving.de/urn:nbn:de:bsz:289-oparu-46342-4 | dc.identifier.urn |
| GND | CVD-Verfahren | dc.subject.gnd |
| GND | Übergangsmetalldichalkogenide | dc.subject.gnd |
| Institution | ZE Elektronenmikroskopie | uulm.affiliationSpecific |
| Peer review | ja | uulm.peerReview |
| DCMI Type | Text | uulm.typeDCMI |
| Category | Publikationen | uulm.category |
| DOI of original publication | 10.1088/2515-7639/aaf982 | dc.relation1.doi |
| Source - Title of source | Journal of Physics: Materials | source.title |
| Source - Place of publication | IOP Publishing | source.publisher |
| Source - Volume | 2 | source.volume |
| Source - Issue | 1 | source.issue |
| Source - Year | 2019 | source.year |
| Source - Article number | 016001 | source.articleNumber |
| Source - eISSN | 2515-7639 | source.identifier.eissn |
| EU project uulm | GRAPHENE / Graphene-Based Revolutions in ICT And Beyond / EC / FP7 / 604391 | uulm.projectEU |
| WoS | 000559778800001 | uulm.identifier.wos |
| Bibliography | uulm | uulm.bibliographie |
| DFG project uulm | JUSTUS 2 / HPC Forschungscluster (bwForCluster) Computergestützte Chemie und Quantenwissenschaften / DFG / 405998092 [INST 275/257-1 FUGG] | uulm.projectDFG |
| Project uulm | SALVE project / DFG, MWK Baden-Württemberg | uulm.projectOther |
