An object is to provide a composition which has performance, such as emission wavelength, of carbon quantum dots in a desired range and in which carbon quantum dots and layered clay minerals are uniformly dispersed, and a method for producing the composition to obtain the composition simply and easily.

The carbon quantum dot-containing composition achieving the object described above containing a carbon quantum dot obtained by reacting a solid organic compound having a reactive group in the presence of a layered clay mineral, and the layered clay mineral.

An object is to provide a composition which has performance, such as emission wavelength, of carbon quantum dots in a desired range and in which carbon quantum dots and layered clay minerals are uniformly dispersed, and a method for producing the composition to obtain the composition simply and easily.

The carbon quantum dot-containing composition achieving the object described above containing a carbon quantum dot obtained by reacting a solid organic compound having a reactive group in the presence of a layered clay mineral, and the layered clay mineral.

Compositions and articles comprising diamond particles, such as nanodiamond based pharmaceutical compositions, are generally provided. In some embodiments, the articles and methods comprising (nano)diamond particles may be useful for monitoring and/or treating a disease (e.g., in a subject).

Compositions and articles comprising diamond particles, such as nanodiamond based pharmaceutical compositions, are generally provided. In some embodiments, the articles and methods comprising (nano)diamond particles may be useful for monitoring and/or treating a disease (e.g., in a subject).

One example of the present invention provides a negative electrode material. Such a negative electrode material may comprise lithium titanium oxide-based particles and a graphene quantum dot coating layer doped with nitrogen that is positioned on the lithium titanium oxide-based particles.

A method for producing a single photon source includes lithographically patterning a polymer on top of a plasmonic thin film, functionalizing top surfaces of the plasmonic thin film and the polymer, removing the polymer to form patterned functionalized sites on the top surface of the plasmonic thin film surface, and depositing nanodiamond particles to the patterned functionalized sites.

Described are devices, such as light emitters, lasers, and switches, and methods, such as methods of generating photoluminescence and methods of fabricating electronic devices. Example devices and methods described include those comprising or employing optically active graphene, such as in the form of one or more layers of quasi-1D graphene nanomaterials or graphene nanostripes including one or more topological defects. Optically active graphene can emit photoluminescence upon exposure to photoexcitation and can also generate laser emission, optionally as a frequency comb. The optically active graphene can be patterned onto substrates according to the disclosed methods of fabricating electronic devices and is optionally useful for generating optical switches.

Described are devices, such as light emitters, lasers, and switches, and methods, such as methods of generating photoluminescence and methods of fabricating electronic devices. Example devices and methods described include those comprising or employing optically active graphene, such as in the form of one or more layers of quasi-1D graphene nanomaterials or graphene nanostripes including one or more topological defects. Optically active graphene can emit photoluminescence upon exposure to photoexcitation and can also generate laser emission, optionally as a frequency comb. The optically active graphene can be patterned onto substrates according to the disclosed methods of fabricating electronic devices and is optionally useful for generating optical switches.

The application discloses a method for preparing a nano-quantum dot, a nano-quantum dot material, the application thereof and a quantum dot article, and relates to the technical field of quantum dot material preparation. The method for preparing the nano-quantum dot includes the following steps: rapidly solidifying a high-temperature melt in which a carrier corresponding to a target product ion/atomic group/molecular group is dissolved to obtain a carrier in which the target product nano-quantum dot is embedded. The nano-quantum dot material is prepared by using the method. The nano-quantum dot material is applied to the fields of luminescent devices, optical biological marks, disease detection, semiconductors or photoelectricity. Moreover, a quantum dot article containing the nano-quantum dot material is provided.

The application discloses a method for preparing a nano-quantum dot, a nano-quantum dot material, the application thereof and a quantum dot article, and relates to the technical field of quantum dot material preparation. The method for preparing the nano-quantum dot includes the following steps: rapidly solidifying a high-temperature melt in which a carrier corresponding to a target product ion/atomic group/molecular group is dissolved to obtain a carrier in which the target product nano-quantum dot is embedded. The nano-quantum dot material is prepared by using the method. The nano-quantum dot material is applied to the fields of luminescent devices, optical biological marks, disease detection, semiconductors or photoelectricity. Moreover, a quantum dot article containing the nano-quantum dot material is provided.