FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4309100384> ?p ?o ?g. }

• W4309100384 endingPage "3333" @default.
• W4309100384 startingPage "3322" @default.
• W4309100384 abstract "Graphene nanoribbons (GNRs)─quasi-one-dimensional graphene cutouts─have drawn growing attention as promising candidates for next-generation electronic and spintronic materials. Theoretical and experimental studies have demonstrated that the electronic and magnetic properties of GNRs critically depend on their widths and edge topologies. Thus, the preparation of structurally defined GNRs is highly desirable not only for their fundamental physicochemical studies but also for their future technological development in carbon-based nanoelectronics. In the past decade, significant efforts have been made to construct a wide variety of GNRs with well-defined widths and edge structures via bottom-up synthesis. In addition to extensively studied planar GNRs consisting of armchair, zigzag, or gulf edges, curved GNRs (cGNRs) bearing cove ([4]helicene unit) or fjord ([5]helicene unit) regions along the ribbon edges have received increasing interest after we presented the first attempt to synthesize the fully cove-edged GNRs in 2015. Profiting from their novel edge topologies, cGNRs usually exhibit an unprecedented narrow band gap and high carrier transport mobility in comparison to the planar GNRs with similar widths. Moreover, cGNRs with particular out-of-plane-distorted structures are expected to provide further opportunities in nonlinear optics and asymmetric catalysis. However, the synthesis of cGNRs bearing cove or fjord edges remains underdeveloped due to the absence of efficient synthetic strategies/methods and suitable molecular precursor design.In this Account, we present the recent advances in the bottom-up synthesis and characterization of structurally defined cGNRs containing cove or fjord edges, mainly from our research group. First, the synthetic strategies toward cGNRs bearing cove edges are described, including the design of molecular monomers and polymer precursors as well as the corresponding polymerization methods, such as Ullmann coupling, Yamamoto coupling, A2B2-type Diels-Alder polymerization, followed by Scholl-type cyclodehydrogenation. The synthesis of typical model compounds is also described to support the understanding of the related cGNRs. In addition, the synthesis of cGNRs containing fjord edges from other research groups via the regioselective Scholl reaction, Hopf cyclization or regioselective photochemical cyclodehydrochlorination approach is presented. Second, we discuss the optoelectronic properties of the as-synthesized cGNRs and reveal the design principle to obtain cGNRs with high charge carrier mobilities. Finally, the challenges and prospects in the design and synthesis of cGNRs are offered. We anticipate that this Account will further stimulate the development of cGNRs through a collaborative effort between different disciplines." @default.
• W4309100384 created "2022-11-22" @default.
• W4309100384 creator A5026825791 @default.
• W4309100384 creator A5029588332 @default.
• W4309100384 creator A5056305193 @default.
• W4309100384 date "2022-11-15" @default.
• W4309100384 modified "2023-10-14" @default.
• W4309100384 title "Precise Structural Regulation and Band-Gap Engineering of Curved Graphene Nanoribbons" @default.
• W4309100384 cites W1582764014 @default.
• W4309100384 cites W1959464420 @default.
• W4309100384 cites W1977087560 @default.
• W4309100384 cites W2047215113 @default.
• W4309100384 cites W2047735309 @default.
• W4309100384 cites W2096474469 @default.
• W4309100384 cites W2118240461 @default.
• W4309100384 cites W2124277227 @default.
• W4309100384 cites W2180555938 @default.
• W4309100384 cites W2328588927 @default.
• W4309100384 cites W2330048111 @default.
• W4309100384 cites W2331244636 @default.
• W4309100384 cites W2333827620 @default.
• W4309100384 cites W2472021490 @default.
• W4309100384 cites W2495358084 @default.
• W4309100384 cites W2594706449 @default.
• W4309100384 cites W2607473138 @default.
• W4309100384 cites W2616019228 @default.
• W4309100384 cites W2750766948 @default.
• W4309100384 cites W2765186663 @default.
• W4309100384 cites W2766535472 @default.
• W4309100384 cites W2774146458 @default.
• W4309100384 cites W2789720320 @default.
• W4309100384 cites W2794248587 @default.
• W4309100384 cites W2804178337 @default.
• W4309100384 cites W2804972464 @default.
• W4309100384 cites W2860018398 @default.
• W4309100384 cites W2870690646 @default.
• W4309100384 cites W2880918529 @default.
• W4309100384 cites W2886122985 @default.
• W4309100384 cites W2916945752 @default.
• W4309100384 cites W2954716044 @default.
• W4309100384 cites W2955401924 @default.
• W4309100384 cites W2956684212 @default.
• W4309100384 cites W2978096418 @default.
• W4309100384 cites W3003268269 @default.
• W4309100384 cites W3009140511 @default.
• W4309100384 cites W3011042268 @default.
• W4309100384 cites W3015129958 @default.
• W4309100384 cites W3041850201 @default.
• W4309100384 cites W3083953951 @default.
• W4309100384 cites W3084311282 @default.
• W4309100384 cites W3092750412 @default.
• W4309100384 cites W3101352084 @default.
• W4309100384 cites W3103057124 @default.
• W4309100384 cites W3144384238 @default.
• W4309100384 cites W3152764704 @default.
• W4309100384 cites W3159193983 @default.
• W4309100384 cites W3184315331 @default.
• W4309100384 cites W3185634248 @default.
• W4309100384 cites W4200066918 @default.
• W4309100384 cites W4212860589 @default.
• W4309100384 cites W4220983188 @default.
• W4309100384 cites W4281943775 @default.
• W4309100384 cites W4284966587 @default.
• W4309100384 doi "https://doi.org/10.1021/acs.accounts.2c00550" @default.
• W4309100384 hasPubMedId "https://pubmed.ncbi.nlm.nih.gov/36378659" @default.
• W4309100384 hasPublicationYear "2022" @default.
• W4309100384 type Work @default.
• W4309100384 citedByCount "9" @default.
• W4309100384 countsByYear W43091003842023 @default.
• W4309100384 crossrefType "journal-article" @default.
• W4309100384 hasAuthorship W4309100384A5026825791 @default.
• W4309100384 hasAuthorship W4309100384A5029588332 @default.
• W4309100384 hasAuthorship W4309100384A5056305193 @default.
• W4309100384 hasConcept C114793014 @default.
• W4309100384 hasConcept C121332964 @default.
• W4309100384 hasConcept C127313418 @default.
• W4309100384 hasConcept C140807948 @default.
• W4309100384 hasConcept C141400236 @default.
• W4309100384 hasConcept C159985019 @default.
• W4309100384 hasConcept C168074166 @default.
• W4309100384 hasConcept C171250308 @default.
• W4309100384 hasConcept C192271897 @default.
• W4309100384 hasConcept C192562407 @default.
• W4309100384 hasConcept C2524010 @default.
• W4309100384 hasConcept C2780291037 @default.
• W4309100384 hasConcept C2780392137 @default.
• W4309100384 hasConcept C30080830 @default.
• W4309100384 hasConcept C32909587 @default.
• W4309100384 hasConcept C33923547 @default.
• W4309100384 hasConcept C62520636 @default.
• W4309100384 hasConceptScore W4309100384C114793014 @default.
• W4309100384 hasConceptScore W4309100384C121332964 @default.
• W4309100384 hasConceptScore W4309100384C127313418 @default.
• W4309100384 hasConceptScore W4309100384C140807948 @default.
• W4309100384 hasConceptScore W4309100384C141400236 @default.
• W4309100384 hasConceptScore W4309100384C159985019 @default.
• W4309100384 hasConceptScore W4309100384C168074166 @default.
• W4309100384 hasConceptScore W4309100384C171250308 @default.

• next