Citation:
Thakur, Soumendra Nath; Samal, Priyanka; Bhattacharjee, Deep (2023). Relativistic effects on phaseshift in frequencies invalidate time dilation II. TechRxiv. Preprint. https://www.researchgate.net/publication/370533379
Abstract:
This research delves into the fundamental aspects of atomic and molecular science within the context of classical mechanics, structures, forces, and energy. The introductory section sets the stage by elucidating the pivotal role of atoms, the basic building blocks of chemical elements, and their combination to form molecules. Classical physics principles are employed to explore atomic and molecular density, which holds critical importance in precision calculations and applications.
The subsequent section embarks on a comprehensive exploration of atomic and molecular structures, focusing on their intricate arrangements, crystalline materials, and the profound influence of energy. The piezoelectric effect and piezoelectricity are discussed, shedding light on the unique properties of certain crystals when subjected to mechanical stress. Moreover, the impact of gravitational forces is examined, with detailed equations and discussions on g-forces, weight, and their relationships to mass.
In this classical Newtonian framework, the research further investigates the dynamics of matter and its intrinsic connection to energy, encompassing potential and kinetic energy. Additionally, it elucidates how external forces deform matter, providing insights into the strains and stresses that result. These explorations serve as the foundational underpinning for a more extensive study of matter's length contraction, dilation, time dilation, and related concepts.
Throughout the paper, we maintain a classical physics perspective, setting aside relativistic considerations, and delve into the core principles that govern the atomic and molecular world within the classical Newtonian mechanics framework. The research thus seeks to unravel the intricate web of atomic and molecular science, offering valuable insights into the mechanical and energetic underpinnings of matter.
Keywords: Atomic and Molecular Science, Atomic Density, Classical Mechanics, Crystal Structures, Deformation of Matter, Dilation, Energy in Matter, G-Forces, Gravitational Forces, Kinetic Energy, Length Contraction, Matter-Energy Relationship, Mechanical and Energetic Underpinnings, Mechanical Stress, Molecular Density, Newtonian Mechanics, Piezoelectricity, Potential Energy, Time Dilation, Weight and Mass,
HashTags: #AtomicandMolecularScience #AtomicDensity #ClassicalMechanics #CrystalStructures #DeformationOfMatter #Dilation #EnergyinMatter #GForce #GravitationalForces #KineticEnergy #LengthContraction #MatterEnergyRelationship #MechanicalandEnergeticUnderpinnings #MechanicalStress #MolecularDensity #NewtonianMechanics #Piezoelectricity #Piezomethod #PotentialEnergy #TimeDilation #WeightandMass
Introduction and Fundamental Concepts
In this introductory section, we
lay the groundwork for our exploration of atomic and molecular science,
concentrating on classical mechanics, physics, and other foundational
scientific principles. At the heart of matter are atoms, which serve as the
fundamental building blocks of all chemical elements. These incredibly small
particles consist of a nucleus containing protons and neutrons, surrounded by a
cloud of electrons bound together by electromagnetic forces. Atoms join
together to create molecules, which are groups of two or more atoms held
together by chemical bonds. Within the context of classical physics, we delve
into the concept of atomic and molecular density, which plays a significant
role in precision calculations, particularly in applications like reactor core
design. Atomic density quantifies the number of atoms within a given volume,
while molecular density quantifies the number of molecules within a specific
volume, serving as a valuable metric for comparing the relative densities of
different substances. Furthermore, we discuss matter, defined as anything with
mass and volume, and mass, an intrinsic property closely related to the type
and density of atoms within an object. Density, represented by the formula D = m/v,
signifies the mass per unit volume of a material. This initial section serves
as the foundation for a more detailed exploration of atomic and molecular
structures, their responses to external forces, and their relationship with
classical physics and other scientific principles.
Atomic and Molecular Structures, Forces, and Energy
In this comprehensive exploration, we delve into the intricate world of atomic and molecular structures, as well as the fundamental forces that govern them. We also examine the profound influence of energy in the realm of classical Newtonian mechanics and provide relevant equations for easy reference and to enhance our understanding.
Atomic Structure: At the heart of matter lies the complex arrangement of atoms, comprising a positively charged nucleus encompassing protons and neutrons, around which negatively charged electrons orbit in distinct shells. The atomic mass or weight (W) is measured in atomic mass units (AMU) encapsulates the total mass of an atom, including protons, neutrons, and electrons:
W = Proton Mass (AMU) + Neutron Mass (AMU) + Electron Mass (AMU)
Atomic and Molecular Structure: Every atom consists of a nucleus, consisting of protons and, in most cases, neutrons, and one or more electrons orbiting the nucleus. These entities form the basis for the creation of molecules electrically neutral groups of two or more atoms bonded together by chemical forces. The molecular weight (Wm) is calculated as the sum of atomic weights:
Wm =∑(Atomic Weight of Constituent Atoms)
Atomic or Molecular Structure of Solid Materials: Solid materials can generally be found in two states: ordered and disordered. In the context of classical physics, we predominantly focus on ordered structures, which are crystalline materials. In the case of a crystalline material, the atoms, ions, or molecules are organized in a repeated, three-dimensional pattern. This ordered structure is made up of unit cells, which can be thought of as the building blocks of a crystal lattice. The number of unit cells (Ncells) in a lattice is determined by the number of particles per unit cell (Nparticles per cell):
Ncells = Nparticles per cell × Nunit cells in a Lattice
The Crystal Structure: A crystal structure defines the repetitive arrangement of atoms, molecules, or ions throughout a crystal. It refers to the internal arrangement of particles within the crystalline solid, rather than its external appearance. The crystal lattice represents a symmetrical three-dimensional structure formed by constituent particles inside a crystalline solid. Crystallography plays a vital role in understanding crystal structures, and the mathematical equations governing it are complex but central to crystallography studies.
Piezoelectric
V = d × Mechanical Stress
Where: V represents the potential difference. d is the piezoelectric coefficient.
Piezoelectric Effect: The piezoelectric effect is the converse of the piezoelectricity, results in stress generation within a crystal due to an applied potential difference, leading to the production of electricity. This phenomenon is closely tied to certain crystals, including piezoelectric materials. It can be represented as:
Electric Charge Produced = d × Mechanical Stress
Piezoelectricity: Piezoelectricity denotes the accumulation of electric charge in response to applied mechanical stress in specific solid materials, such as crystals, ceramics, and even biological matter like bone, DNA, and proteins. The underlying principle is closely related to the presence of electric dipole moments within solids. This accumulation of charge can be described by the equation:
Q = d × Applied Stress
Where: Q represents the electric charge accumulated. d is the piezoelectric coefficient.
Gravitational force (G-force): Gravitational
force, expressed in units of standard gravity, mass-specific force. This force
is important for understanding weight and how it affects objects. It plays an
important role in mechanics and leads to the perception of weight. The
gravitational force (F) between two objects can be calculated using
F = G·(m₁·m₂)/r²
Where: F is the gravitational force. G is the gravitational constant. m₁ and m₂ are the masses of two objects. r is the distance between the centers of the two objects.
In the realm of classical Newtonian mechanics, we explore the relationship between force, mass, and acceleration. In straight and level flight, lift equals weight, while a steady level banked turn at an angle results in increased lift and pilot experience of g-forces. The magnitude of these g-forces grows with steeper banks.
The relationship between weight (W), mass (m), and gravitational acceleration (g) is defined as W = mg. The SI unit for weight is the Newton (N), while mass is measured in kilograms (kg).
Force, a key concept in
mechanics, is any action that alters or maintains the motion of a body.
Finally, we explore the connection between matter and energy, where matter possesses energy, including rest energy. Potential energy is stored due to an object's position relative to other objects or other factors. Gravitational potential energy is defined as U = m⋅g⋅h (measured in Joules), while kinetic energy reflects an object's motion, calculated as 1/2 mv² (also in Joules). Matter exhibits resistance to deformation under external forces, with gravitational forces causing internal particles to interact, resulting in stresses and deformations in matter.
This section introduces the intricacies of atomic and molecular structures, mechanical forces, and the interplay of energy in the classical physics framework.
The paper contains stored offline information for all the subsections listed below in their respective sections:
Section 3:
1. Deformation Stress and Strain
Investigating the effects of deformation stress and strain on materials.
2. Arrangement of Atoms and Molecules in Matter
Examining the organization of atoms and molecules within various forms of matter.
3. Energy of Matter
Delving into the relationship between matter and energy, including potential and kinetic energy.
Section 4:
1. Matter Length Contraction and Dilation
Exploring the phenomena of length contraction and dilation in matter.
2. Time Contraction and Dilation
Investigating the concepts of time contraction and dilation, their causes, and effects