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Modeling the Physical Properties of Envi...

Daku, Latévi Max La...

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Modeling the Physical Properties of Environmentally-Friendly Optical Magnetic Switches: DFT and TD-DFT by Daku, Latévi Max Lawson ( Author )

Content Provider	Lemonjar Open Access
Publisher	Australian National University
Publication Date	11-08-2023
Summary	The dominant majority of the hundreds of available spin-crossover compounds, including the technologically most promising ones, are based on the Earth-abundant metal iron, making these switches particularly appealing in terms of sustainable technology. Furthermore, it has recently been established that these materials may be synthesized using the techniques of Green Chemistry. Spin crossover in transition metal complexes can be induced by a change of temperature, by the application of an external pressure, or a magnetic field, and also by photoexcitation. Given the wide variety of functionalities to which these bistable photomagnetic systems could give access, they may be viewed as the prototypes of molecular-scale optomagnetic switches. Hence, in response to the growing demand for storing and treating increasingly-dense information, much effort has been devoted over several decades to the design of transition metal materials exhibiting spin crossover in technologically-accessible temperature ranges. The cornerstone for designing new efficient photoactive spin-crossover materials remains the ability to predict the magnetic behaviour and the photoresponse of any first-row transition complex, and the manner in which its properties are influenced by its environment. This is a challenge for the inorganic chemist and also, most notably, for the theoretical and the computational chemist. This chapter gives an overview of the issues tied to the application of DFT and TD-DFT to the characterisation of transition metal complexes in the framework of spin-crossover and related phenomena.
ISBN	-
Item Type	Article
File Type	pdf
File Size	30.00 KB
Language	English
Subjects	-
Unlimited	MYR 0.01
Total read	-
URL	http://arxiv.org/abs/1201.2398

Citation

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AMA 11th EditionReferences

Daku, Latévi Max Lawson. Modeling the Physical Properties of Environmentally-Friendly Optical Magnetic Switches: DFT and TD-DFT. Australian National University. August 11, 2023. Accessed October 01, 2025. https://online.provdatabase.com/cite/15797

APA 7th EditionReferences

Daku, Latévi Max Lawson. (2023). Modeling the Physical Properties of Environmentally-Friendly Optical Magnetic Switches: DFT and TD-DFT. Australian National University. https://online.provdatabase.com/cite/15797

Chicago 17th EditionReferences

Daku, Latévi Max Lawson. Modeling the Physical Properties of Environmentally-Friendly Optical Magnetic Switches: DFT and TD-DFT. Australian National University. 2023. https://online.provdatabase.com/cite/15797

HarvardReferences

Daku, Latévi Max Lawson. (2023). Modeling the Physical Properties of Environmentally-Friendly Optical Magnetic Switches: DFT and TD-DFT. [Online]. Australian National University. Available from: https://online.provdatabase.com/cite/15797. (Accessed 01 October 2025).

Harvard AustraliaReferences

Daku, Latévi Max Lawson, 2023, Modeling the Physical Properties of Environmentally-Friendly Optical Magnetic Switches: DFT and TD-DFT, Australian National University, viewed 01 October 2025, <https://online.provdatabase.com/cite/15797>

MLA 9th EditionWorks Cited

Daku, Latévi Max Lawson. Modeling the Physical Properties of Environmentally-Friendly Optical Magnetic Switches: DFT and TD-DFT. Australian National University, 2023. PROV Database, https://online.provdatabase.com/cite/15797.

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