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科学、技術、工学、医学(STEM)分野に焦点を当てています | ISSN: 2995-8067  G o o g l e  Scholar

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IgMin Research | マルチディシプリナリーオープンアクセスジャーナルは、科学、技術、工学、医学(STEM)の広範な分野における研究と知識の進展に貢献することを目的とした権威ある多分野のジャーナルです.

Biology

Physical Chemistry at IgMin Research | Biology Group

私たちの使命は、学際的な対話を促進し、広範な科学領域にわたる知識の進展を加速することです.

について

Physical Chemistry is a fascinating branch of chemistry that focuses on the study of the fundamental principles governing the behavior of matter at the molecular and atomic levels. This field explores the interactions between molecules, the energies involved in chemical reactions, and the underlying physical properties of substances. Physical chemistry provides insights into the fundamental nature of chemical processes and their applications.

Physical chemists investigate topics such as thermodynamics, chemical kinetics, quantum mechanics, and spectroscopy. They seek to understand how molecular structures influence chemical behavior, how reactions occur, and how energy is exchanged. The insights from physical chemistry contribute to advancements in materials science, catalysis, energy storage, and environmental chemistry.

  • Thermodynamics
  • Chemical kinetics
  • Quantum mechanics
  • Spectroscopy
  • Molecular structure
  • Molecular interactions
  • Surface chemistry
  • Electrochemistry
  • Photochemistry
  • Computational chemistry
  • Chemical equilibrium
  • Reaction mechanisms
  • Molecular dynamics
  • Nanoscale chemistry
  • Physical chemistry of materials
  • Solid-state chemistry
  • Supramolecular chemistry
  • Catalysis
  • Physical chemistry and energy
  • Physical chemistry education and outreach
  • Advancements in physical chemistry
  • Physical chemistry and environmental science
  • Physical chemistry and industrial applications
  • Physical chemistry and biophysics
  • Physical chemistry and nanotechnology

Biology Group (2)

Research Article Article ID: igmin207
Cite

Open Access Policy refers to a set of principles and guidelines aimed at providing unrestricted access to scholarly research and literature. It promotes the free availability and unrestricted use of research outputs, enabling researchers, students, and the general public to access, read, download, and distribute scholarly articles without financial or legal barriers. In this response, I will provide you with an overview of the history and latest resolutions related to Open Access Policy.

Modeling of Cr3+ doped Cassiterite (SnO2) Single Crystals
by Maroj Bharati, Vikram Singh and Ram Kripal

Using the superposition model, the crystal field and zero-field splitting parameters of Cr3+ doped cassiterite (tin oxide), SnO2 single crystals are computed. For calculations, the appropriate locations for Cr3+ ions in SnO2 with distortion are taken into account. The experimental values and the zero-field splitting parameters in theory with local distortion agree fairly well. Using the Crystal Field Analysis Program and crystal field parameters, the optical energy bands for Cr3+ in SnO2 are calculated. The findings indicate that in SnO2 single... crystals, one of the Sn4+ ions is replaced by Cr3+ ions.

Computational Biology Physical ChemistrySpectroscopyInorganic Chemistry
Short Communication Article ID: igmin163
Cite

Open Access Policy refers to a set of principles and guidelines aimed at providing unrestricted access to scholarly research and literature. It promotes the free availability and unrestricted use of research outputs, enabling researchers, students, and the general public to access, read, download, and distribute scholarly articles without financial or legal barriers. In this response, I will provide you with an overview of the history and latest resolutions related to Open Access Policy.

Comments to Megascopic Quantum Phenomena
by Michal Svrček

We present here the incompleteness of the Copenhagen interpretation regarding the impossibility of explaining the transition from the exact quantum mechanics to the Born-Oppenheimer approximation, where the inaccurate method captures phenomena like spontaneous symmetry breaking, but this is impossible to achieve with exact equations. The solution to this dilemma lies in the revision of quantum field theory which bounds together internal and external (vibrational, translational, and rotational) degrees of freedom in a similar way as the Lorentz ...transformation deals with space and time. This is the only way how to exactly mathematically justify the corrections beyond the Born-Oppenheimer approximation (Born-Huang ansatz). The consequences are overwhelming: It reveals the wrong BCS theory of superconductivity, derived on the basis of the incomplete quantum field, and all erroneous theories inspired by the BCS one (e.g. Higgs mechanism). Moreover, the second Bohr complementarity emerges from the mechanical wholeness and field fragmentation, opening the door for the megascopic mirror of the microscopic Copenhagen interpretation and for the explanation of megascopic quantum phenomena. Finally, we get an entirely new look at the meaning of physics and chemistry: The first one deals with microscopic and the second one with megascopic phenomena.

Quantum Chemistry Physical ChemistryComputational Chemistry