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+{

+ "cells": [

+  {

+   "cell_type": "markdown",

+   "metadata": {},

+   "source": [

+    "#7: Magnetic Materials"

+   ]

+  },

+  {

+   "cell_type": "markdown",

+   "metadata": {},

+   "source": [

+    "##Example number 7.1, Page number 7.36"

+   ]

+  },

+  {

+   "cell_type": "code",

+   "execution_count": 7,

+   "metadata": {

+    "collapsed": false

+   },

+   "outputs": [

+    {

+     "name": "stdout",

+     "output_type": "stream",

+     "text": [

+      "temperature rise is 8.43 K\n"

+     ]

+    }

+   ],

+   "source": [

+    "#importing modules\n",

+    "import math\n",

+    "from __future__ import division\n",

+    "\n",

+    "#Variable declaration\n",

+    "El=10**-2*50;       #energy loss(J)\n",

+    "H=El*60;      #heat produced(J)\n",

+    "d=7.7*10**3;    #iron rod(kg/m**3)\n",

+    "s=0.462*10**-3;    #specific heat(J/kg K)\n",

+    "\n",

+    "#Calculation\n",

+    "theta=H/(d*s);     #temperature rise(K)\n",

+    "\n",

+    "#Result\n",

+    "print \"temperature rise is\",round(theta,2),\"K\""

+   ]

+  },

+  {

+   "cell_type": "markdown",

+   "metadata": {},

+   "source": [

+    "##Example number 7.2, Page number 7.36"

+   ]

+  },

+  {

+   "cell_type": "code",

+   "execution_count": 8,

+   "metadata": {

+    "collapsed": false

+   },

+   "outputs": [

+    {

+     "name": "stdout",

+     "output_type": "stream",

+     "text": [

+      "magnetic field at the centre is 14.0 weber/m**2\n",

+      "dipole moment is 9.0 *10**-24 ampere/m**2\n"

+     ]

+    }

+   ],

+   "source": [

+    "#importing modules\n",

+    "import math\n",

+    "from __future__ import division\n",

+    "\n",

+    "#Variable declaration\n",

+    "e=1.6*10**-19;    #charge(coulomb)\n",

+    "new=6.8*10**15;   #frequency(revolutions per second)\n",

+    "mew0=4*math.pi*10**-7;\n",

+    "R=5.1*10**-11;     #radius(m)\n",

+    "\n",

+    "#Calculation\n",

+    "i=round(e*new,4);          #current(ampere)\n",

+    "B=mew0*i/(2*R);    #magnetic field at the centre(weber/m**2)\n",

+    "A=math.pi*R**2;\n",

+    "d=i*A;       #dipole moment(ampere/m**2)\n",

+    "\n",

+    "#Result\n",

+    "print \"magnetic field at the centre is\",round(B),\"weber/m**2\"\n",

+    "print \"dipole moment is\",round(d*10**24),\"*10**-24 ampere/m**2\""

+   ]

+  },

+  {

+   "cell_type": "markdown",

+   "metadata": {},

+   "source": [

+    "##Example number 7.3, Page number 7.36"

+   ]

+  },

+  {

+   "cell_type": "code",

+   "execution_count": 9,

+   "metadata": {

+    "collapsed": false

+   },

+   "outputs": [

+    {

+     "name": "stdout",

+     "output_type": "stream",

+     "text": [

+      "intensity of magnetisation is 5.0 ampere/m\n",

+      "flux density in material is 1.257 weber/m**2\n"

+     ]

+    }

+   ],

+   "source": [

+    "#importing modules\n",

+    "import math\n",

+    "from __future__ import division\n",

+    "\n",

+    "#Variable declaration\n",

+    "chi=0.5*10**-5;    #magnetic susceptibility\n",

+    "H=10**6;     #field strength(ampere/m)\n",

+    "mew0=4*math.pi*10**-7;\n",

+    "\n",

+    "#Calculation\n",

+    "I=chi*H;     #intensity of magnetisation(ampere/m)\n",

+    "B=mew0*(I+H);    #flux density in material(weber/m**2)\n",

+    "\n",

+    "#Result\n",

+    "print \"intensity of magnetisation is\",I,\"ampere/m\"\n",

+    "print \"flux density in material is\",round(B,3),\"weber/m**2\""

+   ]

+  },

+  {

+   "cell_type": "markdown",

+   "metadata": {},

+   "source": [

+    "##Example number 7.4, Page number 7.36"

+   ]

+  },

+  {

+   "cell_type": "code",

+   "execution_count": 10,

+   "metadata": {

+    "collapsed": false

+   },

+   "outputs": [

+    {

+     "name": "stdout",

+     "output_type": "stream",

+     "text": [

+      "number of Bohr magnetons is 2.22 bohr magneon/atom\n"

+     ]

+    }

+   ],

+   "source": [

+    "#importing modules\n",

+    "import math\n",

+    "from __future__ import division\n",

+    "\n",

+    "#Variable declaration\n",

+    "B=9.27*10**-24;      #bohr magneton(ampere m**2)\n",

+    "a=2.86*10**-10;      #edge(m)\n",

+    "Is=1.76*10**6;       #saturation value of magnetisation(ampere/m)\n",

+    "\n",

+    "#Calculation\n",

+    "N=2/a**3;\n",

+    "mew_bar=Is/N;      #number of Bohr magnetons(ampere m**2)\n",

+    "mew_bar=mew_bar/B;      #number of Bohr magnetons(bohr magneon/atom)\n",

+    "\n",

+    "#Result\n",

+    "print \"number of Bohr magnetons is\",round(mew_bar,2),\"bohr magneon/atom\""

+   ]

+  },

+  {

+   "cell_type": "markdown",

+   "metadata": {},

+   "source": [

+    "##Example number 7.5, Page number 7.37"

+   ]

+  },

+  {

+   "cell_type": "code",

+   "execution_count": 11,

+   "metadata": {

+    "collapsed": false

+   },

+   "outputs": [

+    {

+     "name": "stdout",

+     "output_type": "stream",

+     "text": [

+      "average magnetic moment is 2.79 *10**-3 bohr magneton/spin\n"

+     ]

+    }

+   ],

+   "source": [

+    "#importing modules\n",

+    "import math\n",

+    "from __future__ import division\n",

+    "\n",

+    "#Variable declaration\n",

+    "mew0=4*math.pi*10**-7;\n",

+    "H=9.27*10**-24;      #bohr magneton(ampere m**2)\n",

+    "beta=10**6;      #field(ampere/m)\n",

+    "k=1.38*10**-23;    #boltzmann constant\n",

+    "T=303;    #temperature(K)\n",

+    "\n",

+    "#Calculation\n",

+    "mm=mew0*H*beta/(k*T);    #average magnetic moment(bohr magneton/spin)\n",

+    "\n",

+    "#Result\n",

+    "print \"average magnetic moment is\",round(mm*10**3,2),\"*10**-3 bohr magneton/spin\""

+   ]

+  },

+  {

+   "cell_type": "markdown",

+   "metadata": {},

+   "source": [

+    "##Example number 7.6, Page number 7.37"

+   ]

+  },

+  {

+   "cell_type": "code",

+   "execution_count": 13,

+   "metadata": {

+    "collapsed": false

+   },

+   "outputs": [

+    {

+     "name": "stdout",

+     "output_type": "stream",

+     "text": [

+      "hysteresis loss per cycle is 188.0 J/m**3\n",

+      "hysteresis loss per second is 9400.0 watt/m**3\n",

+      "power loss is 1.23 watt/kg\n"

+     ]

+    }

+   ],

+   "source": [

+    "#importing modules\n",

+    "import math\n",

+    "from __future__ import division\n",

+    "\n",

+    "#Variable declaration\n",

+    "A=94;      #area(m**2)\n",

+    "vy=0.1;    #value of length(weber/m**2)\n",

+    "vx=20;     #value of unit length\n",

+    "n=50;      #number of magnetization cycles\n",

+    "d=7650;    #density(kg/m**3)\n",

+    "\n",

+    "#Calculation\n",

+    "h=A*vy*vx;     #hysteresis loss per cycle(J/m**3)\n",

+    "hs=h*n;       #hysteresis loss per second(watt/m**3)\n",

+    "pl=hs/d;      #power loss(watt/kg)\n",

+    "\n",

+    "#Result\n",

+    "print \"hysteresis loss per cycle is\",h,\"J/m**3\"\n",

+    "print \"hysteresis loss per second is\",hs,\"watt/m**3\"\n",

+    "print \"power loss is\",round(pl,2),\"watt/kg\""

+   ]

+  }

+ ],

+ "metadata": {

+  "kernelspec": {

+   "display_name": "Python 2",

+   "language": "python",

+   "name": "python2"

+  },

+  "language_info": {

+   "codemirror_mode": {

+    "name": "ipython",

+    "version": 2

+   },

+   "file_extension": ".py",

+   "mimetype": "text/x-python",

+   "name": "python",

+   "nbconvert_exporter": "python",

+   "pygments_lexer": "ipython2",

+   "version": "2.7.9"

+  }

+ },

+ "nbformat": 4,

+ "nbformat_minor": 0

+}