<?xml version="1.0" encoding="UTF-8"?><!DOCTYPE article  PUBLIC "-//NLM//DTD Journal Publishing DTD v3.0 20080202//EN" "http://dtd.nlm.nih.gov/publishing/3.0/journalpublishing3.dtd"><article xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink" dtd-version="3.0" xml:lang="en" article-type="research article"><front><journal-meta><journal-id journal-id-type="publisher-id">JMP</journal-id><journal-title-group><journal-title>Journal of Modern Physics</journal-title></journal-title-group><issn pub-type="epub">2153-1196</issn><publisher><publisher-name>Scientific Research Publishing</publisher-name></publisher></journal-meta><article-meta><article-id pub-id-type="doi">10.4236/jmp.2011.211173</article-id><article-id pub-id-type="publisher-id">JMP-8648</article-id><article-categories><subj-group subj-group-type="heading"><subject>Articles</subject></subj-group><subj-group subj-group-type="Discipline-v2"><subject>Physics&amp;Mathematics</subject></subj-group></article-categories><title-group><article-title>
 
 
  A Loop Diagram Approach to the Nonlinear Optical Conductivity for an Electron-Phonon System
 
</article-title></title-group><contrib-group><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>am</surname><given-names>Lyong Kang</given-names></name></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Sang</surname><given-names>Don Choi</given-names></name><xref ref-type="corresp" rid="cor1"><sup>*</sup></xref></contrib></contrib-group><author-notes><corresp id="cor1">* E-mail:<email>sdchoi@knu.ac.kr(SDC)</email>;</corresp></author-notes><pub-date pub-type="epub"><day>10</day><month>11</month><year>2011</year></pub-date><volume>02</volume><issue>11</issue><fpage>1410</fpage><lpage>1414</lpage><history><date date-type="received"><day>September</day>	<month>7,</month>	<year>2011</year></date><date date-type="rev-recd"><day>October</day>	<month>22,</month>	<year>2011</year>	</date><date date-type="accepted"><day>October</day>	<month>30,</month>	<year>2011</year></date></history><permissions><copyright-statement>&#169; Copyright  2014 by authors and Scientific Research Publishing Inc. </copyright-statement><copyright-year>2014</copyright-year><license><license-p>This work is licensed under the Creative Commons Attribution International License (CC BY). http://creativecommons.org/licenses/by/4.0/</license-p></license></permissions><abstract><p>
 
 
  A loop diagram approach to the nonlinear optical conductivity of an electron-phonon system is introduced. This approach can be categorized as another Feynman-like scheme because all contributions to the self-energy terms can be grouped into topologically-distinct loop diagrams. The results for up to the first order nonlinear conductivity are identical to those derived using the KC reduction identity (KCRI) and the state- dependent projection operator (SDPO) introduced by the present authors. The result satisfies the “population criterion” in that the population of electrons and phonons appear independently or the Fermi distributions are multiplied by the Planck distributions in the formalism. Therefore it is possible, in an organized manner, to present the phonon emissions and absorptions as well as photon absorptions in all electron transition processes. In additions, the calculation needed to obtain the line shape function appearing in the energy denominator of the conductivity can be reduced using this diagram method. This method shall be called the “KC loop diagram method”, since it originates from proper application of KCRI’s and SDPO’s.
 
</p></abstract><kwd-group><kwd>Optical Conductivity</kwd><kwd> Projection Operator</kwd><kwd> KC Reduction Identity</kwd><kwd> Electron-Phononinteraction</kwd></kwd-group></article-meta></front><body><sec id="s1"><title>1. Introduction</title><p>Studies of the optical transitions in electron systems are powerful for examining the electronic structure of solids, because the absorption lineshapes are quite sensitive to the type of scattering mechanism affecting the transport of electrons and to the interaction of electrons with intense laser light. A general method for gaining knowledge on the dynamics of a system is a perturbation-based study. This consists of dividing the Hamiltonian into an exactly soluble part and a nontrivial perturbativepart, the effect of which is studied in order. The most popular method for representing the terms in perturbative expressions is Feynman diagram. This diagrammatic method can be used directly for reasoning and problem solving as well as for representing the perturbative expressions by drawings. The easily recognizable topology of the diagrams makes the diagrammatic method a powerful tool for constructing approximation schemes. Furthermore, the diagrammatic representation can be a suggestive tool providing physical intuition to quantum dynamics by increasing the diagrams to a representation method for possible alternative physical processes.</p><p>On the other hand, the method, although invented originally for particle physics, has been adopted in solid-state physics, where the behavior of phonons may be expressed in analogy to that of photons, e.g. in the theory of superconductivity. An electron traveling in a solid distorts the lattice due to the Coulomb interactions with the ions. The lattice distortion in turn has a feedback on the electron dynamics, resulting in an increase in the electron mass and a shortening of the electron lifetime in a particular quasi-particle state. This effect is described in terms of the self-energy that the electron acquires due to the electron-phonon interaction. The real part of selfenergy describes the change in electron energy, and the imaginary part provides information on the electron lifetime. The electron self-energy can be calculated using the standard Feynman diagram.</p><p>The standard diagram method can represent the trajectories of particles well in the intermediate states of the scattering processes. However, in the line shape (or selfenergy) function for electron-phonon system, the Fermi distribution functions for electrons and the Planck distribution functions for phonons are simply added [1-7], which violates the “population criterion” in that the population of electrons (fermions) and phonons (bosons) appear independently. In other words, a theory can be said to be proper if the Fermi distributions are multiplied by the Planck distributions in the formalism.</p><p>The present authors have developed some projection methods for the optical transitionsin electron-phonon systems and used them to calculate the linewidths in semiconductors [8,9]. Normally, the resolvent factor contained in the conductivity tensor is expanded using projectors, and various formulae can be obtained. Recently, the formalism was improved with the inclusion of nonlinear terms near the resonance points and suggested a meaningful result including the Fermi and Planck distribution functions properly with the proper use of the SDPO and KCRI [10-13]. This paper introduces a method for the nonlinear optical conductivity and line shape functions to represent them in loop diagrams. It can be categorized as another Feynman-like scheme because all the contributions to the line shape functions (or self-energy terms) can be grouped into topologicallydistinct diagrams.</p><p>The diagram approach to the nonlinear phenomena is based on the following methods.</p></sec><sec id="s2"><title>2. Methods</title><p>For diagrammatic representation of the line shape functions, <img src="21-7500528\5859ef55-fdec-41ec-b28d-a436c0cd53b7.jpg" />, we consider the form</p><disp-formula id="scirp.8648-formula69885"><label>(1)</label><graphic position="anchor" xlink:href="21-7500528\851422f3-049c-4421-bf59-3a70c85456af.jpg"  xlink:type="simple"/></disp-formula><p>where<img src="21-7500528\b1747e0e-3166-4d86-b88f-7dd8daa4b6e2.jpg" />.</p><p>1) Let an implicit state <img src="21-7500528\6052d516-24b4-4dcd-85e3-42da3949af93.jpg" /> exist between state <img src="21-7500528\1c8c8878-ca00-4e38-b460-aba12a7f2da3.jpg" /> andstate<img src="21-7500528\f66dbd27-23bd-4ff7-8478-9984ff142f53.jpg" />.</p><p>2) There is a diagram (<xref ref-type="fig" rid="fig1">Figure 1</xref>) connecting the initial state <img src="21-7500528\8b9eca18-81cc-4bf3-9597-b2d1715e0825.jpg" /> to the implicit state <img src="21-7500528\42612166-94e1-4e5d-a745-255f7ddf91b2.jpg" /> with a dotted line and connecting the implicit state <img src="21-7500528\ffee97ba-2b78-44f1-80d3-82c2ad4a30bc.jpg" /> to a state <img src="21-7500528\732a4183-9055-4c50-9320-13b6e9df5bfe.jpg" /> with aclockwise loop. The dotted line and the clockwise loop correspond to <img src="21-7500528\dde7ef11-fdd2-4381-a010-0a97a24a089a.jpg" /> and<img src="21-7500528\d4d15b30-5635-4965-a6b4-71ea8f192196.jpg" />, respectively.</p><p>Here <img src="21-7500528\4278fd7b-5fb8-4feb-8abd-8e7ca74403a5.jpg" /> called the C-factor and <img src="21-7500528\78c614a0-599b-4523-ac36-ce5da20d217a.jpg" /> called the P-factor are defined as follows:</p><disp-formula id="scirp.8648-formula69886"><label>(2)</label><graphic position="anchor" xlink:href="21-7500528\099e409d-2ff0-4917-bdb8-d964c4f73825.jpg"  xlink:type="simple"/></disp-formula><disp-formula id="scirp.8648-formula69887"><label>(3)</label><graphic position="anchor" xlink:href="21-7500528\3af1ff08-6ece-4b46-a927-92760ec7d3d7.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="21-7500528\d5e8f755-d73d-48a5-8152-5e43160a4a42.jpg" /> is the coupling factor that depends on the mode of the phonons and <img src="21-7500528\646e48a1-5b73-4e8d-81cb-002600cfcaf5.jpg" /> is the Planck distribution function for phonons. <img src="21-7500528\32de7306-aeb2-4bce-afb6-6f2a3b0fc20a.jpg" />means that the state <img src="21-7500528\3b791296-5545-4531-b04d-2662d3f6048a.jpg" /> is coupled with the state <img src="21-7500528\c109c12f-cfba-49a5-89e2-c3f82333806e.jpg" /> by a phonon with wave vector q and <img src="21-7500528\3e7aea96-def2-40b9-968f-5c5ecae60e22.jpg" /> means an electron transition from a state <img src="21-7500528\c4b97e04-e42c-4720-923b-2baa2435257f.jpg" />(distribution function:<img src="21-7500528\a4a45bc7-8d76-4c43-bb30-7ff6fdcdcb12.jpg" />) to a state <img src="21-7500528\e07a1c60-f032-48eb-89a9-2a18aff2eb6a.jpg" /> (distribution function:<img src="21-7500528\bc7cebee-45b9-45f7-82ba-f7ccb09d53d9.jpg" />) with a phonon emission (distribution function:<img src="21-7500528\f0d400ad-29b4-466c-ae1b-68ac8ed03e8e.jpg" />) minus a transition from a state <img src="21-7500528\9fe7a957-0859-401b-9fdc-b7047b9eb624.jpg" /> to a state <img src="21-7500528\e18f2e6f-e72c-44d6-84cb-08b84f827428.jpg" /> with a phonon absorption<img src="21-7500528\669f5bed-2560-4e42-9e8a-e13db07f12aa.jpg" />. There is an another diagram connecting with a counterclockwise loop, <img src="21-7500528\a115d510-415b-4eb3-bf76-9239d7858fed.jpg" />, which is defined</p><disp-formula id="scirp.8648-formula69888"><label>(4)</label><graphic position="anchor" xlink:href="21-7500528\a21acade-6eec-4d7f-aa19-8d5dcfefcdf7.jpg"  xlink:type="simple"/></disp-formula><p>In a loop, the upper and lower half circles correspond to phonon emission (<img src="21-7500528\d3066a91-68d3-4b65-bbbf-007b70b7642d.jpg" />) and phonon absorption (<img src="21-7500528\06d97b25-cfe2-46e0-b2f8-3ee3d1b6f261.jpg" />).</p><p>3) There are diagrams connecting the final state <img src="21-7500528\5b2812bc-677c-43d2-bd6d-b91683106156.jpg" /> to the implicit state <img src="21-7500528\1d0b150d-9106-4865-a346-6f7cca141b5e.jpg" /> with dotted line and connecting the implicit state <img src="21-7500528\73323c40-b9d8-4a8d-86b4-9c620b3540c3.jpg" /> to a state <img src="21-7500528\f8e11099-000a-4638-a1d3-b4aa23e7acba.jpg" /> with a clockwise (or counterclockwise) loop. <xref ref-type="fig" rid="fig2">Figure 2</xref> corresponds to clockwise loop.</p><p>4) Assign <img src="21-7500528\11d58ba2-be45-4e03-a039-da9749a536c3.jpg" /> for the clockwise loop <img src="21-7500528\82f0e138-341c-4a95-803a-13c1b48cb637.jpg" />, and assign <img src="21-7500528\c85784d4-5343-45ce-ade0-eceff2960b60.jpg" /> for the counterclockwise loop<img src="21-7500528\9c1e27b1-061f-416e-b993-0d6807539a92.jpg" />. Here <img src="21-7500528\bf1d9411-e28b-409f-81dd-2db6efba3cff.jpg" />called the G-factors are defined as follows:</p><disp-formula id="scirp.8648-formula69889"><label>(5)</label><graphic position="anchor" xlink:href="21-7500528\e5886dc8-f4a7-46d5-8e9b-84e700c15c13.jpg"  xlink:type="simple"/></disp-formula><p>By<img src="21-7500528\e556e9e9-db6b-44fd-a751-f2f84d000e30.jpg" />, the energy conservation is satisfied, i.e.,<img src="21-7500528\3d64cd77-2fad-41b0-8a03-e133706daa19.jpg" />.</p><p>5) Let the states connected to the dotted line involve no loops.</p><p>6) a) Multiply<img src="21-7500528\2990e095-246a-4a4e-8541-fdf1cc230130.jpg" />, <img src="21-7500528\e50de22e-3c00-479e-addb-29d4ad4aad49.jpg" />, and <img src="21-7500528\c1019081-b372-4a12-9998-3ce94bc303bc.jpg" /> for the clockwise loop. b) Multiply<img src="21-7500528\157b0149-3ee1-44cd-b863-32c8e8055de3.jpg" />, <img src="21-7500528\dd4f8206-cce6-4a8c-b0c0-328924fabc3d.jpg" />, and <img src="21-7500528\4ae84c4a-90ed-4c17-b5df-a066cc2a860c.jpg" /> for the counterclockwise loop.</p><p>7) Finally, sum all the diagrams after summing eachdiagram over all q and <img src="21-7500528\e7e36b4e-c37c-49fc-a913-3b67199fc94e.jpg" /> values for the line shape function.</p></sec><sec id="s3"><title>3. Linear Optical Conductivity</title><p>When an electromagnetic wave of frequency <img src="21-7500528\ec885396-a829-4f39-a20b-40805dee1421.jpg" /> is applied to a system along the l (x, y, z) direction, the linear optical conductivity is given by the following: [10-12]</p><disp-formula id="scirp.8648-formula69890"><label>(6)</label><graphic position="anchor" xlink:href="21-7500528\ac918b1f-7a96-43c8-bc53-077439d1fb80.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="21-7500528\2a341072-9675-4db7-b0ad-abff38eff567.jpg" /> for electron states <img src="21-7500528\245245e3-3285-416f-a466-290f23594efb.jpg" /> and<img src="21-7500528\3a14d2b1-ce4e-4786-81f3-b090f019ef6d.jpg" />, j<sub>k</sub> is the k component of the single electron current op-</p><p>erator, r<sub>l</sub> is the l component of the electron position vector, <img src="21-7500528\5c1d2822-62a8-41ab-93bc-00b83ae908eb.jpg" />is the Fermi distribution function for an electron with energy<img src="21-7500528\02ee4385-079b-422c-9b11-041b8dd3dd32.jpg" />, and<img src="21-7500528\02eee62d-f107-41a4-a4df-1e3afa3fa3fa.jpg" />. Equation (6) can be represented by the diagram in <xref ref-type="fig" rid="fig3">Figure 3</xref>.</p><p>The energy term in Equation (6),</p><p><img src="21-7500528\e3c1f172-ac11-4cd4-a5e0-7d3943a68bde.jpg" />, represents the transition from the initial state <img src="21-7500528\74cb840d-cdde-47cd-be80-8c73f4f610af.jpg" /> to the final state <img src="21-7500528\8fd73d0d-548e-4376-ba2b-2cbb1dbe6169.jpg" /> with a photon absorption of frequency<img src="21-7500528\fc2e38d6-dfca-4891-b984-8960debc407a.jpg" />. If there was no phonon scattering, the line shape would be like a delta function. However, as the electrons are scattered by phonons, the shape is broadened, so the line shape function <img src="21-7500528\29dc07a4-34b5-4f10-a7a9-92c64825cb42.jpg" /> is involved.</p><p>In Equation (6), there is no intermediate state between the initial state <img src="21-7500528\8327ee7f-e642-47ae-92b2-edd44e789330.jpg" /> and final state<img src="21-7500528\96f7d7a7-f50e-4d96-b2c3-2245d78112d0.jpg" />, so the line shape function <img src="21-7500528\75c993ce-780b-481a-bb8e-5b819e59435f.jpg" /> is represented by four loop diagrams in <xref ref-type="fig" rid="fig4">Figure 4</xref>.</p><p>From <xref ref-type="fig" rid="fig4">Figure 4</xref>, <img src="21-7500528\b68ec028-a179-4d8b-97ca-c842f55c4c7d.jpg" />is obtained as</p><disp-formula id="scirp.8648-formula69891"><label>(7)</label><graphic position="anchor" xlink:href="21-7500528\2cfcb24e-00c4-41ac-a07b-1d502a588d4c.jpg"  xlink:type="simple"/></disp-formula><p>which is identical to the line shape function given by Equation (4.8) in [<xref ref-type="bibr" rid="scirp.8648-ref11">11</xref>].</p><p>The physical meaning of the first term in Equation (7) is as follows (see the first term in <xref ref-type="fig" rid="fig5">Figure 5</xref>). Since the absorption power delivered to the system is proportional to the real part of the conductivity [10,11], <img src="21-7500528\fb5a95a0-065d-4ce4-82bb-a92d3a7c0e2e.jpg" />becomes Dirac’s delta, i.e.,</p><p><img src="21-7500528\4a1e25ed-d9f0-459e-8698-0e0ec9667bec.jpg" />, since <img src="21-7500528\2fd10635-e096-454b-bf2b-cb8b206ff4cf.jpg" /> can be replaced by <img src="21-7500528\b78bf12c-3414-4151-991b-75a456754b85.jpg" /> (<img src="21-7500528\c169a685-3bd8-4f4b-8e18-39638b8462b3.jpg" />) in the response scheme.</p><p>Note that <img src="21-7500528\21f18897-7ab6-468c-b0fe-0d1144783430.jpg" /> where P means principal value. Therefore, <img src="21-7500528\158cf038-6fd9-4e08-bfef-de6c6654f33c.jpg" />means that the implicit state <img src="21-7500528\05f05c8a-3327-4c5d-80b8-55267c105d09.jpg" /> is determined by the energy of the final state, photon energy, and phonon energy, so that energy conservation can be satisfied, i.e.<img src="21-7500528\d9ff5cd1-df5c-4eb5-9c84-f664bdd4c709.jpg" />. <img src="21-7500528\389acff9-130f-41dd-9962-fb4aaf467a2d.jpg" />means that the implicit state <img src="21-7500528\e0f6bb52-41e2-4a76-8b76-ba8cb166598f.jpg" /> is coupled with the initial state <img src="21-7500528\9ba2dde9-9493-47e3-85d3-2899aa83536b.jpg" /> by a phonon with wave vector q. <img src="21-7500528\e349f863-2b81-4e4d-8e54-33a1a3779faa.jpg" />means that the reverse implicit transition from the final state <img src="21-7500528\3c2896c9-6e63-4258-b564-d4194c7869ec.jpg" /> to the intermediate state <img src="21-7500528\834eabc3-acb8-4e68-b429-b590895160b3.jpg" /> with phonon absorption should be subtracted from the forward implicit transition from the intermediate state <img src="21-7500528\e7fd764d-f6c9-48b9-ae0f-8392369e7658.jpg" /> to the final state <img src="21-7500528\f1fd76e3-a474-427a-8adb-4bd384786798.jpg" /> with a phonon emission. This means that when an electron-phonon interaction is involved in the electron transition, there are local fluctuations, i.e. a transition occurs via implicit states. In other words, an electron undergoes a transition from the implicit state, which is coupled with the initial state, to the final state (or vice versa) with phonon emission (or absorption). The transition forms a loop because the absorption process maintains a balance with the emission process. Although <img src="21-7500528\8decaf8e-d831-4f85-96ae-21f3c5198782.jpg" /> is called the line shape function, the line shape must be calculated from Equation (6) not directly from Equation (7). Therefore, all the states given by <img src="21-7500528\50261d56-5dc7-4353-bbd2-5862aad45ed2.jpg" /> are called the implicit states because they are included only in<img src="21-7500528\405b01a9-fe9d-4d7a-ad31-4d12c8ad1dea.jpg" />. Therefore, the transition from the initial state <img src="21-7500528\b7a0ab15-90f8-44a9-9e69-40ba761244a5.jpg" /> to the final state <img src="21-7500528\71d18195-0d6f-4e20-8c8a-8e9a934332b7.jpg" /> occurs via two implicit transitions, and the implicit state is connected to the initial state by <img src="21-7500528\35dc7b57-1b10-4469-8072-6de279a7d052.jpg" /> and to the final state by<img src="21-7500528\f133c8ed-4172-45aa-b94a-a042d269706b.jpg" />.</p><p>Although the implicit transitions are not measured directly, they should be considered in the calculations. Note that the other theories [1-7] cannot provide any diagram representation because they contain the sums of two distribution functions, such as <img src="21-7500528\c0f86344-6edd-4001-8029-7bd43690e2d9.jpg" /></p><p>The other three terms in <img src="21-7500528\56c9d798-91f1-4cfb-ab4f-f9f52a6dd582.jpg" /> can be represented in a similar manner.</p><p>In <xref ref-type="fig" rid="fig4">Figure 4</xref> or Equation (7), the first two terms are</p><p>topologically equivalent because the absorption of photons appears while phonons can be both absorbed and emitted in the transitions. The absorption (emission) of a photon or a phonon in the forward transitions is identical to the emission (absorption) in the reverse transitions, with negative contributions (minus signs) assigned to the reverse transitions. The final two terms are also topologically equivalent for the same reason. A net transition is possible because the implicit states are determined variously according to the energies of the final (or initial) state, photon energies, and phonon energies.</p></sec><sec id="s4"><title>4. First-Order Nonlinear Optical Conductivity</title><p>The first-order nonlinear optical conductivity for two incident electromagnetic waves of frequencies <img src="21-7500528\5118aa7c-b4d8-4007-bafd-b58981794e40.jpg" /> and <img src="21-7500528\fe7b97e7-fd48-404c-8ad4-8656a1a5b7f4.jpg" /> is given by the following [10-12]</p><disp-formula id="scirp.8648-formula69892"><label>(8)</label><graphic position="anchor" xlink:href="21-7500528\6fb4ae87-5282-442b-ae7d-1b3191f3bf13.jpg"  xlink:type="simple"/></disp-formula><p>where<img src="21-7500528\3a2f30bd-6e29-48a7-bbee-e748ee6d42cd.jpg" />. For the two photon process, there is an intermediate state <img src="21-7500528\711e1265-f066-4777-968f-15d497b2e319.jpg" /> between the initial state <img src="21-7500528\d78aac7b-41f8-4a88-9379-d858babe6233.jpg" /> and final state<img src="21-7500528\5526f735-f5df-488a-adf5-c135cd53be4a.jpg" />. The first term in Equation (8) means thatthere is an intermediate transition from the intermediatestate <img src="21-7500528\971b142e-d193-4966-8ef3-52222129aefa.jpg" /> to the final state <img src="21-7500528\d4153f7c-3d27-4ccd-a839-83e6af39fb96.jpg" /> with photon (<img src="21-7500528\60ed1456-ab8f-46d6-a6e1-c8a12c23630f.jpg" />) absorption and line shape function <img src="21-7500528\a2637f55-116b-46bd-98d9-93d077c98adb.jpg" /> and the direct transition from the initial state <img src="21-7500528\6f157975-4051-455b-95c1-a300553c50a3.jpg" /> to the final state <img src="21-7500528\6bf211af-aa2f-4e95-a486-5e51506dd12c.jpg" /> with two photons (<img src="21-7500528\ed67128c-b61a-466c-bab6-0bd83d0e3173.jpg" />,<img src="21-7500528\96306610-b111-4c87-a884-57aa6bab5d26.jpg" />) absorption and line shape function <img src="21-7500528\a1d50775-ce7b-4c52-a0c7-9c3d04534e30.jpg" /> (<xref ref-type="fig" rid="fig5">Figure 5</xref>). Note that</p><p><img src="21-7500528\dfd113b5-d44b-448e-b7fc-c115870903dc.jpg" />.</p><p><img src="21-7500528\3cd522e5-ce89-4344-9b80-eef9aecd3fa3.jpg" /> is called the intermediate state to be discerned from the implicit state because it is explicitly included in the conductivity but not in the line shape function.</p><p>Four loop diagrams exist because there is an implicit state <img src="21-7500528\8980fb5e-7de1-4f8e-b231-5929a2aac6c0.jpg" /> between state <img src="21-7500528\17c93ffb-f8d8-4c81-9efa-e116a6e3d225.jpg" /> and state <img src="21-7500528\61016750-c5e7-4bd3-8418-1c8a693f454c.jpg" /> through <img src="21-7500528\0084f97c-730e-47a8-b508-3066a4173b37.jpg" /> in the first term in Equation (8) (<xref ref-type="fig" rid="fig5">Figure 5</xref>). The first two terms involve <img src="21-7500528\303da003-04d0-4e1e-8b86-8ed40f58c2a3.jpg" /> in the <img src="21-7500528\9aacd188-f47f-43cb-8f03-6caee56111f6.jpg" /> transition of <xref ref-type="fig" rid="fig6">Figure 6</xref>, considering <img src="21-7500528\ad2429e1-649d-47cb-89e1-1afe39444786.jpg" /> as a pseudo-<img src="21-7500528\70fcd4a7-cdfe-4e02-9df8-0760b02d2693.jpg" /> state through <img src="21-7500528\0a35f3c0-42c7-4036-afc7-3d55f81edbb4.jpg" /> and other two terms involve <img src="21-7500528\74796871-771d-4f68-ab60-eec79e6fda8e.jpg" /> in the <img src="21-7500528\87a65f35-07b1-43cb-80ec-309219bf6d59.jpg" /> transition of <xref ref-type="fig" rid="fig5">Figure 5</xref>.</p><p>Therefore <img src="21-7500528\8458f5e5-3706-4ee0-a6d3-0c91db43c7cc.jpg" /> can be expressed as follows:</p><disp-formula id="scirp.8648-formula69893"><label>(9)</label><graphic position="anchor" xlink:href="21-7500528\2e7f3943-dafd-43e4-b8a4-138e7e69f423.jpg"  xlink:type="simple"/></disp-formula><p>which is identical to the line shape function given by Equation (5.7) in [<xref ref-type="bibr" rid="scirp.8648-ref11">11</xref>]. The physical meaning of the third term in Equation (9) is as follows: <img src="21-7500528\8ba08cf8-1a4a-41cc-9f4a-198146032a47.jpg" />means that the implicit state <img src="21-7500528\b7ebe401-011a-405c-861e-f3bbdfb97d69.jpg" /> is determined by the energy of the final state<img src="21-7500528\c1fa354f-cbfd-4bc7-b532-557ec65ace39.jpg" />, two photon energies, and phonon energy; and <img src="21-7500528\5dd6e80c-8891-49e1-9a87-0293463f7777.jpg" /> means that the implicit state <img src="21-7500528\cde77e72-bde8-4699-8008-5b8aad3fa7d1.jpg" /> is coupledwith the initial state <img src="21-7500528\ebb79265-c8b0-4471-b7ce-3b7ba95ee665.jpg" /> by a phonon with a wave vector q. There are two forward implicit transitions and two reverse implicit transitions with a center on the implicit state<img src="21-7500528\9c208507-f33c-4fcb-80ab-6c04b0516e44.jpg" />. All the implicit states and types of phonons are included in the processes by the sums in Equation (9). The other three terms in <img src="21-7500528\8a7acf10-6e67-4a9b-aae4-1fd95fd20195.jpg" /> can be interpreted in a similar manner. Similarly, <img src="21-7500528\bd999c95-32fd-4806-83ff-fceca9e45e9f.jpg" />can be obtained. In <xref ref-type="fig" rid="fig6">Figure 6</xref> or Equation (9), the first two terms and last two terms are topologically equivalent pairs for the same reason as in <xref ref-type="fig" rid="fig5">Figure 5</xref> or Equation (7).</p></sec><sec id="s5"><title>5. Concluding Remarks</title><p>In conclusion, this paper introduced a loop diagram approach to the nonlinear optical conductivity formula for an electron-phonon system. It was possible to explain the phonon emissions and absorptions in all electron transition processes in an organized manner because the line shape functions include the electron distribution functions properly as well as the phonon distribution functions. Since the present diagram method is not the one representing the trajectories of particles in the intermediate stages of scattering processes, these diagrams should not be confused with the time-ordered diagrams in the Feynman scheme [<xref ref-type="bibr" rid="scirp.8648-ref14">14</xref>] or with the temperature diagrams</p><p>in the Feynman-like scheme [15,16]. However, this method can be classified as another Feynman-like scheme, and shall be called the “KC loop diagrams” because all the contributions to the self-energy terms can be grouped into topologically-distinct loop diagrams based on the electron-phonon population topology originated by proper applications of KCRI’s and SDPO’s. This method can be applied further to other electron transition phenomena.</p></sec><sec id="s6"><title>REFERENCES</title></sec></body><back><ref-list><title>References</title><ref id="scirp.8648-ref1"><label>1</label><mixed-citation publication-type="other" xlink:type="simple">L. Hedin and S. 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