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diff --git a/Engineering_Physics/Chapter14_1.ipynb b/Engineering_Physics/Chapter14_1.ipynb deleted file mode 100755 index 1191c56f..00000000 --- a/Engineering_Physics/Chapter14_1.ipynb +++ /dev/null @@ -1,359 +0,0 @@ -{ - "metadata": { - "name": "", - "signature": "sha256:03a15735237144f42a49956ccb15694e3ce619fee35260180caccfe8f848e036" - }, - "nbformat": 3, - "nbformat_minor": 0, - "worksheets": [ - { - "cells": [ - { - "cell_type": "heading", - "level": 1, - "metadata": {}, - "source": [ - "14: Magnetic Properties of Materials" - ] - }, - { - "cell_type": "heading", - "level": 2, - "metadata": {}, - "source": [ - "Example number 14.1, Page number 306" - ] - }, - { - "cell_type": "code", - "collapsed": false, - "input": [ - " \n", - "#importing modules\n", - "import math\n", - "from __future__ import division\n", - "\n", - "#Variable declaration\n", - "N = 6.02*10**23; #Avogadro's number(per mole)\n", - "A = 56; #Atomic weight of the substance(g/mole)\n", - "d = 7.9; #Density of the substance(g/cm**3)\n", - "m_B = 9.27*10**-24; #Bohr's Magneton(J/T)\n", - "\n", - "#Calculation\n", - "m = 2.2*m_B; #Magnetic moment of substance(J/T)\n", - "n = d*N/A ; #Number of atoms per unit volume of the substance(per cm**3)\n", - "n = n*10**6; #Number of atoms per unit volume of the substance(per m**3)\n", - "M = n*m; #Spontaneous magnetisation of the substance(A/m)\n", - "M = M/10**6;\n", - "M = math.ceil(M*10**3)/10**3; #rounding off the value of M to 3 decimals\n", - "\n", - "#Result\n", - "print \"The spontaneous magnetisation of the substance is\",M,\"*10**6 A/m\"" - ], - "language": "python", - "metadata": {}, - "outputs": [ - { - "output_type": "stream", - "stream": "stdout", - "text": [ - "The spontaneous magnetisation of the substance is 1.732 *10**6 A/m\n" - ] - } - ], - "prompt_number": 5 - }, - { - "cell_type": "heading", - "level": 2, - "metadata": {}, - "source": [ - "Example number 14.2, Page number 307" - ] - }, - { - "cell_type": "code", - "collapsed": false, - "input": [ - " \n", - "#importing modules\n", - "import math\n", - "from __future__ import division\n", - "\n", - "#Variable declaration\n", - "H = 200; #Field strength to which the ferromagnetic material is subjected(A/m)\n", - "M = 3100; #Magnetisation of the ferromagnetic material(A/m)\n", - "\n", - "#Calculation\n", - "chi = M/H; #Magnetic susceptibility\n", - "mew_r = 1 + chi; #Relative permeability of ferromagnetic material\n", - "\n", - "#Result\n", - "print \"The relative permeability of ferromagnetic material is\",mew_r" - ], - "language": "python", - "metadata": {}, - "outputs": [ - { - "output_type": "stream", - "stream": "stdout", - "text": [ - "The relative permeability of ferromagnetic material is 16.5\n" - ] - } - ], - "prompt_number": 6 - }, - { - "cell_type": "heading", - "level": 2, - "metadata": {}, - "source": [ - "Example number 14.3, Page number 307" - ] - }, - { - "cell_type": "code", - "collapsed": false, - "input": [ - " \n", - "#importing modules\n", - "import math\n", - "from __future__ import division\n", - "\n", - "#Variable declaration\n", - "H = 300; #Field strength to which the ferromagnetic material is subjected(A/m)\n", - "M = 4400; #Magnetisation of the ferromagnetic material(A/m)\n", - "\n", - "#Calculation\n", - "chi = M/H; #Magnetic susceptibility\n", - "mew_r = 1 + chi; #Relative permeability of ferromagnetic material\n", - "mew_r = math.ceil(mew_r*100)/100; #rounding off the value of mew_r to 2 decimals\n", - "\n", - "#Result\n", - "print \"The relative permeability of ferromagnetic material is\",mew_r\n" - ], - "language": "python", - "metadata": {}, - "outputs": [ - { - "output_type": "stream", - "stream": "stdout", - "text": [ - "The relative permeability of ferromagnetic material is 15.67\n" - ] - } - ], - "prompt_number": 7 - }, - { - "cell_type": "heading", - "level": 2, - "metadata": {}, - "source": [ - "Example number 14.4, Page number 307" - ] - }, - { - "cell_type": "code", - "collapsed": false, - "input": [ - " \n", - "#importing modules\n", - "import math\n", - "\n", - "#Variable declaration\n", - "mew_0 = 4*math.pi*10**-7; #Magnetic permeability of free space(Tm/A)\n", - "H = 10000; #Field strength to which the diamagnetic material is subjected(A/m)\n", - "chi = -0.4*10**-5; #Magnetic susceptibility\n", - "\n", - "#Calculation\n", - "M = chi*H; #Magnetisation of the diamagnetic material(A/m)\n", - "B = mew_0*(H + M); #Magnetic flux density of diamagnetic material(T)\n", - "B = math.ceil(B*10**4)/10**4; #rounding off the value of B to 4 decimals\n", - "\n", - "#Result\n", - "print \"The magnetisation of diamagnetic material is\",M, \"A/m\"\n", - "print \"The magnetic flux density of diamagnetic material is\",B, \"T\"" - ], - "language": "python", - "metadata": {}, - "outputs": [ - { - "output_type": "stream", - "stream": "stdout", - "text": [ - "The magnetisation of diamagnetic material is -0.04 A/m\n", - "The magnetic flux density of diamagnetic material is 0.0126 T\n" - ] - } - ], - "prompt_number": 8 - }, - { - "cell_type": "heading", - "level": 2, - "metadata": {}, - "source": [ - "Example number 14.5, Page number 307" - ] - }, - { - "cell_type": "code", - "collapsed": false, - "input": [ - " \n", - "#importing modules\n", - "import math\n", - "from __future__ import division\n", - "\n", - "#Variable declaration\n", - "mew_0 = 4*math.pi*10**-7; #Magnetic permeability of free space(Tm/A)\n", - "H = 1.2*10**5; #Field strength to which the diamagnetic material is subjected(A/m)\n", - "chi = -4.2*10**-6; #Magnetic susceptibility\n", - "\n", - "#Calculation\n", - "M = chi*H; #Magnetisation of the diamagnetic material(A/m)\n", - "B = mew_0*(H + M); #Magnetic flux density of diamagnetic material(T)\n", - "B = math.ceil(B*10**3)/10**3; #rounding off the value of B to 3 decimals\n", - "mew_r = M/H + 1; #The relative permeability of diamagnetic material\n", - "mew_r = math.ceil(mew_r*10**6)/10**6; #rounding off the value of mew_r to 6 decimals\n", - "\n", - "#Result\n", - "print \"The magnetisation of diamagnetic material is\",M, \"A/m\"\n", - "print \"The magnetic flux density of diamagnetic material is\",B, \"T\"\n", - "print \"The relative permeability of diamagnetic material is\",mew_r\n" - ], - "language": "python", - "metadata": {}, - "outputs": [ - { - "output_type": "stream", - "stream": "stdout", - "text": [ - "The magnetisation of diamagnetic material is -0.504 A/m\n", - "The magnetic flux density of diamagnetic material is 0.151 T\n", - "The relative permeability of diamagnetic material is 0.999996\n" - ] - } - ], - "prompt_number": 10 - }, - { - "cell_type": "heading", - "level": 2, - "metadata": {}, - "source": [ - "Example number 14.6, Page number 308" - ] - }, - { - "cell_type": "code", - "collapsed": false, - "input": [ - " \n", - "#importing modules\n", - "import math\n", - "from __future__ import division\n", - "\n", - "#Variable declaration\n", - "chi = 5.6*10**-6; #Magnetic susceptibility of diamagnetic material\n", - "m = 9.1*10**-31; #Mass of an electron(kg)\n", - "mew_0 = 4*math.pi*10**-7; #Magnetic permeability of free space(Tm/A)\n", - "Z = 1; #Atomic number\n", - "e = 1.6*10**-19; #Electronic charge(C)\n", - "a = 2.53; #Lattice parameter of bcc structure(A)\n", - "\n", - "#Calculation\n", - "a = a*10**-10; #Lattice parameter of bcc structure(m)\n", - "N = 2/a**3; #The number of electrons per unit volume(per metre cube)\n", - "r = math.sqrt(chi*6*m/(mew_0*Z*e**2*N)); #Mean radius of body centered cubic structure(m)\n", - "r = r*10**10; #Mean radius of body centered cubic structure(A)\n", - "r = math.ceil(r*100)/100; #rounding off the value of r to 2 decimals\n", - "\n", - "#Result\n", - "print \"The mean radius of body centered cubic structure is\",r, \"A\"" - ], - "language": "python", - "metadata": {}, - "outputs": [ - { - "output_type": "stream", - "stream": "stdout", - "text": [ - "The mean radius of body centered cubic structure is 0.88 A\n" - ] - } - ], - "prompt_number": 11 - }, - { - "cell_type": "heading", - "level": 2, - "metadata": {}, - "source": [ - "Example number 14.7, Page number 308" - ] - }, - { - "cell_type": "code", - "collapsed": false, - "input": [ - "\n", - "#importing modules\n", - "import math\n", - "from __future__ import division\n", - "\n", - "#Variable declaration\n", - "mew_0 = 4*math.pi*10**-7; #Magnetic permeability of free space(Tm/A)\n", - "N_A = 6.02*10**26; #Avogadro's number(per kmol)\n", - "rho = 4370; #Density of paramegnetic salt(kg/metre cube)\n", - "M = 168.5; #Molecular weight of paramagnetic salt(g/mol)\n", - "T = 27; #Temperature of paramagnetic salt(C)\n", - "H = 2*10**5; #Field strength to which the paramagnetic salt is subjected(A/m)\n", - "mew_B = 9.27*10**-24; #Bohr's magneton(Am**2)\n", - "p = 2; #Number of Bohr magnetons per molecule\n", - "k = 1.38*10**-23; #Boltzmann constant(J/K)\n", - "\n", - "#Calculation\n", - "T = T+273; #Temperature of paramagnetic salt(K)\n", - "N = rho*N_A/M; #Total density of atoms in the paramagnetic salt(per meter cube)\n", - "chi_para = mew_0*N*p**2*mew_B**2/(3*k*T); #Magnetic susceptibility of paramagnetic salt\n", - "chi_para = chi_para*10**4;\n", - "chi_para = math.ceil(chi_para*10**2)/10**2; #rounding off the value of chi_para to 2 decimals\n", - "M = chi*H; #Magnetisation of paramagnetic salt(A/m)\n", - "M = math.ceil(M*10)/10; #rounding off the value of M to 1 decimal\n", - "\n", - "#Result\n", - "print \"The magnetic susceptibility of paramagnetic salt is\",chi_para,\"*10**-4\"\n", - "print \"The magnetisation of paramagnetic salt is\",M, \"A/m\"\n", - "\n", - "#answer for magnetisation is not given in the textbook" - ], - "language": "python", - "metadata": {}, - "outputs": [ - { - "output_type": "stream", - "stream": "stdout", - "text": [ - "The magnetic susceptibility of paramagnetic salt is 5.43 *10**-4\n", - "The magnetisation of paramagnetic salt is 1.2 A/m\n" - ] - } - ], - "prompt_number": 14 - }, - { - "cell_type": "code", - "collapsed": false, - "input": [], - "language": "python", - "metadata": {}, - "outputs": [] - } - ], - "metadata": {} - } - ] -}
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