虚物质(暗物质)具有8个物质相位的研究
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摘要
提出了低于光速的物质为正物质、等于光速的物质为0(零)物质、超光速的物质为虚物质的概念,这些物质概念是建立新引力场理论的基础。并论证低于光速的正物质(三维空间物质)具有正引力场能,外在表现为放热(或有热辐射),有正引力场(有向心力、正引力)。等于光速的0(零)物质有0(零)引力场,也论证了超光速的虚物质(四维空间物质、暗物质)具有负引力场能,外在表现为吸热,具有反引力场(有离心力、排斥力)。论证了低于光速正物质(三维空间物质)只有1个物质正相位,超光速虚物质(暗物质、四维空间物质)具有8个物质负相位(反引力、负引力),超光速的虚物质(四维空间物质、暗物质)因为具有负引力场能,结果导致了宇称不对称现象。
This paper provided(positive) matter concept,zero matter concept,and virtual matter concept,these matter concepts were basis of establishing gravitation field theory,and the extra-lightspeed matter is virtual matter,this concept is very important. The under-lightspeed positive matter(three-dimension space matter) has the positive gravitation field,it also has the positive gravity,the external expression is exothermic(or having thermal radiation),and there is a positive gravitation field(centripetal force,positive gravity). The equal-lightspeed 0(zero) matter has 0(zero) gravitational field,and the extra-lightspeed virtual matter(four-dimension space matter,dark matter) has the negative gravitation field energy,the external expression is endothermic,has the anti-gravitation field(having the centrifugal force,the repulsion force,anti-gravity). It was demonstrated that the under-lightspeed positive matter(three-dimension space matter) has one matter positive phase,the extra-lightspeed virtual matter(four-dimension space matter,dark matter) has eight matter negative phases(anti-gravity,negative gravity). The extra-lightspeed virtual matter(four-dimension space matter,dark matter) having the negative gravitation field energy,this creates parity asymmetry phenomenon.
This paper provided(positive) matter concept,zero matter concept,and virtual matter concept,these matter concepts were basis of establishing gravitation field theory,and the extra-lightspeed matter is virtual matter,this concept is very important. The under-lightspeed positive matter(three-dimension space matter) has the positive gravitation field,it also has the positive gravity,the external expression is exothermic(or having thermal radiation),and there is a positive gravitation field(centripetal force,positive gravity). The equal-lightspeed 0(zero) matter has 0(zero) gravitational field,and the extra-lightspeed virtual matter(four-dimension space matter,dark matter) has the negative gravitation field energy,the external expression is endothermic,has the anti-gravitation field(having the centrifugal force,the repulsion force,anti-gravity). It was demonstrated that the under-lightspeed positive matter(three-dimension space matter) has one matter positive phase,the extra-lightspeed virtual matter(four-dimension space matter,dark matter) has eight matter negative phases(anti-gravity,negative gravity). The extra-lightspeed virtual matter(four-dimension space matter,dark matter) having the negative gravitation field energy,this creates parity asymmetry phenomenon.
引文
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[29]马国亮.相对论重离子碰撞的输运模型研究[J].原子核物理评论,2017,34(3):370-373.
[2]刘辽,赵峥.广义相对论[M]. 2.北京:高等教育出版社,2004.
[3]俞允强.广义相对论引论[M].北京:北京大学出版社,1987.
[4] Abbott B P,Abbott R,Abbott T D,et al. Observation of gravitational waves from a binary black hole merger[J]. Phys Rev Lett,2016,116(6):1102-1108.
[5]郭汉英,黄超光,田雨,等. Beltrami desitter时空和desitter不变的狭义相对论[J].物理学报,2005,54(6):2494-2501.
[6] Chen Y H. Stellar structure treatment of quadratic gravity[J]. Progress of Theoretical Physics,2001,106(1):63-70.
[7] Chen Y H,Shao C G. Precession of orbiting gyroscope in higher-order gravitational field caused by rotating body[J]. Intern J of Theory Phys,2002,41(7):1377-1387.
[8]周海清,邹冰松.夸克偶素双光子衰变的相对论效应[J].高能物理与核物理,2005,29(6):555-560.
[9]陈光.离散时空中的非塌缩的尘埃球解[J].物理学报,2005,54(7):2971-2977.
[10]张凯,冯俊.相对论Birkhoff系统的对称性与稳定性[J].物理学报,2005,54(7):2985-2989.
[11] Bodwin G T,Petrelli A. Order-v4corrections to S-wave guarkonium decay[J]. Phys Rev,2002,D66:094011-40124.
[12]肖明,龙芸,邓永菊.曲率平方引力场方程的静态轴对称解[J].湖北大学学报(自然科学版),2008,30(3):257-262.
[13]迟爱红,吴亚波.分析力学在广义相对论中的应用[J].辽宁大学学报,2008,35(4):316-321.
[14]袁立新.关于建立涡旋引力场及水星进动与“岁差”运行机制的统一[J].云南大学学报,2012,34(1):24-29.
[15]宋海珍,肖绍武.关于引力场中光速的研究[J].河南师范大学学报,2003,31(4):106-110.
[16]严家利,陈鹏.含温度背景下磁单极引力场的讨论[J].湖北大学学报,1998,20(2):129-134.
[17]孟庆苗,刘景伦,李传安.起源于引力场的Vaidya\Bonner-desitter黑洞的瞬时辐出度[J].贵州师范大学学报,2006,24(4):68-74.
[18]孙鸣超.起源于引力场的Vaidya-Bonner-de Sitter黑洞的量子熵[J].物理学报,2003,52(6):1350-1356.
[19] Jing J L,Yan M L. Effect of spin on the guantum entropy of black holes[J]. Phys Rev,2001,D63:084028-4035.
[20] Li X,Zhao Z[J]. Phys Rev,2000,D62:104001-104006.
[21]宋太平,侯晨霞,史旺林. Vaidya-Bonner黑洞的熵[J].物理学报,2002,51(6):1398-1402.
[22]苏万春.引力场两个定理的探讨[J].电子科技大学学报,2001,30(2):214-206.
[23]杨福家.原子物理学[M]. 4.北京:高等教育出版社,2008.
[24]杜东生,杨茂志.粒子物理导论[M].北京:科学出版社,2015.
[25]胡永红,毛彩霞.宇宙加速膨胀的修正引力理论解释[J].湖北大学学报,2012,34(2):125-129.
[26]范天佑.弱引力场中Einstein引力波简介[J].力学与实践,2016,38:353-358.
[27]陈方培,任洪梅,时家国.视广义相对论及新广义相对论为广义引力理论特殊情况的研究.[J].大连理工大学学报,1993,33(3):269-274.
[28]胡永红,毛彩霞.宇宙加速膨胀的修正引力理论解释[J].湖北大学学报,2012,34(2):125-128.
[29]马国亮.相对论重离子碰撞的输运模型研究[J].原子核物理评论,2017,34(3):370-373.