Theoretical studies of microwave heating of dielectric liquid and magnetic crystal: Classical and quantum mechanical molecular dynamics simulations

Motohiko Tanaka; H. Kono; K. Maruyama; Y. Zempo

Theoretical studies of microwave heating of dielectric liquid and magnetic crystal: Classical and quantum mechanical molecular dynamics simulations

Motohiko Tanaka, H. Kono, K. Maruyama, Y. Zempo

工学科　知能情報工学コース

研究成果: 書籍の章/レポート/会議録 › 会議への寄与 › 査読

1 被引用数 (Scopus)

抄録

Using classical and quantum mechanical molecular dynamics simulations, our recent studies of heating of water (dielectric liquid) and that of magnetite (magnetic crystal) by microwaves have been performed. In the former, the electric field energy of microwave is absorbed mostly by small-angle molecular rotation of water molecules - not by translational motion until evaporation. In the latter, the magnetic energy of microwave is absorbed by the response of electron spins in 3d orbital, which is maximized around the Curie temperature. Heating efficiency depends on the orientation of the microwave magnetic field and the presence of static magnetic field.

本文言語	英語
ホスト出版物のタイトル	Microwave and RF Power Applications
ホスト出版物のサブタイトル	Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011
出版社	Editions Cepadues
ページ	195-198
ページ数	4
ISBN（印刷版）	9782854289787
出版ステータス	出版済み - 2011
イベント	13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011 - Toulouse, フランス継続期間: 2011/09/05 → 2011/09/08

出版物シリーズ

名前	Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011

学会

学会	13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011
国/地域	フランス
City	Toulouse
Period	2011/09/05 → 2011/09/08

ASJC Scopus 主題領域

放射線

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引用スタイル

Tanaka, M., Kono, H., Maruyama, K., & Zempo, Y. (2011). Theoretical studies of microwave heating of dielectric liquid and magnetic crystal: Classical and quantum mechanical molecular dynamics simulations. In Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011 (pp. 195-198). (Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011). Editions Cepadues.

Tanaka, Motohiko ; Kono, H. ; Maruyama, K. その他. / Theoretical studies of microwave heating of dielectric liquid and magnetic crystal : Classical and quantum mechanical molecular dynamics simulations. Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011. Editions Cepadues, 2011. pp. 195-198 (Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011).

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title = "Theoretical studies of microwave heating of dielectric liquid and magnetic crystal: Classical and quantum mechanical molecular dynamics simulations",

abstract = "Using classical and quantum mechanical molecular dynamics simulations, our recent studies of heating of water (dielectric liquid) and that of magnetite (magnetic crystal) by microwaves have been performed. In the former, the electric field energy of microwave is absorbed mostly by small-angle molecular rotation of water molecules - not by translational motion until evaporation. In the latter, the magnetic energy of microwave is absorbed by the response of electron spins in 3d orbital, which is maximized around the Curie temperature. Heating efficiency depends on the orientation of the microwave magnetic field and the presence of static magnetic field.",

keywords = "3d electron spin, Heisenberg model, Hydrogen bonds, Magnetite, Pure and salty water, Rotation of dipole moments",

author = "Motohiko Tanaka and H. Kono and K. Maruyama and Y. Zempo",

year = "2011",

language = "英語",

isbn = "9782854289787",

series = "Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011",

publisher = "Editions Cepadues",

pages = "195--198",

booktitle = "Microwave and RF Power Applications",

note = "13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011 ; Conference date: 05-09-2011 Through 08-09-2011",

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Tanaka, M, Kono, H, Maruyama, K & Zempo, Y 2011, Theoretical studies of microwave heating of dielectric liquid and magnetic crystal: Classical and quantum mechanical molecular dynamics simulations. in Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011. Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011, Editions Cepadues, pp. 195-198, 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011, Toulouse, フランス, 2011/09/05.

Theoretical studies of microwave heating of dielectric liquid and magnetic crystal: Classical and quantum mechanical molecular dynamics simulations. / Tanaka, Motohiko; Kono, H.; Maruyama, K. その他.
Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011. Editions Cepadues, 2011. p. 195-198 (Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011).

研究成果: 書籍の章/レポート/会議録 › 会議への寄与 › 査読

TY - GEN

T1 - Theoretical studies of microwave heating of dielectric liquid and magnetic crystal

T2 - 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011

AU - Tanaka, Motohiko

AU - Kono, H.

AU - Maruyama, K.

AU - Zempo, Y.

PY - 2011

Y1 - 2011

N2 - Using classical and quantum mechanical molecular dynamics simulations, our recent studies of heating of water (dielectric liquid) and that of magnetite (magnetic crystal) by microwaves have been performed. In the former, the electric field energy of microwave is absorbed mostly by small-angle molecular rotation of water molecules - not by translational motion until evaporation. In the latter, the magnetic energy of microwave is absorbed by the response of electron spins in 3d orbital, which is maximized around the Curie temperature. Heating efficiency depends on the orientation of the microwave magnetic field and the presence of static magnetic field.

AB - Using classical and quantum mechanical molecular dynamics simulations, our recent studies of heating of water (dielectric liquid) and that of magnetite (magnetic crystal) by microwaves have been performed. In the former, the electric field energy of microwave is absorbed mostly by small-angle molecular rotation of water molecules - not by translational motion until evaporation. In the latter, the magnetic energy of microwave is absorbed by the response of electron spins in 3d orbital, which is maximized around the Curie temperature. Heating efficiency depends on the orientation of the microwave magnetic field and the presence of static magnetic field.

KW - 3d electron spin

KW - Heisenberg model

KW - Hydrogen bonds

KW - Magnetite

KW - Pure and salty water

KW - Rotation of dipole moments

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M3 - 会議への寄与

AN - SCOPUS:84907022250

SN - 9782854289787

T3 - Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011

SP - 195

EP - 198

BT - Microwave and RF Power Applications

PB - Editions Cepadues

Y2 - 5 September 2011 through 8 September 2011

ER -

Tanaka M, Kono H, Maruyama K, Zempo Y. Theoretical studies of microwave heating of dielectric liquid and magnetic crystal: Classical and quantum mechanical molecular dynamics simulations. In Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011. Editions Cepadues. 2011. p. 195-198. (Microwave and RF Power Applications: Proceeding of the 13th International Conference on Microwave and Radio Frequency Heating, AMPERE 2011).