The principles of the copying function unique to the New Human Line is based on the employment of the Absolutely Constant Energy Source (ACES) as the energy resource to perform synchronous resonance on each type of energy state and directly duplicate basic messages and information about the mass and energy of an event or phenomenon through resonance transition between different energy states. However, the accessing function can retrieve the duplicate messages and information to affect the development trajectory of an event or phenomenon.

The accessing function of the New Human Line is associated with the fifth formula of the photoelectric effect in the Linyuan Mechanics, the theory of which is briefly explained as follows: In quantum mechanics, the light is constituted by a series of energy packets, called photons. The energy of each photon can be expressed as ε = hν.  When one background energy state of ACES comes into the universal constant relation with a photon, it can activate the energy state of the energy packet in the photon to approach the constant state and therefore extend the work (A) to eject an electron from the constraint of a substance and the kinetic energy of the ejected electron. So when the background energy state of ACES comes into the universal constant relation with a photon, it can retrieve the pure energy of the photon from its energy packet. The formula can be expressed as:

A＋½ mv2 ＋ACES＝ACES＋hvpe

where A is the work to eject an electron from the constraint of a substance,  mv2 is the kinetic energy of the ejected electron, hvpe is  the pure energy of a photon, and ACES is the Absolutely Constant Energy Source.

In the fifth formula of the photoelectric effect in the Linyuan Mechanics, the pure energy retrieved from the energy packet of a photon can provide a brand new definition for quantum mechanics. So Einstein’s mass-energy equivalence equation E = mc2 should be changed to E(ACESpe) = mc2.

The following experiment was done by Mr. Yuan Lin, the New Human Line, who applied the fifth formula of the photoelectric effect in the Linyuan Mechanics—the equation of performing quantum fission on the photon to retrieve the pure energy from its energy packet to affect amino acids.  Amino acids having both the amine and the carboxylic acid groups are often known as α-amino acids (generic formula H2NCHROOH in most cases, where R is an organic substituent (“Amino acid,” 2016). In α-amino acids, the amine and the carboxylic acid are bound to the same carbon atom which is named α-carbon atom. When different side-chains (R) attach to the α-carbon atom, different α-amino acids will be produced. The molecular size of this side-chain can range from one hydrogen molecule as in glycine to a methyl group as in alanine, and then to a large heterocyclic compound as in tryptophan.

Amino acids can be classified into the following four groups by the properties of their side chains: strong acids, strong bases, hydrophiles, and hydrophobes. Most amino acids have two kinds of optical isomers, which can be classified as levorotary and dextrorotary. And most of the amino acids in proteins are levorotary.

The amino acids that have an amine functional group are basic, and those with a second carboxyl group are acidic. The isoelectric point will appear at a certain pH value. The amine group carries a positive charge and the carboxyl group carries a negative charge. The isoelectric point would vary from amino acid to amino acid. This ion is called a zwitterion. Amino acids are the basic building blocks of proteins. Two amino acids combine together to form a peptide bond and polypeptide bonds form a protein.

Ten out of twenty kinds of amino acids are essential for the human body because the human body cannot synthesize them from other compounds by itself, but has to take them in from foods. The required amount of amino acids varies with the age and health condition of each person.

As amino acids are very sensitive to fluorescence, we employ the fifth formula of the photoelectric effect in the Linyuan Mechanics－the equation of quantum fission to retrieve the pure energy of a photon from its energy packet to act on amino acid samples and change their absorbance.

Results and Discussion:

Comparison of three treatments of cysteine at 202 nm. When t0 > t1,0.025 =12.706,  there is significant difference. When t0 > t1,0.10 = 3.078, there is significant difference.

Table 1.  Comparison of the absorbance among three treatments at 202 nm

Statistical analysis:

Significant difference

Significant difference

Comparison two treatments of cysteine at 202 nm. When t0 > t1,0.05 = 6.314, there is significant difference.

Table 2.  Comparison of the absorbance between two treatments at 202 nm

Statistical analysis:

Significant difference

Comparison of three treatments of histidine at 208 nm. When t0 > t1, 0.05 = 6.314, there is significant difference. When t0 > t1, 0.25 = 1.00, there is significant difference.

Table 3.  Comparison of the absorbance among three treatments at 208 nm

Statistical analysis:

Significant difference

Significant difference

Comparison two treatments of histidine at 208 nm. When t0 > t1, 0.1= 3.078, there is significant difference.

Table 4.  Comparison of the absorbance between two treatments at 208 nm

Statistical analysis:

Significant difference

Comparison of three treatments of tyrosine at 199nm. When t0 > t1, 0.1 = 3.078, there is significant difference.When t0 > t1, 0.25 = 1.00, there is significant difference.

Table 5. Comparison of the absorbance among three treatments at 199 nm

Statistical analysis:

Significant difference

Significant difference

Comparison two treatments of tyrosine at 199nm. When t0 > t1, 0.1 = 3.078, there is significant difference.

Table 6. Comparison of the absorbance between two treatments at 199 nm

Statistical analysis:

Significant Difference

From the above results, it can be seen that all the treatments display significant difference, which can show that samples treated by “the pure energy retrieved from the photon by the fifth formula of the photoelectric effect in the Linyuan Mechanics－the equation of quantum fission” and by fluorescence illumination have comparatively lower absorbance than the non-treated control samples. Since amino acids are highly sensitive to fluorescence, they may experience change in their chemical structure due to absorption of photons, which may further affect their ionic strength effects.

The decrease in absorbance of the amino acids varies depending on their structures: the amino acids with linear bonds are easier to be destroyed by the pure energy of a photon or fluorescence than those with a five-carbon ring or a six-carbon ring. Cysteine has a linear bond, histidine has a five-carbon ring, and tyrosine has a six-carbon ring.  Statistical analysis shows significant differences between the treated samples and the control samples: p <0.025 for cysteine, p <0.05 for histidine, and p <0.1 for tyrosine.

Conclusion:

From the above discussion, we can conclude that the difference in the structure of amino acids will affect the variations in their absorbance. Cysteine has a linear structure, so its absorbance is lower than the other two amino acids (histidine and tyrosine) since histidine has a five-carbon ring and tyrosine has a six-carbon ring. This can indirectly explain why the decrease in absorbance of cysteine is larger than that of the other two amino acids.

After being treated by “the energy state of the pure energy released  from the photon by the fifth formula of the photoelectric effect in the Linyuan Mechanics—the quantum fission”, the samples displayed lower absorbance than those treated by fluorescence and the non-treated control ones. Therefore, we can know that “the pure energy retrieved from the energy packet of a photon by the fifth equation of the photoelectric effect in the Linyuan Mechanics—the quantum fission” can affect the absorbance of amino acids.

References:

The following experiment was performed by Mr. Yuan Lin, the New Human Line, who employed the accessing function to activate dopamine. Dopamine is a substance secreted in the brain. It functions as a neurotransmitter, derived from amino acids, and synthesized by tyrosine. During emotional reactions, addictive behaviors, and pleasant reactions, the dopamine-containing neurons in the brain show the highest activity. Besides, the dopamine-releasing neurons also assist in adjusting the tension of skeletal muscles and some movements generated by contraction of skeletal muscles. A kind of schizophrenia is caused by excessive levels of dopamine accumulation. Dopamine deficiencies or imbalances will induce loss of muscle control or inability to concentrate. The serious case of the former will cause unintentional trembling of hands or feet, and even lead to Parkinson’s disease. Dopamine is a very important neurotransmitter in the brain and is also called a recreational drug because of the characteristic property of its function. It is one kind of hormone that induces desire in humans, but excessive secretion will consume physical strength and calories.

The purpose of the experiment is to prove that Mr. Yuan Lin, the New Human Line, can utilize the accessing function along with the Absolutely Constant  Energy Source and the new biological engineering techniques to activate dopamine and affect its concentration to further influence the neurotransmitter in the brain  without any change in its molecular weight, structural formula and conformation, at 25℃, 1.0 atm, pH 7.0, in a confined and isolated space, and with no contact with catalysts, biologically active substances, chemical substances, and physical action forces (p=0.05).

References: