Detail publikace

EXPERIMENTS WITH the influence of a Magnetic Field on the Speed of Temperature Experiments with the influence of a Magnetic Field on the Speed of Temperature Change

Originální název

EXPERIMENTS WITH the influence of a Magnetic Field on the Speed of Temperature Experiments with the influence of a Magnetic Field on the Speed of Temperature Change

Anglický název

EXPERIMENTS WITH the influence of a Magnetic Field on the Speed of Temperature Experiments with the influence of a Magnetic Field on the Speed of Temperature Change

Jazyk

en

Originální abstrakt

The paper presents the micro/nanoscopic model of a material inserted in a magnetic field. The model accepts the time component of an electromagnetic field from the perspective of the relative motion of systems. The relatively moving systems were derived and tested , Fiala P., 2011, and the influence of the motion on the superposed electromagnetic field was proved to exist already at relative motion speeds in the order of units of ms-1. In micro- and nanoscopic objects such as biological tissues, the effect of an external magnetic field on the growth and behaviour of the biological system needs to be evaluated. We designed the model based on a description using Maxwells equations of the electromagnetic field, and we also extended the monitored quantities to include the various flux densities; moreover, the time flux density t(t) was monitored as a quantity. This quantity was then experimentally examined on the physical problem of the speed of heating a defined volume of a homogeneous material in relation to the magnitude and type of the surrounding magnetic field. Experiments were conducted with growth properties of simple biological samples in pre-set external magnetic fields

Anglický abstrakt

The paper presents the micro/nanoscopic model of a material inserted in a magnetic field. The model accepts the time component of an electromagnetic field from the perspective of the relative motion of systems. The relatively moving systems were derived and tested , Fiala P., 2011, and the influence of the motion on the superposed electromagnetic field was proved to exist already at relative motion speeds in the order of units of ms-1. In micro- and nanoscopic objects such as biological tissues, the effect of an external magnetic field on the growth and behaviour of the biological system needs to be evaluated. We designed the model based on a description using Maxwells equations of the electromagnetic field, and we also extended the monitored quantities to include the various flux densities; moreover, the time flux density t(t) was monitored as a quantity. This quantity was then experimentally examined on the physical problem of the speed of heating a defined volume of a homogeneous material in relation to the magnitude and type of the surrounding magnetic field. Experiments were conducted with growth properties of simple biological samples in pre-set external magnetic fields

BibTex


@inproceedings{BUT111180,
  author="Eliška {Vlachová Hutová} and Karel {Bartušek} and Pavel {Fiala}",
  title="EXPERIMENTS WITH the influence of a Magnetic Field on the Speed of Temperature Experiments with the influence of a Magnetic Field on the Speed of Temperature Change",
  annote="The paper presents the micro/nanoscopic model of a material inserted in a
magnetic field. The model accepts the time component of an electromagnetic field from
the perspective of the relative motion of systems. The relatively moving systems were
derived and tested , Fiala P., 2011, and the influence of the motion on the superposed
electromagnetic field was proved to exist already at relative motion speeds in the order of
units of ms-1. In micro- and nanoscopic objects such as biological tissues, the effect of an
external magnetic field on the growth and behaviour of the biological system needs to be
evaluated. We designed the model based on a description using Maxwells equations of
the electromagnetic field, and we also extended the monitored quantities to include the
various flux densities; moreover, the time flux density t(t) was monitored as a quantity.
This quantity was then experimentally examined on the physical problem of the speed of
heating a defined volume of a homogeneous material in relation to the magnitude and
type of the surrounding magnetic field. Experiments were conducted with growth
properties of simple biological samples in pre-set external magnetic fields",
  booktitle="Proceedings of 22nd SVSFEM ANSYS Users' Group Meeting and Conference 2014 25th – 27th of June 2014, Jasná, Slovak Republic",
  chapter="111180",
  howpublished="online",
  year="2014",
  month="july",
  pages="149--157",
  type="conference paper"
}