Article 5. The Principal of Thermodynamics: Specific Heat Capacity and Material/热力学原理:比热容与材料
Author: Liu Huan(1983-), Master of Science (First Class Honours), The University of Auckland.
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My article further discusses the ‘heating’ scenario: when the receptor materials is heated by external thermal sources, the thermal energy increases in the receptor materials. Inside the space of receptor molecules (or atoms), the stable effects of constructive interference between the external thermal source of electromagnetic waves and the electromagnetic waves emitted from the receptor molecules (or atoms) becomes the major forces of accelerating the revolution/rotation motion of receptor molecules (or atoms). Consequently, the most efficient ‘heating’ process is the electromagnetic waves from external thermal sources, which have the same frequency as the electromagnetic waves emitted by the molecule motion of receptor objects and show similar amplitude of vibration to the electromagnetic waves emitted by the molecule motion of receptor objects (the amplitude of vibration between these two waves should not show large variation), is able to accelerate the revolution/rotation motion of receptor molecules (or atoms) most effectively. In this definition, the acceleration rate of molecular angular velocity becomes the first indicator of specific heat capacity of the receptor objects.
However, the thermal energy, in terms of temperature ascending or descending capacity, varies among different frequencies of electromagnetic waves. Consequently, if the frequencies of electromagnetic waves emitted by the molecule motion of receptor objects is the frequencies leading to higher thermal energy, in terms of higher thermal energy caused by temperature change per unit, then the specific heat capacity of this receptor object is higher! In this case, the efficiency of specific heat capacity is the not linear relationship with the increased frequency of electromagnetic waves emitted by materials (not received by materials), due to the buffering effects of dark matter. Similarly, the increasing intensity of received electromagnetic waves is not the linear relationship with the specific heat capacity of the receptor objects as well due to different destructive phases in dark matters. This means that the specific heat capacity can show the ‘jumped’ and non-continuous relationship with the received intensity of electromagnetic waves in statistics when it reaches the critical values differentiating each destructive phases in dark matter, so that the past numerical modeling based on the linear regression analysis would be the inexact ones for the chemical engineering of new materials, especially under extreme conditions (review paper to be continued in the coming article next).
See PDF Documents. Fig 1 (PDF Document). The red zone represents the constructive interference zones of two electromagnetic waves; The grey zone represents the destructive interference zones of two electromagnetic waves; The green ‘e’ represents the electrons inside the atom or molecule. This simple graph indicates the electron accelerating process inside the atom or molecule spaces due to the the stable effects of constructive interference between the external thermal source of electromagnetic waves and the electromagnetic waves emitted from the receptor molecules (or atoms). This is the revised materials in book “Proceedings for Degree of Postgraduate Diploma in Environmental Science (3rd Edition).” published in 2016. Revised on 31/12/2020; Secondly revised on 12/06/2021; Thirdly Revised on 09/10/2021. References: 搜狗百科,共享百科全书/Sogou Baike, Creative Commons.
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