《萬有引力破譯》補(bǔ)充材料-萬物互聯(lián)宏微同一

萬有引力破譯補(bǔ)充材料作者：邱旭濱Correspondingauthor:windpassocean01@163.com萬物互聯(lián)，宏微同一物理量之間的關(guān)聯(lián)辯證哲學(xué)認(rèn)為宇宙是一個(gè)統(tǒng)一體，萬物互聯(lián)，宏微同源。根據(jù)系統(tǒng)理論，一個(gè)系統(tǒng)由許多相互關(guān)聯(lián)的部分組成，這些部分共同決定了整個(gè)系統(tǒng)的性質(zhì)。物理系統(tǒng)是一個(gè)統(tǒng)一的整體，每個(gè)物理量都是相互聯(lián)系的，不存在獨(dú)立的物理量。物理體系是個(gè)統(tǒng)一整體，各物理量是互相聯(lián)系的，獨(dú)立不群的物理量是不存在的。物理學(xué)體系由7個(gè)基本物理量（質(zhì)量m、時(shí)間t、長(zhǎng)度l、電流I、溫度T、物質(zhì)的量n、發(fā)光強(qiáng)度i）組成，最為核心的物理量是質(zhì)量、時(shí)間、空間，其它的物理量都是圍繞著這三個(gè)物理量展開的。物理體系中的所有物理量，都由數(shù)量與單位構(gòu)成。單位代表事物屬性，數(shù)量反映變化。物理研究實(shí)際是物質(zhì)、空間、時(shí)間之間的量變關(guān)系。物理常數(shù)是描述物質(zhì)和能量行為的基本值。它們用于預(yù)測(cè)物理系統(tǒng)的行為。物理常數(shù)之間的關(guān)系是物理學(xué)中一個(gè)復(fù)雜而重要的研究領(lǐng)域。理解這些關(guān)系使我們能夠預(yù)測(cè)物理系統(tǒng)的行為，并更深入地理解物理的基本結(jié)構(gòu)。然而，由于各學(xué)科在發(fā)展過程中缺乏橫向聯(lián)系，使得物理量之間的量綱無法建立起對(duì)應(yīng)關(guān)聯(lián)，無法明晰物理量的本質(zhì)屬性，給研究帶來了很大的障礙。如電荷是什么？質(zhì)量是什么？電荷與質(zhì)量之間有什么關(guān)系？溫度的本質(zhì)是什么，與什么基本量對(duì)應(yīng)關(guān)聯(lián)？各種物理常數(shù)之間有何內(nèi)在的關(guān)聯(lián)？等等。顯然，由于這些明顯的割裂，難以將物理體系統(tǒng)一起來。故下面就正文涉及的不可避免的物理量及量綱作適度的補(bǔ)充，以增強(qiáng)讀者對(duì)正文的理解。而找出它們的對(duì)應(yīng)關(guān)系，一個(gè)有效的方法就是通過等效關(guān)系建立起各種實(shí)驗(yàn)公式的關(guān)聯(lián)，如通過能量等效關(guān)系，把庫(kù)倫公式與能量公式等效，在公式中找出等量對(duì)應(yīng)關(guān)系，從而判斷對(duì)應(yīng)的物理量組合之間的對(duì)應(yīng)關(guān)系。并通過所獲得的系列相關(guān)結(jié)果，判斷出它們具有很高的可信度。因?yàn)?，盡管這種對(duì)應(yīng)關(guān)系是符合邏輯的，但人們對(duì)孤立案例往往具有一定的保守性。所以通過大量的相關(guān)結(jié)果，可以增強(qiáng)它的可信度。等效關(guān)系舉例說明如下：電磁學(xué)、熱力學(xué)、量子學(xué)的能量等效關(guān)系：hh通過具體的分解，結(jié)合數(shù)據(jù)，便可得到各種相應(yīng)的關(guān)系：h=結(jié)合黑體輻射原理，黑體輻射能量作為電磁輻射與電荷、光速、及玻爾茲曼相關(guān)，h=ecke同樣，通過萬有引力與電磁力的能量等效，kqkG從引力常數(shù)G的信息結(jié)構(gòu)中，我們可以進(jìn)一步得到玻爾茲曼常數(shù)的時(shí)空結(jié)構(gòu)以及普朗克常數(shù)和玻爾茲曼常數(shù)之間的關(guān)系：kh進(jìn)而揭示磁通量量子的時(shí)空結(jié)構(gòu)：Φ其中，t0是氫原子電子圍繞原子核的運(yùn)動(dòng)周期，f從h=eckB[1]中我們還可以發(fā)現(xiàn)，光電效應(yīng)方程h=eK的系數(shù)K，實(shí)際就是K=ckB；黑體輻射中，維恩公式M=af3e-β/f/T的系數(shù)β，實(shí)際就是再者，通過比較電磁能等效公式中溫度和頻率之間的關(guān)系，可以看出韋恩位移定律中溫度與頻率的比例系數(shù)Cv本質(zhì)上是f/CvT公式C’v=f/T=3/ec=6.24Cv可以看出，這些對(duì)應(yīng)關(guān)系無不與實(shí)驗(yàn)數(shù)值相符，物理內(nèi)涵也能得到合理的解釋。這些物理量描述了物質(zhì)運(yùn)動(dòng)的時(shí)空分布和能量交換，并且相互關(guān)聯(lián)，這表明各個(gè)相關(guān)學(xué)科的理論密切相關(guān)。更多關(guān)聯(lián)見表S1：Table1顯示了物理量之間的關(guān)系，所有量綱(Dim)彼此對(duì)應(yīng)。例如:DimDimDime=DimTableS1.物理量之間的相關(guān)性關(guān)于質(zhì)量?jī)?nèi)涵物質(zhì)是運(yùn)動(dòng)的載體，質(zhì)量的本義是物質(zhì)的量。由于微觀物質(zhì)的具體形式無法直接觀察，因此只能通過某些手段間接測(cè)量。因此，物理學(xué)中的質(zhì)量與物理學(xué)中的測(cè)量密切相關(guān)。只有從測(cè)量的角度才能描述質(zhì)量。在物理學(xué)中，質(zhì)量主要通過特定的物理關(guān)系來描述，例如力、動(dòng)量和能量。它們都是對(duì)物質(zhì)運(yùn)動(dòng)和變化之間關(guān)系的描述，而物質(zhì)的運(yùn)動(dòng)和變化就是物質(zhì)的時(shí)空變化。由于科學(xué)的發(fā)展具有一定的歷史局限性，對(duì)物理學(xué)的描述僅基于當(dāng)前的理論和測(cè)量水平。在現(xiàn)代物理學(xué)之前，物體的質(zhì)量主要通過比較其重量來描述。隨著科學(xué)研究進(jìn)入原子時(shí)代，人們逐漸意識(shí)到在原子水平上描述物質(zhì)的數(shù)量。隨著科學(xué)發(fā)展到量子時(shí)代，能量分立理論已經(jīng)徹底改變了認(rèn)知的概念，測(cè)量已經(jīng)深入到量子層面。今天，我們可以從量子層面理解質(zhì)量。量子理論描述質(zhì)量的能量關(guān)系如下：m基本量子能量為：h基本量子質(zhì)量為m0m1公斤對(duì)應(yīng)的質(zhì)量頻數(shù)為：1基本量子質(zhì)量與1kg質(zhì)量頻率之間的關(guān)系：m0s可以看出，從量子化的角度來看，質(zhì)量對(duì)應(yīng)的時(shí)空是周期T。這樣，物理量就可以轉(zhuǎn)化為相應(yīng)的時(shí)空結(jié)構(gòu)關(guān)系。物理單位的協(xié)調(diào)《萬有引力破譯》中存在一個(gè)問題。按照對(duì)應(yīng)關(guān)系，方程ec2=mp2ve2的單位為C=眾所周知，長(zhǎng)度的平方是面積。但質(zhì)量與長(zhǎng)度不同，質(zhì)量的平方不能改變質(zhì)量的屬性。例如：100kg物質(zhì)，橫排為10kg，縱排為10kg,，縱橫相乘總量為100kg。顯然，數(shù)量N雖然發(fā)生改變，但單位屬性保持不變。故有m1m2=|m1m2|kg。物理中，力的單位中所含質(zhì)量單位為kg，而不是kg2，因此，引力公式中，其中一質(zhì)量單位b通過系數(shù)G的量綱加以消除，SI(G)=kg物理中，物理量由數(shù)量與單位組成，單位代表物理屬性，數(shù)量反映變化程度。而力是動(dòng)量關(guān)于時(shí)間的變化量F=d(mv)/dt。引力中兩質(zhì)量體是互相依存的，其中一個(gè)質(zhì)量體的質(zhì)量必然要轉(zhuǎn)換成另一個(gè)質(zhì)量體的頻數(shù)N，即m1m2=m1?|m2|。由于萬有引力通過真空量子以光速c交換能量，所以引力實(shí)際由變化的質(zhì)量決定，即F=c?dm/dt，體現(xiàn)在引力公式中即為Fm如此便解決了萬有引力與電磁力間，電荷與質(zhì)量量綱轉(zhuǎn)換不協(xié)調(diào)的問題。e參考文獻(xiàn)：邱旭濱，揭開量子和溫度的隱秘關(guān)系，格物(China).19(94),53-58(2019).SupplementaryMaterialsforDecipheringuniversalgravitationXubinQiuCorrespondingauthor:windpassocean01@163.com

1.PhysicalquantitycorrelationanddimensionDialecticalphilosophyholdsthattheuniverseisaunity,withallthingsinterconnectedandmacroandmicrohomologous.Accordingtosystemtheory,asystemiscomposedofmanyinterrelatedparts,whichtogetherdeterminethenatureofthewholesystem.Thephysicalsystemisaunifiedwhole,eachphysicalquantityisinterconnected,andthereisnoindependentphysicalquantity.Thephysicalsystemiscomposedofsevenbasicphysicalquantities(mass,time,length,electriccurrentI,Temperature,amountofsubstancen,luminousintensityi).Thecorephysicalquantitiesaremass,timeandspace,andotherphysicalquantitiesaredevelopedaroundthesethreephysicalquantities.Allphysicalquantitiesinaphysicalsystemarecomposedofquantitiesandunits.Theunitrepresentstheattributeofthings,andthequantityreflectsthechange.Physicalresearchisactuallyaquantitativerelationshipbetweenmatter,spaceandtime.Physicalconstantsarebasicvaluesthatdescribethebehaviorofmatterandenergy.Theyareusedtopredictthebehaviorofphysicalsystems.Therelationshipbetweenphysicalconstantsisacomplexandimportantresearchfieldinphysics.Understandingtheserelationshipsenablesustopredictthebehaviorofphysicalsystemsandunderstandtheunderlyingstructureofphysicsmoredeeply.However,duetothelackofhorizontallinksinthedevelopmentprocessofvariousdisciplines,thedimensionsbetweenphysicalquantitiescannotestablishcorrespondingrelationships,andtheessentialattributesofphysicalquantitiescannotbeclarified,whichhasbroughtgreatobstaclestoresearch.Whatisthecharge?Whatisquality?Whatistherelationshipbetweenchargeandmass?Whatisthenatureoftemperatureandwhatbasicquantitiesarerelatedtoit?Whatistheinternalrelationshipbetweenvariousphysicalconstants?wait.Obviously,duetotheseobvioussplits,itisdifficulttounifythephysicalsystem.Therefore,theinevitablephysicalquantitiesanddimensionsinvolvedinthetextareappropriatelysupplementedtoenhancereaders'understandingofthetext.Aneffectivewaytofindouttheircorrespondingrelationshipistoestablishtheequivalentrelationshipoftheexperimentalformulaandfindouttheequivalentcorrespondingrelationshipbetweenthecombinationsofphysicalquantities.Throughaseriesofrelevantresultsobtained,itisprovedthattheyarehighlycredible.Examplesareasfollows:Energyequivalencerelationshipofelectromagnetism,thermodynamicsandquantum:hhAccordingtothecorrespondingrelationship：h=ThisresultisconsistentwiththecorrelationbetweenPlanckconstantandcharge,speedoflight,andBoltzmannconstantinblackbodyradiationtheory.Wherein,formulaArevealsthattheessenceoftemperatureisthechangeofelectriccharge.Asaphysicalquantitytodescribetheenergy,temperatureactuallycorrespondstothespace-timerelationshipofmovingmatter.keThisresultrevealsthattheessenceofchargeisthemovementandchangeofelectromagneticmass.Similarly,thecorrespondingphysicalquantitycorrelationcanalsobeobtainedthroughtheenergyequivalenceofuniversalgravitationandelectromagneticforce.Seethetextforthespecificderivationprocess.kGFromtheinformationstructureofgravitationalconstantG,wecanfurtherobtainthespace-timestructureofBoltzmannconstantandtherelationshipbetweenPlanckconstantandBoltzmannconstant:khThenrevealthespace-timestructureofmagneticfluxquantum:ΦWhere,t0=1/f0istheperiodofmotionofhydrogenatFromformulah=eckB,wecanalsofindthatthecoefficientofequationh=eKinphotoelectriceffectisK=ckB;ThecoefficientofWienformulaM=af3e-β/f/TInaddition,bycomparingtherelationshipbetweentemperatureandfrequencyintheequivalentformulaofelectromagneticenergy,itcanbeseenthattheproportionalcoefficientoftemperatureandfrequencyCvinWayne'sdisplacementlawisessentially1/qc.CvTFormulaf/T=3/ec=6.24×1010Thesephysicalquantitiesdescribethespatiotemporaldistributionandenergyexchangeofmaterialmovementandarerelatedtoeachother,whichshowsthatthetheoriesofvariousrelateddisciplinesarecloselyrelated.SeeTableS1formoreassociations:Table1showstherelationshipbetweenphysicalquantities,andalldimensionscorrespondtoeachother.Forexample:DimDimDime=DimTableS1.Planckconstanthh==GravitationalconstantGGBoltzmannconstantkkElectrostaticconstantk,Dielectricconstantε0,magneticpermeabilityμkμelementarychargeee=h/=electronmassmmBohrelectronvelocityvvBohrradiusa0,periodt0,frequencyfa0=λfinestructureconstantααMagneticfluxquantumΦΦRydbergconstantRRcut-offfrequencyandvoltagecoefficientK(U=KKlitzingconstantRRPlanckmassmmBasicquantummassmmElectronmassandenergyfrequencyffRemarkscolumnTheboldfacerepresentsthespace-timestructureofphysicalquantities.SICorrelationbetweenphysicalquantitie2.AbouttheconnotationofqualityMatteristhecarrierofmotion,andmassreferstothequantityofmatter.Becausethespecificformofmicroscopicmattercannotbeobserveddirectly,itcanonlybemeasuredindirectlybycertainmeans.Therefore,themassinphysicsiscloselyrelatedtothemeasurementinphysics.Onlyfromtheperspectiveofmeasurementcanthemassbedescribed.Inphysics,themassismainlydescribedthroughspecificphysicalrelations,suchasforce,momentum,andenergy.Theyarealldescriptionsoftherelationshipbetweenthemovementandchangeofmatter,andthemovementandchangeofmatteristhespace-timechangeofmatter.Becausethedevelopmentofsciencehascertainhistoricallimitations,thedescriptionofphysicsisonlybasedonthecurrenttheoryandmeasurementlevel.Beforemodernphysics,themassofanobjectwasmainlydescribedbycomparingitsweight.Asscientificresearchenterstheatomicera,itisgraduallyrealizedtodescribetheamountofmatterattheatomiclevel.Withthedevelopmentofscienceintothequantumera,theseparationtheoryofenergyhasrevolutionizedtheconceptofcognition,andmeasurementhasgonedeepintothequantumlevel.Today,wecanunderstandmassfromthequantumlevel.Quantumtheorydescribestheenergyrelationshipofmassasfollows:mBasicPlanckenergyis:hBasicquantummassm0mMassfrequencycorrespondingto1kg：1Therelationshipbetweenthebasicquantummassandthefrequencyof1kgmass:m0Itcanbeseenthatfromtheperspectiveofquantization,thespace-timecorrespondingtomassistheperiodT.Inthisway,thephysicalquantitycanbetransformedintothecorrespondingspace-timestructurerelationship.CoordinationofphysicalunitsThereisaprobleminthetext.Accordingtothecorrespondence,thecorrespondingunitofformulaec2=mp2ve2isC=Asweallknow,thesquareoflengthisthearea.Butmassisdifferentfromlength,and