自然界四力統(tǒng)一的形成機(jī)制(中英文)(1)

1、場(chǎng)內(nèi)斂平衡方程組（中英文） 王明理（河南省洛陽(yáng)市）717905836摘要： 萬(wàn)有引力、電荷力、弱力、強(qiáng)力的統(tǒng)一是物理領(lǐng)域研究的重心之一，“標(biāo)準(zhǔn)模型”是在“量子力學(xué)”的基礎(chǔ)上發(fā)展而來(lái)，“標(biāo)準(zhǔn)模型”實(shí)現(xiàn)了磁力、弱力及強(qiáng)力的統(tǒng)一，目前世界上還沒(méi)有任何一種理論能夠?qū)崿F(xiàn)四力統(tǒng)一，“四力統(tǒng)一”涉及到空間的最基本存在形式、宇宙創(chuàng)生以及物質(zhì)創(chuàng)生與分化等大量問(wèn)題。自然界有許多現(xiàn)象現(xiàn)有理論無(wú)法給以合理的解釋如：（1）質(zhì)子在達(dá)到穩(wěn)定態(tài)的基態(tài)后不會(huì)再進(jìn)一步衰變、電子能夠環(huán)繞質(zhì)子恒動(dòng);（2）夸克間存在巨大的強(qiáng)力但卻存在“漸進(jìn)自由”現(xiàn)象；（3）微觀粒子間量子糾纏的形成機(jī)制；（4）在高能對(duì)撞所產(chǎn)生的粒子中有些粒子質(zhì)量的衰減

2、速度非?？於行┝Ｗ拥馁|(zhì)量卻非常穩(wěn)定;（5）物質(zhì)慣性的來(lái)源；（6）熱吸收與熱輻射的形成機(jī)制;（7）四力統(tǒng)一的起源問(wèn)題;（8）物質(zhì)靜止質(zhì)量的來(lái)源；（9）正反物質(zhì)演化的本質(zhì)；（10）天體自旋與傾斜等。本篇論文基于上述現(xiàn)象提出“等價(jià)場(chǎng)力學(xué)”構(gòu)架，“等價(jià)場(chǎng)力學(xué)”在邏輯推理的基礎(chǔ)上能夠解釋上述問(wèn)題。論文的主要?jiǎng)?chuàng)新點(diǎn)有3個(gè)：（1）用“場(chǎng)內(nèi)斂”這一概念來(lái)做為物質(zhì)熱吸收的起源，用“場(chǎng)內(nèi)斂”與“場(chǎng)內(nèi)斂平衡”這兩個(gè)概念來(lái)統(tǒng)一四力的起源問(wèn)題，“場(chǎng)內(nèi)斂”為物質(zhì)間“場(chǎng)相互作用”的一種機(jī)制，“場(chǎng)內(nèi)斂率”能夠貫通物質(zhì)引力、電荷力、弱力、強(qiáng)力4種力學(xué)特征的變化；（2）提出自然界物質(zhì)系“廣泛性存在規(guī)律”的“靜態(tài)場(chǎng)內(nèi)斂率對(duì)應(yīng)性關(guān)

3、聯(lián)方程”（不含光子），該方程只需知道客體對(duì)主體的環(huán)繞周期與環(huán)繞半徑無(wú)需知道“環(huán)繞客體”的質(zhì)量值就可精確計(jì)算出主體的質(zhì)量值；（3）依據(jù)“靜態(tài)場(chǎng)內(nèi)斂率對(duì)應(yīng)性關(guān)聯(lián)方程”提出“飽和態(tài)場(chǎng)內(nèi)斂”的概念，進(jìn)而提出空間為一個(gè)基于“靜態(tài)場(chǎng)內(nèi)斂率對(duì)應(yīng)性關(guān)聯(lián)方程”呈體系性“飽和場(chǎng)平衡”的概念，從這里可推導(dǎo)出特定空間對(duì)其特定“場(chǎng)內(nèi)斂率值”的守衡，進(jìn)一步可推導(dǎo)出任意空間“場(chǎng)內(nèi)斂率值守衡張量”的存在，“空間SH值守衡張量”對(duì)外來(lái)物質(zhì)有斥力作用而對(duì)系內(nèi)物質(zhì)的“場(chǎng)內(nèi)斂率升值行為”有一定的阻遏力。與“標(biāo)準(zhǔn)模型”相比“等價(jià)場(chǎng)力學(xué)”在發(fā)展完善后可以建成一個(gè)完全無(wú)參數(shù)化的理論體系，該理論體系能夠涵蓋宏觀天體、黑洞以及各種微觀粒子間的

4、相會(huì)作用與演化?！暗葍r(jià)場(chǎng)力學(xué)”尚在初創(chuàng)階段還有大量重要的公式?jīng)]有完成，同時(shí)伴隨其發(fā)展一定會(huì)出現(xiàn)許多新的矛盾與問(wèn)題，希望有更多的專業(yè)人士能夠參與該理論體系的創(chuàng)建。關(guān)鍵詞：等價(jià)場(chǎng)；場(chǎng)內(nèi)斂；場(chǎng)內(nèi)斂平衡；場(chǎng)內(nèi)斂率S；場(chǎng)失衡能QE；飽和態(tài)場(chǎng)平衡；電子勢(shì)能阱；場(chǎng)屏蔽的雙向性；場(chǎng)慣勢(shì)；一：等價(jià)場(chǎng)原理 理論假設(shè)：任何物質(zhì)體在其外圍存在一個(gè)與“自體實(shí)體”的質(zhì)能值相等的“等價(jià)場(chǎng)體系”，等價(jià)場(chǎng)體系由邊際內(nèi)等價(jià)場(chǎng)體系 (EN)與邊際外等價(jià)場(chǎng)體系(EO)構(gòu)成且各自的總場(chǎng)能值相等即EN=EO，EN與EO有各自的子單元構(gòu)成、其子單元交替向外部空間衍生，EN與EO相鄰的“一對(duì)子單元構(gòu)成”稱為ENi與EOi，ENi與EOi的磁

5、場(chǎng)流分布規(guī)律為反對(duì)稱的關(guān)系（圖1），以整體來(lái)看EO體系位于EN體系的外部、空間的位置關(guān)系使ENi磁場(chǎng)能量的密度以極微小的程度大于EOi，等價(jià)場(chǎng)體系在其存在范圍內(nèi)系統(tǒng)性的受到空間里“磁波”的擾動(dòng)進(jìn)而發(fā)生場(chǎng)內(nèi)斂，子單元ENi與EOi“場(chǎng)能量密度”的差異性導(dǎo)致兩者被空間磁波所消弱的程度不同，這種差異性使EN與EO各自場(chǎng)內(nèi)斂的程度也不相同、EN內(nèi)斂的程度大而EO內(nèi)斂的程度輕，等價(jià)場(chǎng)這種內(nèi)斂效應(yīng)的偏置性最終積累于一個(gè)體系的近距空間（圖2）,特定空間場(chǎng)失衡的程度用場(chǎng)內(nèi)斂率S來(lái)表示，空間磁波相互作用產(chǎn)生的能量對(duì)于物質(zhì)以自體場(chǎng)內(nèi)斂率S增加的方式來(lái)體現(xiàn)，場(chǎng)內(nèi)斂率S值決定物質(zhì)體運(yùn)動(dòng)屬性以及其空間場(chǎng)失衡的分布特征。

6、 場(chǎng)內(nèi)斂的本質(zhì)是空間磁波相互間存在擾動(dòng)產(chǎn)生自然做功進(jìn)而將能量傳導(dǎo)到體系的近區(qū)空間、場(chǎng)內(nèi)斂的能量以一種非平衡的方式存在，熱吸收是廣域空間磁場(chǎng)做功的結(jié)果，熱輻射是體系“場(chǎng)內(nèi)斂平衡”的結(jié)果，粒子熱吸收與其熱輻射的能力是平衡的關(guān)系，粒子熱吸收能力與其場(chǎng)內(nèi)斂率S間存在特定的關(guān)聯(lián)關(guān)系，“飽和空間系統(tǒng)”有物質(zhì)進(jìn)入后引發(fā)“場(chǎng)內(nèi)斂平衡”的失衡、空間磁波是“飽和空間系統(tǒng)”場(chǎng)內(nèi)斂平衡的結(jié)果。一個(gè)體系磁波的波動(dòng)特征在空間的分布有其規(guī)律性，在穩(wěn)定的飽和態(tài)條件下一個(gè)定域空間在一定時(shí)間內(nèi)所經(jīng)過(guò)的能量越多、在此區(qū)域里“場(chǎng)平衡行為”所造成的磁波波動(dòng)頻率就越大，這一分布規(guī)律用場(chǎng)內(nèi)斂率S也可精確描述。物質(zhì)相互間存在的“場(chǎng)擾動(dòng)作用”

7、使一個(gè)系統(tǒng)內(nèi)任何對(duì)象的“場(chǎng)內(nèi)斂率值”均都有所增加，“場(chǎng)內(nèi)斂”為一種物質(zhì)間相互影響的機(jī)制。二：場(chǎng)內(nèi)斂平衡原理 物質(zhì)體系場(chǎng)內(nèi)斂造成其近區(qū)空間的場(chǎng)失衡，場(chǎng)失衡需要特定物質(zhì)對(duì)所在空間的邊際內(nèi)等價(jià)場(chǎng)進(jìn)行擾動(dòng)以使其場(chǎng)內(nèi)斂的程度與邊際外等價(jià)場(chǎng)達(dá)到平衡,“場(chǎng)平衡施體”的擾動(dòng)行為對(duì)邊際外等價(jià)場(chǎng)有增加其內(nèi)斂的作用、而對(duì)邊際內(nèi)等價(jià)場(chǎng)有減少其場(chǎng)內(nèi)斂的作用（圖2），物質(zhì)存在是空間“場(chǎng)內(nèi)斂失衡 ”的產(chǎn)物，宏觀系統(tǒng)場(chǎng)內(nèi)斂平衡原則：一個(gè)宏觀系統(tǒng)在“場(chǎng)內(nèi)斂區(qū)”之外的慢場(chǎng)區(qū)空間里所存在的“正電性慢物質(zhì)的總質(zhì)能值”等于慢場(chǎng)區(qū)空間里邊際內(nèi)等價(jià)場(chǎng)體系與邊際外等價(jià)場(chǎng)體系兩者的總場(chǎng)能值之差（應(yīng)當(dāng)考慮系內(nèi)所存在的運(yùn)動(dòng)態(tài)光子的擾動(dòng)效能），在一

8、個(gè)體系內(nèi)物質(zhì)間既是“相互擾體”的關(guān)系也是“相互場(chǎng)平衡施體”的關(guān)系，Si=Sh條件下物質(zhì)體的運(yùn)動(dòng)屬性由所在空間的場(chǎng)失衡特性所賦予。 “等價(jià)場(chǎng)力學(xué)”用“靜態(tài)場(chǎng)內(nèi)斂率對(duì)應(yīng)性關(guān)聯(lián)方程”來(lái)描述廣域概念“物質(zhì)系統(tǒng)”場(chǎng)失衡性在空間的分布規(guī)律（不含光子），用物質(zhì)自體的場(chǎng)內(nèi)斂率S來(lái)描述其空間場(chǎng)失衡性的特定分布特征，物質(zhì)在特定空間的運(yùn)動(dòng)屬性用其自體的S值和其存在空間的場(chǎng)內(nèi)斂率Sh值來(lái)描述，物質(zhì)間的所有力學(xué)關(guān)系統(tǒng)一在“場(chǎng)內(nèi)斂平衡”這一機(jī)制下去描述。 物質(zhì)體外部空間磁場(chǎng)強(qiáng)度的改變能夠影響其自體的場(chǎng)內(nèi)斂率S，除去標(biāo)準(zhǔn)光速外同一速度對(duì)一個(gè)體系的邊際外等價(jià)場(chǎng)與邊際內(nèi)等價(jià)場(chǎng)的影響不同，物質(zhì)體“場(chǎng)平衡效率”隨其速度或其場(chǎng)內(nèi)斂率

9、S的增加而增加，“場(chǎng)平衡效率”的增加使物質(zhì)體外“場(chǎng)失衡性的場(chǎng)內(nèi)斂區(qū)”以一定程度減小，當(dāng)自體場(chǎng)內(nèi)斂率S=0.5時(shí)物質(zhì)在其空間的S0.5區(qū)以外實(shí)現(xiàn)極高程度的場(chǎng)平衡、即在S0.5區(qū)域?qū)崿F(xiàn)ENi=EOi，當(dāng)物質(zhì)體S大于0.5后其“場(chǎng)內(nèi)斂區(qū)”幾乎消失、但“場(chǎng)內(nèi)斂區(qū)”外部的“慢場(chǎng)區(qū)空間”卻隨之增大、同時(shí)慢場(chǎng)區(qū)“場(chǎng)失衡性”的程度也隨之相應(yīng)增大，慢場(chǎng)區(qū)在其主體S0.5時(shí)的特點(diǎn)是“場(chǎng)失衡性”極微弱?？臻g磁場(chǎng)對(duì)物質(zhì)有“等效用”的場(chǎng)擾作用和場(chǎng)平衡作用，以太陽(yáng)系為例：行星距離太陽(yáng)越近其外圍場(chǎng)失衡的程度越小，近距行星因外空間處于場(chǎng)平衡態(tài)造成衛(wèi)星不能夠穩(wěn)定存在（無(wú)需衛(wèi)星存在），太陽(yáng)系遠(yuǎn)距行星需要更多的衛(wèi)星才能夠?qū)崿F(xiàn)其外空

10、間的場(chǎng)平衡，物質(zhì)的場(chǎng)擾作用與場(chǎng)平衡作用最終只能是以物質(zhì)外部的等價(jià)場(chǎng)來(lái)實(shí)現(xiàn)。邊際外等價(jià)場(chǎng)EO與邊際內(nèi)等價(jià)場(chǎng)EN是相互平衡、相互制約的關(guān)聯(lián)關(guān)系，平衡性場(chǎng)行為在通過(guò)EO與EN時(shí)對(duì)兩者都有內(nèi)斂作用，在場(chǎng)內(nèi)斂區(qū)內(nèi)同一個(gè)場(chǎng)擾動(dòng)條件下EN內(nèi)斂程度只有EO的0.604897432倍，也就是說(shuō)場(chǎng)平衡行為每完成1份場(chǎng)平衡效用另產(chǎn)生出0.604897432份失衡性，一個(gè)質(zhì)子如果讓其等價(jià)場(chǎng)的失衡性完全不存在其質(zhì)量就要增加5.061976698倍電子的質(zhì)量值。MP=MO+MeSi1+0.604897432(1+22+33.NN)(MP為質(zhì)子的動(dòng)態(tài)質(zhì)量值，MO為質(zhì)子Si0時(shí)的質(zhì)量值，Me為電子的質(zhì)量值，Si為質(zhì)子動(dòng)態(tài)的場(chǎng)

11、內(nèi)斂率值)三：飽和態(tài)場(chǎng)平衡與局部型場(chǎng)平衡 “飽和態(tài)場(chǎng)平衡”的定義：物質(zhì)“等價(jià)場(chǎng)體系”全范圍完整實(shí)現(xiàn)與“存在環(huán)境Sh”真正對(duì)等的場(chǎng)平衡。“飽和態(tài)場(chǎng)平衡”需要對(duì)象物質(zhì)體在“特定值的Sh環(huán)境”里穩(wěn)定存在極長(zhǎng)時(shí)間才能夠?qū)崿F(xiàn)?！帮柡蛻B(tài)場(chǎng)平衡”的對(duì)象物質(zhì)其“場(chǎng)內(nèi)斂率S值”的改變是一個(gè)極其緩慢的過(guò)程，物質(zhì)體在近距上以快速方式所實(shí)現(xiàn)的場(chǎng)內(nèi)斂率增加為“局部型場(chǎng)平衡”，“局部型場(chǎng)平衡”產(chǎn)生的能量會(huì)被該體系“飽和態(tài)場(chǎng)平衡”的能量逐步稀釋掉，局部型“場(chǎng)內(nèi)斂率S值”的衰退時(shí)間與其形成時(shí)間存在關(guān)聯(lián)關(guān)系，劇烈的場(chǎng)內(nèi)斂率增加能夠一定程度上增加體系中“主體實(shí)體”的質(zhì)量值，物質(zhì)實(shí)體質(zhì)量的衰減速度取決于該體系中所含“局部型場(chǎng)內(nèi)斂”

12、的成份。四：場(chǎng)失衡能QE 場(chǎng)失衡能QE是指一個(gè)對(duì)象物質(zhì)其“等價(jià)場(chǎng)系統(tǒng)”中所存在的“場(chǎng)內(nèi)斂性失衡能的總值”，“場(chǎng)失衡能QE”在概念上不同于量子力學(xué)中的E=hv，E=hv是特定光子對(duì)物質(zhì)或空間的擾動(dòng)能力所產(chǎn)生出的等價(jià)能的描述，正電性對(duì)空間的擾動(dòng)能力與其電荷量間的關(guān)系是倍比關(guān)系、而負(fù)電荷則是某種指數(shù)關(guān)系（注：精確公式作者尚未找到），E=hv是光子負(fù)電荷達(dá)到“特定臨界值”后、光子“負(fù)電性成分”在與空間交互作用過(guò)程中所產(chǎn)生出的熱吸收與熱輻射能力的反央，正電性的“場(chǎng)內(nèi)斂區(qū)”相對(duì)縮小能夠強(qiáng)化物質(zhì)正電荷對(duì)空間的擾動(dòng)能力，物質(zhì)在S0.5時(shí)對(duì)空間的擾動(dòng)能力最小，因?yàn)镾0.5時(shí)粒子“失衡性的場(chǎng)內(nèi)斂區(qū)”幾近消失、且整

13、個(gè)體系處于最理想的場(chǎng)平衡態(tài)。電子對(duì)質(zhì)子的逃逸動(dòng)能由質(zhì)子場(chǎng)失衡能QE的減少所賦予。QEi=EOi-ENi （QEi為物質(zhì)等價(jià)場(chǎng)體系“一對(duì)相鄰子單元”的場(chǎng)失衡能）QE=QEi （在粒子等價(jià)場(chǎng)空間S=0至S=1區(qū)間）QE=（1-2Si ）limQE （limQE為一個(gè)體系存在的最大值場(chǎng)失衡能，Si為該物質(zhì)體系的飽和態(tài)場(chǎng)內(nèi)斂率，粒子Si0時(shí)其等價(jià)場(chǎng)在近程上帶有正最大值的場(chǎng)失衡能，粒子Si=1時(shí)其等價(jià)場(chǎng)在遠(yuǎn)程上的大范圍空間里系統(tǒng)性帶有負(fù)最大值的場(chǎng)失衡能。） Si0.5的粒子離開(kāi)“等價(jià)存在環(huán)境Sh”后從其“等價(jià)場(chǎng)系負(fù)電荷”與空間的作用中獲得動(dòng)力，物質(zhì)Si值如大于所在空間的Sh值就會(huì)受到空間里排斥性的“Sh

14、值守衡張量力”，外在因素在短期內(nèi)并不能夠改變物質(zhì)的飽和態(tài)場(chǎng)內(nèi)斂率，“Sh值守衡張量”能夠使空間始終以場(chǎng)平衡的方式存在，正電性在近程上以“能量的相對(duì)集中存在”來(lái)反央，負(fù)電性以“能量大范圍系統(tǒng)性分散存在的方式”來(lái)反央。五：電子勢(shì)能阱質(zhì)子場(chǎng)內(nèi)斂失衡最大的區(qū)域（S0.5區(qū)域附件）為“電子勢(shì)能阱”，“電子勢(shì)能阱”是電子創(chuàng)生的環(huán)境，電子對(duì)質(zhì)子的逃逸能量由質(zhì)子總體的場(chǎng)失衡能QE減少所賦予，質(zhì)子的場(chǎng)內(nèi)斂率從S0S=0.5發(fā)展時(shí)、場(chǎng)內(nèi)斂失衡區(qū)向質(zhì)子中心區(qū)壓縮、場(chǎng)能量也向質(zhì)子中心區(qū)匯聚（因電子逃逸后失衡區(qū)的場(chǎng)平衡有場(chǎng)能量替代），質(zhì)子S1時(shí)質(zhì)子場(chǎng)內(nèi)斂失衡的能量與場(chǎng)內(nèi)斂平衡的能量?jī)烧呷哭D(zhuǎn)換成質(zhì)量，在質(zhì)子場(chǎng)內(nèi)斂率由S

15、1S0發(fā)展時(shí)、場(chǎng)內(nèi)斂失衡區(qū)外移、同時(shí)場(chǎng)內(nèi)斂平衡的場(chǎng)能量也向質(zhì)子外圍擴(kuò)散、高能區(qū)的場(chǎng)平衡能量經(jīng)過(guò)S0.5區(qū)時(shí)被“電子勢(shì)能阱”整合為“電子”。六：場(chǎng)內(nèi)斂平衡方程 物質(zhì)體自體的場(chǎng)內(nèi)斂率用S表示，物質(zhì)體存在空間的場(chǎng)內(nèi)斂率用Sh表示。（1）SkS1 (Sk為自然界空間所存在的極限最低場(chǎng)內(nèi)斂率。)（2）Si=Sh (Si=Sh為飽和態(tài)場(chǎng)平衡關(guān)系下物質(zhì)體與存在環(huán)境間的對(duì)等關(guān)系式。)（3）ViSi×2C；Si=Sh；Sh0.5；(Si為對(duì)象體系的飽和態(tài)場(chǎng)內(nèi)斂率值，Sh為對(duì)象體系所在環(huán)境的飽和態(tài)場(chǎng)內(nèi)斂率值；C為光速，Vi為對(duì)象體的向心環(huán)繞速度其大小由所在環(huán)境的場(chǎng)失衡程度所賦予，場(chǎng)失衡程度最大的空間其粒

16、子的運(yùn)動(dòng)速度為光速。）（4）ViSN×2C；SNSh；Sh0.5；（SN為對(duì)象體系局部型或者飽和態(tài)的場(chǎng)內(nèi)斂率值，Sh為對(duì)象體系所在環(huán)境的飽和態(tài)場(chǎng)內(nèi)斂率值。）（5）ViC； 1Si0.5；Sh0.5；（Sh為粒子存在環(huán)境的飽和態(tài)場(chǎng)內(nèi)斂率，Vi為粒子的運(yùn)動(dòng)速度，Si為粒子的飽和態(tài)場(chǎng)內(nèi)斂率，C為光速；）（6）Vi（1-Si）×2C；1Si0.5，SiSh，（C為光速。）七：靜態(tài)場(chǎng)內(nèi)斂率對(duì)應(yīng)性關(guān)聯(lián)方程（場(chǎng)平衡效率方程）Si=RO/；(Si為一個(gè)飽和態(tài)場(chǎng)平衡的物質(zhì)體系“場(chǎng)內(nèi)斂率值”在其周邊空間距離上的分布（含星系、宏觀天體、微觀粒子不含光子），RO為常數(shù)半徑、RO2為一個(gè)體系場(chǎng)內(nèi)斂率

17、S等于1的區(qū)域，Ri為對(duì)象體到體系中心的瞬時(shí)距離,“場(chǎng)平衡施體”的Ri越小其場(chǎng)平衡的效率越高、其外部具有電荷性特征的場(chǎng)內(nèi)斂區(qū)空間越小，太陽(yáng)系行星的RO值見(jiàn)表1。)太陽(yáng)系各天體的RO值（表一）平均公轉(zhuǎn)速度（KM/秒）公轉(zhuǎn)周期（天）軌道半長(zhǎng)軸（KM）各行星計(jì)算出的太陽(yáng)RO值（KM）各行星的RO值（KM）太陽(yáng)220.00水星47.5003504387.9690857909050.01.886584946金星35.02006027224.701108208000.01.908727573地球29.78381512365.24219149587443.71.9086534030.001057109火星2

18、4.08920653686.98227925000.01.9040217290.000331074木星13.073312644328.9778547200.01.9108797510.018773829土星9.68962766110752.171433449369.51.921652280.010296588天王星6.79455862430778.013992876679082.51.9090982630.004019555海王星5.44441051260152.04503443661.51.9143328090.004358451M0=4/3(RO3)K (M0為一個(gè)物質(zhì)體系實(shí)體的質(zhì)量值，R

19、O為該物質(zhì)體系的常數(shù)半徑，K為常數(shù)) 光子在自然界里沒(méi)有合適的場(chǎng)平衡施體存在、其“場(chǎng)內(nèi)斂”不能夠最終演化成Si=RO/的平方反比分布規(guī)律，光子“等價(jià)場(chǎng)系空間”不存在大值QE的區(qū)域，光子的場(chǎng)失衡能QE以極微弱、相對(duì)勻化、大范圍分布為特征，這種特征使光子“飽和態(tài)場(chǎng)內(nèi)斂率值”改變所需的時(shí)間更長(zhǎng)，光子相互間所具有的“遠(yuǎn)距糾纏能力”與光子場(chǎng)能量的大范圍分布特征有關(guān)。八：靜止質(zhì)量（1）物質(zhì)的“動(dòng)能質(zhì)量”VM公式：VMM0×Si；（M0為一個(gè)物質(zhì)實(shí)體的質(zhì)量值，Si為該體系的飽和態(tài)場(chǎng)內(nèi)斂率；）（2）物質(zhì)的“阻動(dòng)質(zhì)量”FM公式： FMM0(1Si)；（3）：“靜止質(zhì)量”M公式： M（FMVM） MM0

20、(1-2Si )；當(dāng)物質(zhì)Si0.5時(shí)成為正質(zhì)量物質(zhì)、力學(xué)作用的來(lái)源為近程上的“場(chǎng)內(nèi)斂區(qū)”占主導(dǎo)（即場(chǎng)內(nèi)斂區(qū)ENiEOi）；當(dāng)物質(zhì)Si0.5時(shí)成為電中性物質(zhì)；當(dāng)物質(zhì)Si0.5時(shí)成為負(fù)質(zhì)量物質(zhì)；當(dāng)物質(zhì)Si0.5、存在環(huán)境的Sh0.5時(shí)其在近程上表現(xiàn)為電中性，而在遠(yuǎn)程上（慢場(chǎng)區(qū)）表現(xiàn)為極微弱、相對(duì)勻化、大范圍分布的負(fù)電性（即慢場(chǎng)區(qū)由近似平衡態(tài)變?yōu)橄鄬?duì)較明顯的EOiENi）、并且其靜止質(zhì)量為零值。一對(duì)反物質(zhì) Si從0至0.5區(qū)的質(zhì)子帶正電荷其電子帶負(fù)電荷（電子Si0.5），Si大于0.5的質(zhì)子帶負(fù)電荷其電子帶正電荷（電子Si0.5）、但條件是質(zhì)子的Si值必須在S0.5上下的近區(qū)，物質(zhì)系間引力或斥力的力

21、學(xué)關(guān)系用物質(zhì)自體的場(chǎng)內(nèi)斂率S和物質(zhì)存在空間的場(chǎng)內(nèi)斂率Sh來(lái)描述。limF=M0·S·g (limF為物質(zhì)間的最大引力，M0為該粒子的質(zhì)量值，S為物質(zhì)進(jìn)入一個(gè)系統(tǒng)處于穩(wěn)定態(tài)后所增加的場(chǎng)內(nèi)斂率，g為常數(shù)。）九：力程方程L（RO2）/（Si2 ）；Si=Sh； （L為粒子的力程，R02為一個(gè)粒子“場(chǎng)內(nèi)斂率”等于1區(qū)域的半徑，Si為該體系的“飽和態(tài)場(chǎng)內(nèi)斂率”，Si0.5的粒子在Si=Sh的環(huán)境里其力程隨Si的增加而減小。）十：場(chǎng)屏蔽的雙向性、場(chǎng)分離 一個(gè)體系內(nèi)物質(zhì)間的關(guān)系既是“相互擾體”的關(guān)系又是“相互場(chǎng)平衡施體”的關(guān)系，“場(chǎng)平衡施體”與主體粒子間存在“雙向場(chǎng)內(nèi)斂效應(yīng)”，自然界質(zhì)量

22、最小的粒子或者近程上不能夠存在“場(chǎng)平衡施體”的粒子其“場(chǎng)內(nèi)斂率S值”有機(jī)會(huì)達(dá)到自然界“場(chǎng)內(nèi)斂率的極限最小值SK”，粒子場(chǎng)內(nèi)斂的能力與其質(zhì)量值成正比、可以推導(dǎo)出光子的場(chǎng)失衡能只能以“相對(duì)系統(tǒng)性分散的方式存在”而不能夠演化為“在近程上以相對(duì)集中的方式存在”，大質(zhì)量粒子因“場(chǎng)平衡施體”對(duì)其“等價(jià)場(chǎng)體系”的擾動(dòng)作用其“場(chǎng)內(nèi)斂率S的極限最小值”相對(duì)要大的多，大質(zhì)量“主體粒子”的運(yùn)動(dòng)速度受制于其“場(chǎng)平衡施體”對(duì)其所帶“電荷能”的屏蔽作用?！案逽值粒子”的場(chǎng)能量會(huì)被系內(nèi)“場(chǎng)內(nèi)斂的能量系”所屏蔽，屏蔽的結(jié)果造成粒子等價(jià)場(chǎng)與其實(shí)體的分離，場(chǎng)分離是造成粒子量子糾纏態(tài)的根源之一。十一：輻射光子與其主體場(chǎng)內(nèi)斂率的關(guān)系

23、Sp=Si (Sp為輻射光子的場(chǎng)內(nèi)斂率，Si為輻射粒子的場(chǎng)內(nèi)斂率；)十二：慢場(chǎng)區(qū)的手征性 Si小于0.5的粒子與Si大于0.5的粒子相比較其“手征性的規(guī)律相反”，宏觀體系其空間Si0的廣大區(qū)域?yàn)椤奥龍?chǎng)區(qū)”，宏觀體系“慢場(chǎng)區(qū)”的“宏觀系手征性”與“微觀粒子Si值”大于0.5的粒子相同,宏觀天體外圍的“慢場(chǎng)區(qū)”有數(shù)量龐大的Si值近似等于0的“慢物質(zhì)”構(gòu)成，“慢場(chǎng)區(qū)”大量“慢物質(zhì)”的存在是一個(gè)體系“場(chǎng)平衡”的需要。十三：場(chǎng)內(nèi)斂率S的波動(dòng)性特征主體粒子“場(chǎng)失衡性”在空間的分布規(guī)律由所在空間（包含廣域概念的空間）總體的磁波擾動(dòng)規(guī)律所支配，“場(chǎng)平衡機(jī)制”需要一個(gè)傳導(dǎo)過(guò)程、期間粒子在廣域空間所受到的“場(chǎng)擾動(dòng)

24、”能增加粒子的S值，場(chǎng)平衡機(jī)制的傳導(dǎo)過(guò)程造成粒子“場(chǎng)內(nèi)斂S值”的波動(dòng)，“場(chǎng)平衡施體”距離“主體粒子”越近其S值的波動(dòng)幅度越小。十四：場(chǎng)慣勢(shì)物質(zhì)的運(yùn)動(dòng)屬性（速度、自旋與軸傾斜）由空間的“場(chǎng)擾動(dòng)因素”所造成，在“飽和空間系統(tǒng)里”任何“場(chǎng)擾動(dòng)因素”以空間場(chǎng)內(nèi)斂率的變化來(lái)反央，將“物質(zhì)場(chǎng)擾動(dòng)因素”在空間所產(chǎn)生的能量稱為“場(chǎng)擾能”，“場(chǎng)擾能”存在“外延”與“內(nèi)延”兩種傳導(dǎo)方式，外延：在空間“Sh值守衡張量”的平衡下“場(chǎng)擾能”趨于向“事件點(diǎn)”的外部空間傳導(dǎo)、并實(shí)現(xiàn)逐步消弱，內(nèi)延:“場(chǎng)擾效應(yīng)”在“場(chǎng)內(nèi)斂”機(jī)制下向“主體質(zhì)心區(qū)”的最內(nèi)部傳導(dǎo)，物質(zhì)外在的等價(jià)場(chǎng)來(lái)源于物質(zhì)的質(zhì)心體，物質(zhì)的“動(dòng)能信息”在源頭上存儲(chǔ)于

25、其“質(zhì)心體”，物質(zhì)的“動(dòng)能”依靠其“等價(jià)場(chǎng)”與空間中場(chǎng)的相互作用來(lái)實(shí)現(xiàn)，物質(zhì)的“等價(jià)場(chǎng)系”與其“質(zhì)心體”是“統(tǒng)一體”的關(guān)系，低S值的物質(zhì)處在相對(duì)高的Sh環(huán)境里時(shí)其外部空間的“場(chǎng)擾能信息”在“質(zhì)心區(qū)”逐步由外向內(nèi)存儲(chǔ)、同時(shí)其“等價(jià)場(chǎng)系統(tǒng)”由內(nèi)向外調(diào)整能量信息，當(dāng)飽和態(tài)的高S值物質(zhì)進(jìn)人“低能環(huán)境”時(shí)其“等價(jià)場(chǎng)系”與“質(zhì)心體”所存儲(chǔ)的能量信息就會(huì)按照存儲(chǔ)時(shí)的相反時(shí)間順序逐步釋放，物質(zhì)“質(zhì)心區(qū)”的能量信息存儲(chǔ)用“飽和態(tài)場(chǎng)內(nèi)斂機(jī)制”來(lái)描述，將物質(zhì)“場(chǎng)擾能信息”的存儲(chǔ)與釋放機(jī)制稱為“場(chǎng)慣勢(shì)”，“場(chǎng)慣勢(shì)”是物質(zhì)慣性的來(lái)源。 論文結(jié)論：（1）物質(zhì)間的引力除了與質(zhì)量值、相互間的距離大小有關(guān)外還與各自的內(nèi)在屬性（

26、S值）和存在環(huán)境的（Sh值）有關(guān)聯(lián)。（2）宏觀體系中天體的動(dòng)能演化由體系整體的場(chǎng)內(nèi)斂平衡被破壞所賦予，在體系場(chǎng)平衡態(tài)不被任何改變的前提下一個(gè)物質(zhì)體系內(nèi)主體與各場(chǎng)平衡施體的質(zhì)量值與能態(tài)會(huì)被鎖定。（3）天體在低S值的環(huán)境里不會(huì)形成黑洞，在宇宙的最極限條件下（Sh=1）任何粒子以場(chǎng)能的方式存在。（4）空間只要存在失衡性就必然存在物質(zhì)（運(yùn)動(dòng)態(tài)或相對(duì)靜止態(tài)的物質(zhì)），宇宙的起源與演化以“等價(jià)場(chǎng)力學(xué)”的飽和時(shí)空觀來(lái)衡量:星系體系的演化不可能存在突變，“星系體系”過(guò)于龐大時(shí)超大型星系間的空檔區(qū)也會(huì)越大，這些空檔區(qū)足夠大時(shí)在場(chǎng)內(nèi)斂機(jī)制下會(huì)形成新的星系，空檔區(qū)新星系的發(fā)展會(huì)對(duì)大型星系的大型化發(fā)展形成制約，宇宙演化

27、是在向大型化和小型化兩個(gè)方向演化。引文：【1】王明理.場(chǎng)內(nèi)斂平衡方程組J.科技視界，2015(27):341-344【2】美國(guó)俄亥俄州的IMB探測(cè)器（the Irvine-Michigan-Brookhaven detector）關(guān)于質(zhì)子衰變研究公布的數(shù)據(jù)?！?】日本超級(jí)神岡探測(cè)器關(guān)于質(zhì)子衰變研究公布的數(shù)據(jù)?！?】歐洲大型強(qiáng)子對(duì)撞機(jī)(Large Hadron Collider)高能對(duì)撞中新生粒子質(zhì)量衰減公布的數(shù)據(jù)。 Basic Principle of Equivalent Field MechanicsSummary:The unitary of Gravitation, Electric

28、Charge Force, Weak force and Strong forceis one of the majorphysics researches, Standard Model shall be growing up from the soil basis of the Quantum mechanism, and the Standard Model may demonstrate the unitary of magnetic, weak and strong force, but none of the existing theories in the current wor

29、ld can achieve the unitary of above four force.In nature, there are many phenomena for which current existing theoriesmay fail to placeproper explanation, such as:(1) The proton will never decay, electrons follow Perpetual Motion around the proton constantly; (2) There can be gigantic force existing

30、 among quarks but simultaneously being in presence of Asymptotic Freedom; (3) The forming mechanism of the Quantum Entanglement; (4) Among the particles borne in high-energy collision, MassAttenuation of some particle could be very fast and comparatively the others may remain quite stable; (5) The s

31、ource of Inertia Potential of material; (6) The formation mechanism of heat absorption and radiation; (7) The origin of unitary of four forces; (8) The source of the static mass of material; (9) The origin of the positive and negative material;(10) The spin and tilt of celestial body, etc.In basis o

32、f the above mentioned phenomena, the Article shall be able to explain the above problems bythe Equivalent Field Mechanism architecture, the Equivalent Field Mechanics can place appropriate explanation by logical reasoning. There will mainly be three innovations in the Paper:(1) Field Introversion ca

33、n be the origin of the material heat absorption, Field Introversion and Field IntroversionBalance concepts can be applied inunitary of these four forces, Field Introversioncan be a kind of Field Reciprocity Mechanism among the substance, the Field Introversion Rate can be well threaded together the

34、variation of four mechanical characteristics of the material gravitational force, electronic charge force, weak force and strong force;(2) The Article will demonstrate the Correspondent Correlation Equation of the Static Field Introversion Rate (excluding photons), by which it can precisely calculat

35、e out the quality value of the subject by simply substituting the orbit cycle and radius of the object substance to the subject body without requiring the mass value of the objective substance,; (3) On the basis of the Correspondent Correlation Equation of the Static Field Introversion Rate,the conc

36、ept of the Saturated Field Introversion could be proposed, and then leading to the concept of being in presence of systematic Saturated Field Balanced for the Correspondent Correlation Equation of the Static Field Introversion Rate, and furthermore the conservation of value of the specific Field Int

37、roversion Rate of the specific spatial area, and eventually being derived the existence of Conservation Tensor of the Field Introversion Rate, and the Spatial SHValue Conservation Tensor can bring a repulsion effect on outer substances, as well as some certain resistance and repression for the Appre

38、ciation Behavior of the Field Introversion of the internal substances in the system.Compared with the Standard Model, the Equivalent Field Mechanicscan be established and developed a fullynon-parameterized theoretical system, the theoretical system willcontain the macroscopic celestial bodies, black

39、 holes, and interaction and evolution of various microscopic particles.Equivalent Field Mechanicscould seemingly be still in the very beginning stage now, and a large number of important equations have still notbeencompleted yet, many new contradictions and problemsmight occuralong with the developm

40、ent, I expect more professionals can participate in the creation of the theoretical system.Key Words: Equivalent Field;Field Introversion; Field IntroversionBalance;Field Introversion Rate, S; Field Imbalances Energy, QE; Saturated Field Balance;Electronic Potential Trap;Field Inertia Potential;1:Eq

41、uivalent Field PrincipleOuter Sub-Unit of CentroidInner Sub-Unit of centroidOuter Sub-Unit of External Marginal Equivalent Field, EOiInner Sub-Unit of Internal Marginal Equivalent Field, ENiExternal and Internal Marginal Equivalent Field shall alternately derived outward the outer space. Figure 1: E

42、quivalent Field TheoryTheoretical Hypothesis: There would be an Equivalent Field System existing surround the peripheral of the autogenous entity and having the same mass energy value in any physical body, the Equivalent Field system should be constituted of Infra-marginal Equivalent Field System (E

43、N) and Outside Marginal Equivalent Field System (EO), and their total field energy should be in equal, EN=EO,EN and EO should be constituted by their own subsidiary units, and theirsub-unitsshould be alternatelyderiving and extending to external space, a pair unit formationbeing adjacent of EN and E

44、O could be called as ENi and EOi, the distribution law of magnetic field flow of ENi and EOi could be anti-semmetry relationship (Figure 1). In overall, EO system being located in the external range of the EN system, and its space location relationship makes the density of the ENi magnetic field ene

45、rgy could be greater than that of EOi atvery slight degree, the equivalent field system could systematically be interfered by the magnetic wave in space and leading to Field Introversion, the differentiation of the field energy density of the sub-unit ENi and EOi may lead to different extinction deg

46、ree by the space magnetic wave. This difference may envoy different Field Introversion degree of EN and EO, the filed introversion degree may be greater and on the contrary that of EO may be slighter, the deviation of the Field Introversion effect shall eventually be accumulated in a relatively clos

47、e space of single system (Figure 2), the specific space field imbalance degree would be represented by Field Introversion Rate, S, and the energy taken by the interaction of the space magnetic wave could be shown as an increase of the autogenous Field Introversion Rate, S, the value of the Field Int

48、roversion Rate, S can determine the movement property of physical body and the distribution features of space field imbalance.The essence of Field Introversionaresome kind of energy transmitted in relatively close range space of the system by the natural acting of the interactive effect of the space

49、 magnetic waves, and the Field Introversion energy shall be existing in some kind of imbalanced way, heat absorption could be the acting result of the magnetic field of the broaddomain space, and the heat radiation could be the systematic balance result causedbyField Introversion, the capacity of th

50、e particles heat absorption as well as radiation shall be balanced in relations, heat absorption capacity of particle shall be specifically associated with its Field Introversion Rate, S. The entering of materials inward the saturated space systemcould trigger an imbalance of the Field Introversionb

51、alance, and the space magnetic wave can be the result of the balance of a saturated space system. The variation characteristics of magnetic wave of a single system in space distribution shall be some certain kind of regularity. In relatively stable saturated conditions, the more the energy passing t

52、hrough in a certain period, the bigger the magnetic fluctuation rate produced by field balance act in the recent area. This distribution regulation shall also be precisely described as the Field Introversion Rate, S. The reciprocal field perturbation existing in the materials shall cause an increase

53、 for Field Introversion value of any object in one single system, and Field Introversion shall be a mechanism of interaction or reciprocal effect among substances.2:The Field IntroversionBalance TheoryFigure 2: Field Introversion Balance TheoryOuter Sub-Unit of CentroidR, RadiusNegativeExternal Marg

54、inal Equivalent Field, EOExtreme Low Saturated Balance Area, SKExtreme Boundary of the SystemSlow Field AreaPositive Material AreaFast Field Area(Negative Material Area)ElectropositivityInternal Marginal Equivalent Field, EN(Macroscopic) Slow Field Area should realize balance with EO by existing ele

55、ctropositivity material.Space should reach balance with EN by the perturbation of electroposivity material.Boundary of the Approximate Balance AreaSpace should reach balance with EN by perturbation of electronegativity material.Field Energy, EImbalance AreaBoundary of Effect Area for Mass Value Boun

56、dary of Extreme High-Energy AreaIncreaseDecreaseR=0 (Centroid Point)Material system Field Introversion leads to field imbalances in its surrounding close region, that the field imbalance shall be interfered by required specific substance towards the infra-marginal equivalent field in the space, and

57、so as to the degree of the Field Introversion may reach the balance with the external equivalent field, the field balance Perturbation act of the infliction shall act the role of increasing for the Field Introversion of the outer marginal equivalent field, and reducing for the infra-marginal equival

58、ent field (Figure 2). The existing matter shall be the offspring of the space Field Introversion out-of-balance, macro system Field Introversion balance theory: for one single macroscopic system, the total biomass value of positive electrical slow material existing in the slow field space outside the Field Introversion space shall be equal to the difference of total