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<div id="content">
<header>
<h1 class="title">
<a href="./index.html" class="homepage-link">Pre-Quantum Electrodynamics</a>
</h1>
</header>
<nav id="collapsed-table-of-contents">
<details>
<summary>
Table of contents
</summary>
<ul>
<li>

<details>
<summary>
<a href="./in.html#in">Introduction</a><span class="headline-id">in</span>


</summary>
<ul>
<li>
<a href="./in_p.html#in_p">Preface</a><span class="headline-id">in.p</span>

</li>
<li>

<details>
<summary>
<a href="./in_t.html#in_t">Tips for the reader</a><span class="headline-id">in.t</span>


</summary>
<ul>
<li>
<a href="./in_t_l.html#in_t_l">Section and equation labelling</a><span class="headline-id">in.t.l</span>

</li>
<li>
<a href="./in_t_c.html#in_t_c">Contextual colors</a><span class="headline-id">in.t.c</span>

</li>

</ul>
</details>
</li>

</ul>
</details>
</li>
<li>

<details open="">
<summary class="toc-open">
<a href="./ems.html#ems">Electromagnetostatics</a><span class="headline-id">ems</span>


</summary>
<ul>
<li>

<details>
<summary>
<a href="./ems_es.html#ems_es">Electrostatics</a><span class="headline-id">ems.es</span>


</summary>
<ul>
<li>

<details>
<summary>
<a href="./ems_es_ec.html#ems_es_ec">Electric Charge</a><span class="headline-id">ems.es.ec</span>


</summary>
<ul>
<li>
<a href="./ems_es_ec_b.html#ems_es_ec_b">Basics</a><span class="headline-id">ems.es.ec.b</span>

</li>
<li>
<a href="./ems_es_ec_c.html#ems_es_ec_c">Conservation</a><span class="headline-id">ems.es.ec.c</span>

</li>
<li>
<a href="./ems_es_ec_q.html#ems_es_ec_q">Quantization</a><span class="headline-id">ems.es.ec.q</span>

</li>
<li>
<a href="./ems_es_ec_s.html#ems_es_ec_s">Structure</a><span class="headline-id">ems.es.ec.s</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./ems_es_efo.html#ems_es_efo">Electric Force and Energy</a><span class="headline-id">ems.es.efo</span>


</summary>
<ul>
<li>
<a href="./ems_es_efo_cl.html#ems_es_efo_cl">Coulomb's Law</a><span class="headline-id">ems.es.efo.cl</span>

</li>
<li>
<a href="./ems_es_efo_ps.html#ems_es_efo_ps">Principle of Superposition</a><span class="headline-id">ems.es.efo.ps</span>

</li>
<li>
<a href="./ems_es_efo_exp.html#ems_es_efo_exp">Experimental Investigations</a><span class="headline-id">ems.es.efo.exp</span>

</li>
<li>
<a href="./ems_es_efo_e.html#ems_es_efo_e">Energy in Systems of Point Charges</a><span class="headline-id">ems.es.efo.e</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./ems_es_ef.html#ems_es_ef">Electrostatic Fields</a><span class="headline-id">ems.es.ef</span>


</summary>
<ul>
<li>
<a href="./ems_es_ef_pc.html#ems_es_ef_pc">Electrostatic Field of Point Charges</a><span class="headline-id">ems.es.ef.pc</span>

</li>
<li>
<a href="./ems_es_ef_ccd.html#ems_es_ef_ccd">Electrostatic Field of Continuous Charge Distributions</a><span class="headline-id">ems.es.ef.ccd</span>

</li>
<li>
<a href="./ems_es_ef_cE.html#ems_es_ef_cE">The Curl of \({\bf E}\)</a><span class="headline-id">ems.es.ef.cE</span>

</li>
<li>
<a href="./ems_es_ef_Gl.html#ems_es_ef_Gl">Gauss's Law: the divergence of \({\bf E}\)</a><span class="headline-id">ems.es.ef.Gl</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./ems_es_ep.html#ems_es_ep">The Electrostatic Potential</a><span class="headline-id">ems.es.ep</span>


</summary>
<ul>
<li>
<a href="./ems_es_ep_d.html#ems_es_ep_d">Definition</a><span class="headline-id">ems.es.ep.d</span>

</li>
<li>
<a href="./ems_es_ep_fp.html#ems_es_ep_fp">Field in terms of the potential</a><span class="headline-id">ems.es.ep.fp</span>

</li>
<li>
<a href="./ems_es_ep_ex.html#ems_es_ep_ex">Example calculations for the potential</a><span class="headline-id">ems.es.ep.ex</span>

</li>
<li>
<a href="./ems_es_ep_PL.html#ems_es_ep_PL">Poisson's and Laplace's Equations</a><span class="headline-id">ems.es.ep.PL</span>

</li>
<li>
<a href="./ems_es_ep_bc.html#ems_es_ep_bc">Electrostatic Boundary Conditions</a><span class="headline-id">ems.es.ep.bc</span>

</li>

</ul>
</details>
</li>
<li>
<a href="./ems_es_e.html#ems_es_e">Electrostatic Energy from the Potential</a><span class="headline-id">ems.es.e</span>

</li>
<li>

<details>
<summary>
<a href="./ems_es_c.html#ems_es_c">Conductors</a><span class="headline-id">ems.es.c</span>


</summary>
<ul>
<li>
<a href="./ems_es_c_p.html#ems_es_c_p">Properties</a><span class="headline-id">ems.es.c.p</span>

</li>
<li>
<a href="./ems_es_c_ic.html#ems_es_c_ic">Induced Charges</a><span class="headline-id">ems.es.c.ic</span>

</li>
<li>
<a href="./ems_es_c_sc.html#ems_es_c_sc">Surface Charge and the Force on a Conductor</a><span class="headline-id">ems.es.c.sc</span>

</li>
<li>
<a href="./ems_es_c_cap.html#ems_es_c_cap">Capacitors</a><span class="headline-id">ems.es.c.cap</span>

</li>

</ul>
</details>
</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./ems_ca.html#ems_ca">Calculating or Approximating the Electrostatic Potential</a><span class="headline-id">ems.ca</span>


</summary>
<ul>
<li>

<details>
<summary>
<a href="./ems_ca_fe.html#ems_ca_fe">Fundamental Equations for the Electrostatic Potential</a><span class="headline-id">ems.ca.fe</span>


</summary>
<ul>
<li>
<a href="./ems_ca_fe_L.html#ems_ca_fe_L">The Laplace Equation</a><span class="headline-id">ems.ca.fe.L</span>

</li>
<li>
<a href="./ems_ca_fe_g.html#ems_ca_fe_g">Green's Identities</a><span class="headline-id">ems.ca.fe.g</span>

</li>
<li>
<a href="./ems_ca_fe_uP.html#ems_ca_fe_uP">Uniqueness of Solution to Poisson's Equation</a><span class="headline-id">ems.ca.fe.uP</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./ems_ca_mi.html#ems_ca_mi">The Method of Images</a><span class="headline-id">ems.ca.mi</span>


</summary>
<ul>
<li>
<a href="./ems_ca_mi_isc.html#ems_ca_mi_isc">Induced Surface Charges</a><span class="headline-id">ems.ca.mi.isc</span>

</li>
<li>
<a href="./ems_ca_mi_fe.html#ems_ca_mi_fe">Force and Energy</a><span class="headline-id">ems.ca.mi.fe</span>

</li>
<li>
<a href="./ems_ca_mi_o.html#ems_ca_mi_o">Other Image Problems</a><span class="headline-id">ems.ca.mi.o</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./ems_ca_sv.html#ems_ca_sv">Separation of Variables</a><span class="headline-id">ems.ca.sv</span>


</summary>
<ul>
<li>
<a href="./ems_ca_sv_car.html#ems_ca_sv_car">Cartesian Coordinates</a><span class="headline-id">ems.ca.sv.car</span>

</li>
<li>
<a href="./ems_ca_sv_cyl.html#ems_ca_sv_cyl">Cylindrical Coordinates</a><span class="headline-id">ems.ca.sv.cyl</span>

</li>
<li>
<a href="./ems_ca_sv_sph.html#ems_ca_sv_sph">Spherical Coordinates</a><span class="headline-id">ems.ca.sv.sph</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./ems_ca_me.html#ems_ca_me">The Multipole Expansion</a><span class="headline-id">ems.ca.me</span>


</summary>
<ul>
<li>
<a href="./ems_ca_me_a.html#ems_ca_me_a">Approximate Potential at Large Distance</a><span class="headline-id">ems.ca.me.a</span>

</li>
<li>
<a href="./ems_ca_me_md.html#ems_ca_me_md">Monopole and Dipole Terms</a><span class="headline-id">ems.ca.me.md</span>

</li>
<li>
<a href="./ems_ca_me_h.html#ems_ca_me_h">Higher Moments</a><span class="headline-id">ems.ca.me.h</span>

</li>
<li>
<a href="./ems_ca_me_Ed.html#ems_ca_me_Ed">The Electric Field of a Dipole</a><span class="headline-id">ems.ca.me.Ed</span>

</li>
<li>
<a href="./ems_ca_me_Eq.html#ems_ca_me_Eq">The Electric Field of a Quadrupole</a><span class="headline-id">ems.ca.me.Eq</span>

</li>

</ul>
</details>
</li>

</ul>
</details>
</li>
<li>

<details open="">
<summary class="toc-open">
<a href="./ems_ms.html#ems_ms">Magnetostatics</a><span class="headline-id">ems.ms</span>


</summary>
<ul>
<li>

<details>
<summary>
<a href="./ems_ms_lf.html#ems_ms_lf">Charges in Motion: the Lorentz Force Law</a><span class="headline-id">ems.ms.lf</span>


</summary>
<ul>
<li>
<a href="./ems_ms_lf_pc.html#ems_ms_lf_pc">Point Charges</a><span class="headline-id">ems.ms.lf.pc</span>

</li>
<li>
<a href="./ems_ms_lf_sc.html#ems_ms_lf_sc">Steady Currents</a><span class="headline-id">ems.ms.lf.sc</span>

</li>

</ul>
</details>
</li>
<li>
<a href="./ems_ms_ce.html#ems_ms_ce">Charge Conservation and the Continuity Equation</a><span class="headline-id">ems.ms.ce</span>

</li>
<li>
<a href="./ems_ms_BS.html#ems_ms_BS">Steady Currents: the Biot-Savart Law</a><span class="headline-id">ems.ms.BS</span>

</li>
<li>

<details open="">
<summary class="toc-open">
<a href="./ems_ms_dcB.html#ems_ms_dcB">Divergence and Curl of \({\bf B}\)</a><span class="headline-id">ems.ms.dcB</span>


</summary>
<ul>
<li>
<a href="./ems_ms_dcB_iw.html#ems_ms_dcB_iw">Simplistic case: infinite wire</a><span class="headline-id">ems.ms.dcB.iw</span>

</li>
<li>
<a href="./ems_ms_dcB_d.html#ems_ms_dcB_d">Divergence of \({\bf B}\) from Biot-Savart</a><span class="headline-id">ems.ms.dcB.d</span>

</li>
<li class="toc-currentpage">
<a href="./ems_ms_dcB_c.html#ems_ms_dcB_c">Curl of \({\bf B}\) from Biot-Savart; Ampère's Law</a><span class="headline-id">ems.ms.dcB.c</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./ems_ms_vp.html#ems_ms_vp">The Vector Potential</a><span class="headline-id">ems.ms.vp</span>


</summary>
<ul>
<li>
<a href="./ems_ms_vp_A.html#ems_ms_vp_A">Definition; Gauge Choices</a><span class="headline-id">ems.ms.vp.A</span>

</li>
<li>
<a href="./ems_ms_vp_mbc.html#ems_ms_vp_mbc">Magnetic Boundary Conditions</a><span class="headline-id">ems.ms.vp.mbc</span>

</li>
<li>
<a href="./ems_ms_vp_me.html#ems_ms_vp_me">Multipole Expansion of the Vector Potential</a><span class="headline-id">ems.ms.vp.me</span>

</li>
<li>
<a href="./ems_ms_vp_comp.html#ems_ms_vp_comp">Comparison of Electrostatics and Magnetostatics</a><span class="headline-id">ems.ms.vp.comp</span>

</li>
<li>
<a href="./ems_ms_vp_LC.html#ems_ms_vp_LC">The Levi-Civita Symbol</a><span class="headline-id">ems.ms.vp.LC</span>

</li>

</ul>
</details>
</li>

</ul>
</details>
</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emsm.html#emsm">Electromagnetostatics in matter</a><span class="headline-id">emsm</span>


</summary>
<ul>
<li>

<details>
<summary>
<a href="./emsm_esm.html#emsm_esm">Electrostatics in matter</a><span class="headline-id">emsm.esm</span>


</summary>
<ul>
<li>

<details>
<summary>
<a href="./emsm_esm_mE.html#emsm_esm_mE">Matter Bathed in E Fields; Polarization</a><span class="headline-id">emsm.esm.mE</span>


</summary>
<ul>
<li>
<a href="./emsm_esm_mE_o.html#emsm_esm_mE_o">Overview</a><span class="headline-id">emsm.esm.mE.o</span>

</li>
<li>
<a href="./emsm_esm_mE_P.html#emsm_esm_mE_P">Polarization</a><span class="headline-id">emsm.esm.mE.P</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emsm_esm_po.html#emsm_esm_po">Polarized Objects; Bound Charges</a><span class="headline-id">emsm.esm.po</span>


</summary>
<ul>
<li>
<a href="./emsm_esm_po_pibc.html#emsm_esm_po_pibc">Physical Interpretation of Bound Charges</a><span class="headline-id">emsm.esm.po.pibc</span>

</li>
<li>
<a href="./emsm_esm_po_fid.html#emsm_esm_po_fid">The Field Inside a Dielectric</a><span class="headline-id">emsm.esm.po.fid</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emsm_esm_D.html#emsm_esm_D">The Electric Displacement</a><span class="headline-id">emsm.esm.D</span>


</summary>
<ul>
<li>
<a href="./emsm_esm_D_bc.html#emsm_esm_D_bc">Boundary Conditions</a><span class="headline-id">emsm.esm.D.bc</span>

</li>

</ul>
</details>
</li>
<li>
<a href="./emsm_esm_di.html#emsm_esm_di">Dielectrics</a><span class="headline-id">emsm.esm.di</span>

</li>
<li>

<details>
<summary>
<a href="./emsm_esm_ld.html#emsm_esm_ld">Linear Dielectrics</a><span class="headline-id">emsm.esm.ld</span>


</summary>
<ul>
<li>
<a href="./emsm_esm_ld_sp.html#emsm_esm_ld_sp">Susceptibility, Permittivity, Dielectric Constant</a><span class="headline-id">emsm.esm.ld.sp</span>

</li>
<li>
<a href="./emsm_esm_ld_bvp.html#emsm_esm_ld_bvp">Boundary Value Problems with Linear Dielectrics</a><span class="headline-id">emsm.esm.ld.bvp</span>

</li>
<li>
<a href="./emsm_esm_ld_e.html#emsm_esm_ld_e">Energy in Dielectric Systems</a><span class="headline-id">emsm.esm.ld.e</span>

</li>
<li>
<a href="./emsm_esm_ld_f.html#emsm_esm_ld_f">Forces on Dielectrics</a><span class="headline-id">emsm.esm.ld.f</span>

</li>

</ul>
</details>
</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emsm_msm.html#emsm_msm">Magnetostatics in matter</a><span class="headline-id">emsm.msm</span>


</summary>
<ul>
<li>

<details>
<summary>
<a href="./emsm_msm_m.html#emsm_msm_m">Magnetization</a><span class="headline-id">emsm.msm.m</span>


</summary>
<ul>
<li>
<a href="./emsm_msm_m_dpf.html#emsm_msm_m_dpf">Diamagnetism, Paramagnetism, Ferromagnetism</a><span class="headline-id">emsm.msm.m.dpf</span>

</li>
<li>
<a href="./emsm_msm_m_fdi.html#emsm_msm_m_fdi">Torques and Forces on Magnetic Dipoles</a><span class="headline-id">emsm.msm.m.fdi</span>

</li>
<li>
<a href="./emsm_msm_a.html#emsm_msm_a">Effect of Magnetic Field on Atomic Orbits</a><span class="headline-id">emsm.msm.a</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emsm_msm_fmo.html#emsm_msm_fmo">The Field of a Magnetized Object</a><span class="headline-id">emsm.msm.fmo</span>


</summary>
<ul>
<li>
<a href="./emsm_msm_fmo_bc.html#emsm_msm_fmo_bc">Bound Currents</a><span class="headline-id">emsm.msm.fmo.bc</span>

</li>
<li>
<a href="./emsm_msm_fmo_pibc.html#emsm_msm_fmo_pibc">Physical Interpretation of Bound Currents</a><span class="headline-id">emsm.msm.fmo.pibc</span>

</li>
<li>
<a href="./emsm_msm_fmo_fim.html#emsm_msm_fmo_fim">The Magnetic Field Inside Matter</a><span class="headline-id">emsm.msm.fmo.fim</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emsm_msm_H.html#emsm_msm_H">The H Field</a><span class="headline-id">emsm.msm.H</span>


</summary>
<ul>
<li>
<a href="./emsm_msm_H_A.html#emsm_msm_H_A">Ampère's Law in Magnetized Materials</a><span class="headline-id">emsm.msm.H.A</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emsm_msm_lnlm.html#emsm_msm_lnlm">Linear and Nonlinear Media</a><span class="headline-id">emsm.msm.lnlm</span>


</summary>
<ul>
<li>
<a href="./emsm_msm_lnlm_sp.html#emsm_msm_lnlm_sp">Magnetic Susceptibility and Permeability</a><span class="headline-id">emsm.msm.lnlm.sp</span>

</li>
<li>
<a href="./emsm_msm_lnlm_fm.html#emsm_msm_lnlm_fm">Ferromagnetism</a><span class="headline-id">emsm.msm.lnlm.fm</span>

</li>

</ul>
</details>
</li>

</ul>
</details>
</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emd.html#emd">Electromagnetodynamics</a><span class="headline-id">emd</span>


</summary>
<ul>
<li>

<details>
<summary>
<a href="./emd_Fl.html#emd_Fl">Induction: Faraday's Law</a><span class="headline-id">emd.Fl</span>


</summary>
<ul>
<li>
<a href="./emd_Fl_Fl.html#emd_Fl_Fl">Faraday's Law</a><span class="headline-id">emd.Fl.Fl</span>

</li>
<li>
<a href="./emd_Fl_ief.html#emd_Fl_ief">The Induced Electric Field</a><span class="headline-id">emd.Fl.ief</span>

</li>
<li>
<a href="./emd_Fl_i.html#emd_Fl_i">Inductance</a><span class="headline-id">emd.Fl.i</span>

</li>
<li>
<a href="./emd_Fl_e.html#emd_Fl_e">Energy in Magnetic Fields</a><span class="headline-id">emd.Fl.e</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emd_Me.html#emd_Me">Maxwell's Equations</a><span class="headline-id">emd.Me</span>


</summary>
<ul>
<li>
<a href="./emd_Me_ebM.html#emd_Me_ebM">Electrodynamics Before Maxwell</a><span class="headline-id">emd.Me.ebM</span>

</li>
<li>
<a href="./emd_Me_dc.html#emd_Me_dc">Maxwell's Correction to Ampère's Law; the Displacement Current</a><span class="headline-id">emd.Me.dc</span>

</li>
<li>
<a href="./emd_Me_Me.html#emd_Me_Me">Maxwell's Equations</a><span class="headline-id">emd.Me.Me</span>

</li>
<li>
<a href="./emd_Me_mc.html#emd_Me_mc">Magnetic Charge</a><span class="headline-id">emd.Me.mc</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emd_ce.html#emd_ce">Charge and Energy Flows</a><span class="headline-id">emd.ce</span>


</summary>
<ul>
<li>
<a href="./emd_ce_ce.html#emd_ce_ce">The Continuity Equation</a><span class="headline-id">emd.ce.ce</span>

</li>
<li>
<a href="./emd_ce_poy.html#emd_ce_poy">Poynting's Theorem; the Poynting Vector</a><span class="headline-id">emd.ce.poy</span>

</li>
<li>
<a href="./emd_ce_mst.html#emd_ce_mst">Maxwell's Stress Tensor</a><span class="headline-id">emd.ce.mst</span>

</li>
<li>
<a href="./emd_ce_mom.html#emd_ce_mom">Momentum</a><span class="headline-id">emd.ce.mom</span>

</li>
<li>
<a href="./emd_ce_amom.html#emd_ce_amom">Angular Momentum</a><span class="headline-id">emd.ce.amom</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emd_emw.html#emd_emw">Electromagnetic waves in vacuum</a><span class="headline-id">emd.emw</span>


</summary>
<ul>
<li>
<a href="./emd_emw_we.html#emd_emw_we">The Wave Equation</a><span class="headline-id">emd.emw.we</span>

</li>
<li>
<a href="./emd_emw_mpw.html#emd_emw_mpw">Monochromatic Plane Waves</a><span class="headline-id">emd.emw.mpw</span>

</li>
<li>
<a href="./emd_emw_ep.html#emd_emw_ep">Energy and Momentum</a><span class="headline-id">emd.emw.ep</span>

</li>

</ul>
</details>
</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emdm.html#emdm">Electromagnetodynamics in Matter</a><span class="headline-id">emdm</span>


</summary>
<ul>
<li>

<details>
<summary>
<a href="./emdm_Me.html#emdm_Me">Maxwell's Equations in Matter</a><span class="headline-id">emdm.Me</span>


</summary>
<ul>
<li>
<a href="./emdm_Me_Mem.html#emdm_Me_Mem">Maxwell's Equations in Matter</a><span class="headline-id">emdm.Me.Mem</span>

</li>
<li>
<a href="./emdm_Me_bc.html#emdm_Me_bc">Boundary Conditions</a><span class="headline-id">emdm.Me.bc</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emdm_emwm.html#emdm_emwm">Electromagnetic Waves in Matter</a><span class="headline-id">emdm.emwm</span>


</summary>
<ul>
<li>
<a href="./emdm_emwm_plm.html#emdm_emwm_plm">Propagation in Linear Media</a><span class="headline-id">emdm.emwm.plm</span>

</li>
<li>
<a href="./emdm_emwm_refr.html#emdm_emwm_refr">Refraction</a><span class="headline-id">emdm.emwm.refr</span>

</li>
<li>

<details>
<summary>
<a href="./emdm_emwm_refl.html#emdm_emwm_refl">Reflection and Transmission</a><span class="headline-id">emdm.emwm.refl</span>


</summary>
<ul>
<li>
<a href="./emdm_emwm_refl_ni.html#emdm_emwm_refl_ni">Normal Incidence</a><span class="headline-id">emdm.emwm.refl.ni</span>

</li>
<li>
<a href="./emdm_emwm_refl_oi.html#emdm_emwm_refl_oi">Oblique Incidence</a><span class="headline-id">emdm.emwm.refl.oi</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emdm_emwm_ad.html#emdm_emwm_ad">Absorption and Dispersion</a><span class="headline-id">emdm.emwm.ad</span>


</summary>
<ul>
<li>
<a href="./emdm_emwm_ad_c.html#emdm_emwm_ad_c">EM Waves in Conductors</a><span class="headline-id">emdm.emwm.ad.c</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emdm_emwm_wg.html#emdm_emwm_wg">Waveguides</a><span class="headline-id">emdm.emwm.wg</span>


</summary>
<ul>
<li>
<a href="./emdm_emwm_wg_gw.html#emdm_emwm_wg_gw">Guided waves</a><span class="headline-id">emdm.emwm.wg.gw</span>

</li>
<li>
<a href="./emdm_emwm_wg_r.html#emdm_emwm_wg_r">Rectangular Waveguides</a><span class="headline-id">emdm.emwm.wg.r</span>

</li>
<li>
<a href="./emdm_emwm_wg_c.html#emdm_emwm_wg_c">Coaxial Lines</a><span class="headline-id">emdm.emwm.wg.c</span>

</li>

</ul>
</details>
</li>

</ul>
</details>
</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./emf.html#emf">Electromagnetic Fields</a><span class="headline-id">emf</span>


</summary>
<ul>
<li>
<a href="./emf_svp.html#emf_svp">Scalar and Vector Potentials</a><span class="headline-id">emf.svp</span>

</li>
<li>

<details>
<summary>
<a href="./emf_g.html#emf_g">Gauge Freedom and Choices</a><span class="headline-id">emf.g</span>


</summary>
<ul>
<li>
<a href="./emf_g_Cg.html#emf_g_Cg">Coulomb Gauge</a><span class="headline-id">emf.g.Cg</span>

</li>
<li>
<a href="./emf_g_Lg.html#emf_g_Lg">Lorenz Gauge; d'Alembertian; Inhomogeneous Maxwell Equations</a><span class="headline-id">emf.g.Lg</span>

</li>

</ul>
</details>
</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./red.html#red">Relativistic Electrodynamics</a><span class="headline-id">red</span>


</summary>
<ul>
<li>

<details>
<summary>
<a href="./red_sr.html#red_sr">Special Relativity</a><span class="headline-id">red.sr</span>


</summary>
<ul>
<li>
<a href="./red_sr_p.html#red_sr_p">Postulates and their consequences</a><span class="headline-id">red.sr.p</span>

</li>
<li>
<a href="./red_sr_Lt.html#red_sr_Lt">Lorentz Transformations</a><span class="headline-id">red.sr.Lt</span>

</li>
<li>
<a href="./red_sr_4v.html#red_sr_4v">Covariant and Contravariant Four-Vectors</a><span class="headline-id">red.sr.4v</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./red_rm.html#red_rm">Relativistic Mechanics</a><span class="headline-id">red.rm</span>


</summary>
<ul>
<li>
<a href="./red_rm_pt.html#red_rm_pt">Proper Time and Proper Velocity</a><span class="headline-id">red.rm.pt</span>

</li>
<li>
<a href="./red_rm_rme.html#red_rm_rme">Relativistic Momentum and Energy</a><span class="headline-id">red.rm.rme</span>

</li>
<li>
<a href="./red_rm_Mf.html#red_rm_Mf">Relativistic version of Newton's Laws; the Minkowski Force</a><span class="headline-id">red.rm.Mf</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./red_rem.html#red_rem">Relativistic Electromagnetism</a><span class="headline-id">red.rem</span>


</summary>
<ul>
<li>
<a href="./red_rem_mre.html#red_rem_mre">Magnetism as a Relativistic Effect</a><span class="headline-id">red.rem.mre</span>

</li>
<li>
<a href="./red_rem_Ltf.html#red_rem_Ltf">Lorentz Transformation of Electromagnetic Fields</a><span class="headline-id">red.rem.Ltf</span>

</li>
<li>
<a href="./red_rem_Fmunu.html#red_rem_Fmunu">The Field Tensor</a><span class="headline-id">red.rem.Fmunu</span>

</li>
<li>
<a href="./red_rem_Me.html#red_rem_Me">Maxwell's Equations in Relativistic Notation</a><span class="headline-id">red.rem.Me</span>

</li>

</ul>
</details>
</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./qed.html#qed">Quantum Electrodynamics</a><span class="headline-id">qed</span>


</summary>
<ul>
<li>
<a href="./qed_L.html#qed_L">Lagrangian</a><span class="headline-id">qed.L</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./d.html#d">Diagnostics</a><span class="headline-id">d</span>


</summary>
<ul>
<li>
<a href="./d_ems.html#d_ems">Diagnostics: Electromagnetostatics</a><span class="headline-id">d.ems</span>

</li>
<li>
<a href="./d_ems_ca.html#d_ems_ca">Diagnostics: Calculating or Approximating the Electostatic Potential</a><span class="headline-id">d.ems.ca</span>

</li>
<li>
<a href="./d_emsm.html#d_emsm">Diagnostics: Electromagnetostatics in Matter</a><span class="headline-id">d.emsm</span>

</li>
<li>
<a href="./d_ems_ms.html#d_ems_ms">Diagnostics: Magnetostatics</a><span class="headline-id">d.ems.ms</span>

</li>
<li>
<a href="./d_emsm_msm.html#d_emsm_msm">Diagnostics: Magnetostatics in Matter</a><span class="headline-id">d.emsm.msm</span>

</li>
<li>
<a href="./d_emd.html#d_emd">Diagnostics: Electromagnetodynamics</a><span class="headline-id">d.emd</span>

</li>
<li>
<a href="./d_emd_ce.html#d_emd_ce">Diagnostics: Conservation Laws</a><span class="headline-id">d.emd.ce</span>

</li>
<li>
<a href="./d_emd_emw.html#d_emd_emw">Diagnostics: Electromagnetic Waves</a><span class="headline-id">d.emd.emw</span>

</li>
<li>
<a href="./d_emf.html#d_emf">Diagnostics: Potentials, Gauges and Fields</a><span class="headline-id">d.emf</span>

</li>
<li>
<a href="./d_red.html#d_red">Diagnostics: Relativistic Electrodynamics</a><span class="headline-id">d.red</span>

</li>
<li>
<a href="./d_m.html#d_m">Diagnostics: Compendium - Mathematics</a><span class="headline-id">d.m</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./a.html#a">Appendices</a><span class="headline-id">a</span>


</summary>
<ul>
<li>
<a href="./a_l.html#a_l">Literature</a><span class="headline-id">a.l</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./c.html#c">Compendium</a><span class="headline-id">c</span>


</summary>
<ul>
<li>

<details>
<summary>
<a href="./c_m.html#c_m">Mathematics</a><span class="headline-id">c.m</span>


</summary>
<ul>
<li>

<details>
<summary>
<a href="./c_m_va.html#c_m_va">Vector Analysis</a><span class="headline-id">c.m.va</span>


</summary>
<ul>
<li>
<a href="./c_m_va_n.html#c_m_va_n">Notation and algebraic properties</a><span class="headline-id">c.m.va.n</span>

</li>
<li>
<a href="./c_m_va_sp.html#c_m_va_sp">Scalar product</a><span class="headline-id">c.m.va.sp</span>

</li>
<li>
<a href="./c_m_va_cp.html#c_m_va_cp">Cross product</a><span class="headline-id">c.m.va.cp</span>

</li>
<li>
<a href="./c_m_va_tp.html#c_m_va_tp">Triple Products</a><span class="headline-id">c.m.va.tp</span>

</li>
<li>
<a href="./c_m_va_pds.html#c_m_va_pds">Position, Displacement and Separation Vectors</a><span class="headline-id">c.m.va.pds</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./c_m_dc.html#c_m_dc">Differential Calculus</a><span class="headline-id">c.m.dc</span>


</summary>
<ul>
<li>
<a href="./c_m_dc_g.html#c_m_dc_g">Gradient</a><span class="headline-id">c.m.dc.g</span>

</li>
<li>
<a href="./c_m_dc_del.html#c_m_dc_del">The \({\boldsymbol \nabla}\) Operator</a><span class="headline-id">c.m.dc.del</span>

</li>
<li>
<a href="./c_m_dc_div.html#c_m_dc_div">The Divergence</a><span class="headline-id">c.m.dc.div</span>

</li>
<li>
<a href="./c_m_dc_curl.html#c_m_dc_curl">The Curl</a><span class="headline-id">c.m.dc.curl</span>

</li>
<li>
<a href="./c_m_dc_pr.html#c_m_dc_pr">Product arguments</a><span class="headline-id">c.m.dc.pr</span>

</li>
<li>
<a href="./c_m_dc_d2.html#c_m_dc_d2">Second Derivatives</a><span class="headline-id">c.m.dc.d2</span>

</li>

</ul>
</details>
</li>
<li>

<details>
<summary>
<a href="./c_m_ic.html#c_m_ic">Integral Calculus</a><span class="headline-id">c.m.ic</span>


</summary>
<ul>
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<ul class="breadcrumbs"><li><a class="breadcrumb-link"href="ems.html">Electromagnetostatics</a></li><li><a class="breadcrumb-link"href="ems_ms.html">Magnetostatics</a></li><li><a class="breadcrumb-link"href="ems_ms_dcB.html">Divergence and Curl of \({\bf B}\)</a></li><li>Curl of \({\bf B}\) from Biot-Savart; Ampère's Law</li></ul><ul class="navigation-links"><li>Prev:&nbsp;<a href="ems_ms_dcB_d.html">Divergence of \({\bf B}\) from Biot-Savart&emsp;<small>[ems.ms.dcB.d]</small></a></li><li>Next:&nbsp;<a href="ems_ms_vp.html">The Vector Potential&emsp;<small>[ems.ms.vp]</small></a></li><li>Up:&nbsp;<a href="ems_ms_dcB.html">Divergence and Curl of \({\bf B}\)&emsp;<small>[ems.ms.dcB]</small></a></li></ul><div id="outline-container-ems_ms_dcB_c" class="outline-5">
<h5 id="ems_ms_dcB_c">Curl of \({\bf B}\) from Biot-Savart; Ampère's Law<a class="headline-permalink" href="./ems_ms_dcB_c.html#ems_ms_dcB_c"><svg xmlns="http://www.w3.org/2000/svg" width="16" height="16" fill="currentColor" class="bi bi-link" viewBox="0 0 16 16">
  <path d="M6.354 5.5H4a3 3 0 0 0 0 6h3a3 3 0 0 0 2.83-4H9c-.086 0-.17.01-.25.031A2 2 0 0 1 7 10.5H4a2 2 0 1 1 0-4h1.535c.218-.376.495-.714.82-1z"/>
  <path d="M9 5.5a3 3 0 0 0-2.83 4h1.098A2 2 0 0 1 9 6.5h3a2 2 0 1 1 0 4h-1.535a4.02 4.02 0 0 1-.82 1H12a3 3 0 1 0 0-6H9z"/>
</svg></a><span class="headline-id">ems.ms.dcB.c</span></h5>
<div class="outline-text-5" id="text-ems_ms_dcB_c">
<p>
We can play the same trick with the curl:
\[
{\boldsymbol \nabla} \times {\bf B} ({\bf r}) = \frac{\mu_0}{4\pi} \int_{\cal V} d\tau' ~{\boldsymbol \nabla} \times
\left(\frac{{\bf J}({\bf r}') \times ({\bf r} - {\bf r}')}{|{\bf r} - {\bf r}'|^3} \right)
\label{Gr(5.49)}
\]
Do as above but now use product rule <a href="./c_m_dc_pr.html#curl_xprod">curl_xprod</a>
and (dropping terms involving derivatives of \({\bf J}({\bf r}')\) with respect to \({\bf r}\),
which vanish):
</p>

\begin{align}
{\boldsymbol \nabla} \times \left(\frac{{\bf J}({\bf r}') \times ({\bf r} - {\bf r}')}{|{\bf r} - {\bf r}'|^3} \right)
&amp;= -{\boldsymbol \nabla} \times \left( {\bf J}({\bf r}') \times {\boldsymbol \nabla} \frac{1}{|{\bf r} - {\bf r}'|} \right) \nonumber \\
&amp;=
-{\bf J} ({\bf r}') \left({\boldsymbol \nabla} \cdot {\boldsymbol \nabla} \frac{1}{|{\bf r} - {\bf r}'|}\right)
+ ({\bf J} ({\bf r}') \cdot {\boldsymbol \nabla}) {\boldsymbol \nabla} \frac{1}{|{\bf r} - {\bf r}'|}
\end{align}
<p>
The first term can be reworked into
\[
-{\bf J} ({\bf r}') \left({\boldsymbol \nabla} \cdot {\boldsymbol \nabla} \frac{1}{|{\bf r} - {\bf r}'|}\right)
= -{\bf J} ({\bf r}') \left({\boldsymbol \nabla}^2 \frac{1}{|{\bf r} - {\bf r}'|}\right) =  -{\bf J} ({\bf r}') \left(-4\pi \delta^{(3)} ({\bf r} - {\bf r}') \right)
\label{Gr(5.51)}
\]
where we have used <a href="./c_m_dd_3d.html#Lap1or">Lap1or</a>. Back in Biot-Savart, this term thus integrates to
\[
\frac{\mu_0}{4\pi} \int_{\cal V} d\tau' {\bf J} ({\bf r}') 4\pi \delta^{(3)} ({\bf r} - {\bf r}') = \mu_0 {\bf J}({\bf r}).
\]
To treat the other term, we use that for a symmetric function of \({\bf r} - {\bf r}'\),
changing from \(\nabla\) to \(\nabla'\) simply changes the sign, <i>i.e.</i>
\[
({\bf J} ({\bf r}') \cdot {\boldsymbol \nabla}) {\boldsymbol \nabla} \frac{1}{|{\bf r} - {\bf r}'|}
= -({\bf J} ({\bf r}') \cdot {\boldsymbol \nabla}') {\boldsymbol \nabla} \frac{1}{|{\bf r} - {\bf r}'|}
\]
This allows us to rewrite the second part of the integral as
\[
-\frac{\mu_0}{4\pi} {\boldsymbol \nabla} \int_{\cal V} d\tau' ({\bf J} ({\bf r}') \cdot {\boldsymbol \nabla}') \frac{1}{|{\bf r} - {\bf r}'|}
= \frac{\mu_0}{4\pi} {\boldsymbol \nabla} \int_{\cal V} d\tau' \frac{{\boldsymbol \nabla}' \cdot {\bf J} ({\bf r}')}{|{\bf r} - {\bf r}'|}
= 0
\]
where in the second step we have used integration by parts using product rule <a href="./c_m_dc_pr.html#div_prod">div_prod</a>
(the surface term vanishes because we take \({\bf J} \rightarrow 0\)
at infinity), and in the third step we have used the assumption of steady-state so \({\boldsymbol \nabla}' \cdot {\bf J} = 0\).
</p>

<p>
We thus obtain
</p>
<div class="core div" id="orgea4bf7e">
<p>
<b>Ampère's law</b>
</p>
<div class="eqlabel" id="orgd432700">
<p>
<a id="Amp"></a><a href="./ems_ms_dcB_c.html#Amp"><svg xmlns="http://www.w3.org/2000/svg" width="16" height="16" fill="currentColor" class="bi bi-link" viewBox="0 0 16 16">
  <path d="M6.354 5.5H4a3 3 0 0 0 0 6h3a3 3 0 0 0 2.83-4H9c-.086 0-.17.01-.25.031A2 2 0 0 1 7 10.5H4a2 2 0 1 1 0-4h1.535c.218-.376.495-.714.82-1z"/>
  <path d="M9 5.5a3 3 0 0 0-2.83 4h1.098A2 2 0 0 1 9 6.5h3a2 2 0 1 1 0 4h-1.535a4.02 4.02 0 0 1-.82 1H12a3 3 0 1 0 0-6H9z"/>
</svg></a>
</p>
<div class="alteqlabels" id="org1527214">
<ul class="org-ul">
<li>FLS II (13.13)</li>
<li>Gr (5.56)</li>
<li>W (15-12)</li>
</ul>

</div>

</div>
<p>
\[
{\boldsymbol \nabla} \times {\bf B} = \mu_0 {\bf J}
\tag{Amp}\label{Amp}
\]
</p>

</div>
<p>
(in differential form).  Using Stokes' theorem,
\[
\int_{\cal S} d{\bf a} \cdot {\boldsymbol \nabla} \times {\bf B} = \oint_{\cal P} d{\bf l} \cdot {\bf B} = \mu_0 \int_{\cal S} d{\bf a} \cdot {\bf J}
\]
yielding
</p>
<div class="core div" id="org47c2e9c">
<p>
<b>Ampère's law (integral form)</b>
</p>
<div class="eqlabel" id="org7d03160">
<p>
<a id="Amp_int"></a><a href="./ems_ms_dcB_c.html#Amp_int"><svg xmlns="http://www.w3.org/2000/svg" width="16" height="16" fill="currentColor" class="bi bi-link" viewBox="0 0 16 16">
  <path d="M6.354 5.5H4a3 3 0 0 0 0 6h3a3 3 0 0 0 2.83-4H9c-.086 0-.17.01-.25.031A2 2 0 0 1 7 10.5H4a2 2 0 1 1 0-4h1.535c.218-.376.495-.714.82-1z"/>
  <path d="M9 5.5a3 3 0 0 0-2.83 4h1.098A2 2 0 0 1 9 6.5h3a2 2 0 1 1 0 4h-1.535a4.02 4.02 0 0 1-.82 1H12a3 3 0 1 0 0-6H9z"/>
</svg></a>
</p>
<div class="alteqlabels" id="org7df7f43">
<ul class="org-ul">
<li>FLS II (13.16)</li>
<li>Gr (5.57)</li>
<li>PM (6.25)</li>
</ul>

</div>

</div>
<p>
\[
\oint_{\cal P} d{\bf l} \cdot {\bf B} = \mu_0 I_{enc} \hspace{2cm}
I_{enc} = \int_{\cal S} d{\bf a} \cdot {\bf J}.
\label{Gr(5.55)}
\]
</p>

</div>
<p>
where \(I_{enc}\) is the current enclosed in the <b>amperian loop</b> \({\cal P}\) which defines the boundary of surface \({\cal S}\).
</p>

<p>
Sign ambiguity:  resolved by right-hand rule as usual.
</p>

<p>
Ampère's law in magnetostatics takes a parallel role to Gauss's law in electrostatics.
</p>

<div class="example div" id="orgb588a5a">
<p>
<b>Example: infinite wire</b>
</p>

<p>
Same as direct integration we did before, but let's now use Ampère.
</p>

<p>
<b>Solution</b>:  by symmetry, \({\bf B}\) is circumferential and can only depend on \(r\).  Then,
choosing an amperian loop at a fixed radius \(r\), we get
\[
\oint d{\bf l} \cdot {\bf B} = B 2\pi s = \mu_0 I ~~\Rightarrow~~ B = \frac{\mu_0 I}{2\pi r}
\]
</p>

</div>

<div class="example div" id="orgdd3bf23">
<p>
<b>Example: uniform sheet current</b>
</p>

<p>
Consider an infinite sheet with uniform surface current \({\bf K} = K \hat{\bf x}\) flowing in \(xy\) plane.
</p>

<p>
<b>Task</b>: calculate \({\bf B}\).
</p>

<p>
<b>Solution</b>: from Biot-Savart <a href="./ems_ms_BS.html#BiotSavart_s">BiotSavart_s</a>,  \({\bf B}\) must be perpendicular to \({\bf K}\).
Intuition: \({\bf B}\) cannot have a component along \(\hat{\bf z}\).
Right-hand rule:  \({\bf B}\) along \(-\hat{\bf y}\) for \(z &gt; 0\),
and along \(\hat{\bf y}\) for \(z &lt; 0\).  Amperian loop of width \(l\) punching through surface:
\[
\oint {\bf B} \cdot d{\bf l} = 2B l = \mu_0 I_{enc} = \mu_0 K l
~~\Rightarrow~~
{\bf B} = \left\{ \begin{array}{cc} \frac{\mu_0}{2} K \hat{\bf y}, &amp; z &lt; 0, \\
-\frac{\mu_0}{2} K \hat{\bf y}, &amp; z &gt; 0. \end{array} \right.
\label{Gr(5.56)}
\]
</p>

</div>

<div class="example div" id="org620aee8">
<p>
<b>Example: solenoid</b>
</p>

<p>
Consider an infinite solenoid along \(\hat{\bf z}\), made of a wire carrying current \(I\)
doing \(n\) turns per unit length on a cylinder of radius \(R\).
</p>

<p>
<b>Task</b>: calculate \({\bf B}\).
</p>

<p>
<b>Solution</b>:  by symmetry, \({\bf B}\) must be along axis of solenoid.
Outside:  infinitely far away, \({\bf B}\) must vanish.
But an amperian loop outside gives zero always, so \({\bf B}\) vanishes everywhere outside the solenoid.
Amperian loop of length \(l\), half-inside and half-outside:
</p>
<div class="eqlabel" id="orgb28c666">
<p>
<a id="Bsol"></a><a href="./ems_ms_dcB_c.html#Bsol"><svg xmlns="http://www.w3.org/2000/svg" width="16" height="16" fill="currentColor" class="bi bi-link" viewBox="0 0 16 16">
  <path d="M6.354 5.5H4a3 3 0 0 0 0 6h3a3 3 0 0 0 2.83-4H9c-.086 0-.17.01-.25.031A2 2 0 0 1 7 10.5H4a2 2 0 1 1 0-4h1.535c.218-.376.495-.714.82-1z"/>
  <path d="M9 5.5a3 3 0 0 0-2.83 4h1.098A2 2 0 0 1 9 6.5h3a2 2 0 1 1 0 4h-1.535a4.02 4.02 0 0 1-.82 1H12a3 3 0 1 0 0-6H9z"/>
</svg></a>
</p>
<div class="alteqlabels" id="orga2e2f32">
<ul class="org-ul">
<li>Gr (5.59)</li>
</ul>

</div>

</div>
<p>
\[
\oint d{\bf l} \cdot {\bf B} = Bl = \mu_0 I_{enc} = \mu_0 I n l ~~\Rightarrow~~
{\bf B} = \left\{ \begin{array}{cc} \mu_0 I n ~\hat{\bf z}, &amp; r &lt; R, \\
0, &amp; r &gt; R \end{array} \right.
\tag{Bsol}\label{Bsol}
\]
</p>

</div>

<p>
<b>N.B.</b>: the situations in which Ampère's law can be useful are those involving some
form of symmetry, for example
i) infinite straight lines, ii) infinite planes, iii) infinite solenoids, iv) toroids.
</p>

<div class="example div" id="org4328fb9">
<p>
<b>Example: toroidal coil</b>
</p>

<p>
Consider a toroidal coil
(it doesn't matter what the cross-sectional shape, as long as it is rotationally symmetric).
</p>

<p>
<b>Task</b>: calculate \({\bf B}\).
</p>

<p>
<b>Solution</b>: by rotational symmetry, the magnetic field is circumferential everywhere.
Outside the coil, the field must again be zero.
</p>

<p>
Consider now an Amperian loop which is just a circle at radius \(r\):
</p>
<div class="eqlabel" id="orgf18763d">
<p>
<a id="Btor"></a><a href="./ems_ms_dcB_c.html#Btor"><svg xmlns="http://www.w3.org/2000/svg" width="16" height="16" fill="currentColor" class="bi bi-link" viewBox="0 0 16 16">
  <path d="M6.354 5.5H4a3 3 0 0 0 0 6h3a3 3 0 0 0 2.83-4H9c-.086 0-.17.01-.25.031A2 2 0 0 1 7 10.5H4a2 2 0 1 1 0-4h1.535c.218-.376.495-.714.82-1z"/>
  <path d="M9 5.5a3 3 0 0 0-2.83 4h1.098A2 2 0 0 1 9 6.5h3a2 2 0 1 1 0 4h-1.535a4.02 4.02 0 0 1-.82 1H12a3 3 0 1 0 0-6H9z"/>
</svg></a>
</p>
<div class="alteqlabels" id="orgd921abb">
<ul class="org-ul">
<li>Gr (5.60)</li>
</ul>

</div>

</div>
<p>
\[
B 2\pi r = \mu_0 I_{enc} ~~\Rightarrow~~
{\bf B} = \left\{ \begin{array}{cc} \frac{\mu_0 N I}{2\pi r} \hat{\boldsymbol \varphi}, &amp; \mbox{inside coil}, \\
0, &amp; \mbox{outside} \end{array} \right.
\tag{Btor}\label{Btor}
\]
</p>

</div>
</div>
</div>


<br><ul class="navigation-links"><li>Prev:&nbsp;<a href="ems_ms_dcB_d.html">Divergence of \({\bf B}\) from Biot-Savart&emsp;<small>[ems.ms.dcB.d]</small></a></li><li>Next:&nbsp;<a href="ems_ms_vp.html">The Vector Potential&emsp;<small>[ems.ms.vp]</small></a></li><li>Up:&nbsp;<a href="ems_ms_dcB.html">Divergence and Curl of \({\bf B}\)&emsp;<small>[ems.ms.dcB]</small></a></li></ul>
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<div id="postamble" class="status">
<p class="author">Author: Jean-Sébastien Caux</p>
<p class="date">Created: 2022-03-24 Thu 08:42</p>
<p class="validation"></p>
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