Navigate the SPIN Funding Opportunities Database effectively with guidance from Karen Markin, Ph.D. Learn how to search by keywords, view results, and access program descriptions. Boost your grant-seeking success!

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Considerable insight was generated from a recent conference on fission, shedding light on crucial theoretical and experimental aspects. Key topics include angular momentum, fission-fragment spin references, and the dynamics of nuclear fission. Theoretical advancements like the TDSLDA model and super

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Examination of spin polarized fuel in fusion plasmas to enhance energy production efficiency. Planned experiments aim to measure the lifetime of polarized nuclei for optimized fusion reactions. Key aspects include depolarization mechanisms, neutral beam heating, and fueling techniques with pellets.

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A fundamental question in astrophysics is how efficiently active galactic nuclei (AGN) produce jets. Black hole spin and magnetic flux play crucial roles in determining the jet production efficiency. High-spin values and large magnetic flux threading are essential for generating high-efficiency jets

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Crystal Field Theory (CFT) explains the colors and magnetic properties of transition metal complexes. It focuses on the energy changes in d-orbitals of metal ions caused by surrounding ligands. This theory, developed in 1929, provides insights into the bonding interactions in complex compounds. The

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The energy of atomic configurations is determined by electrostatic attraction between electrons and the nucleus, electron-electron repulsion, spin-orbit coupling, and spin-spin interactions. Term symbols in electronic spectroscopy specify atomic states using quantum numbers. Hund's rule and the Paul

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Crystal Field Theory (CFT) explains how electron orbital degeneracies, particularly d or f orbitals, are affected by a static electric field generated by neighboring anions. In CFT, the metal ion is considered positive while ligands are negative charges, leading to attractive and repulsive forces af

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The nuclear shell model, a fundamental concept in quantum physics, is explained in detail using Schrodinger wave equations and spherical coordinates. The model describes the behavior of nucleons in atomic nuclei based on energy values, quantum numbers, and shell closure principles. Spin-orbit intera

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Exploring the concept of total angular momentum in quantum mechanics, which involves the quantization of orbital and spin angular momenta. The coupling of these vectors leads to the formation of total angular momentum, with implications for the behavior of single-electron systems like the hydrogen a

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Zero field splitting in ESR spectroscopy involves the relaxation times in ESR and how spin-lattice relaxation affects the spectral width. Discover how T1 value and spin lattice relaxation play a crucial role in observing sharp spectrum lines in EPR. Learn about line widths in ESR, spin dilution, and

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Are you looking for an effective way to shed those extra pounds and boost your fitness level? Look no further than Spin Class Workout! At Cycle Bar, we are passionate about helping you achieve your weight loss goals through the power of Indoor Cyclin

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Nuclear Magnetic Resonance (NMR) spectroscopy is a powerful technique for analyzing molecular structures based on the chemical shifts of protons. In an NMR spectrum, peaks correspond to different protons in a compound, with their positions, intensities, and spin-spin splitting providing valuable inf

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Nuclear reaction rates and cross sections play a crucial role in determining the probability of interactions between particle beams and target nuclei. Cross section is the effective area of a target nucleon to the incident beam, with the interaction probability calculated based on the number density

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Spin workouts, also known as indoor cycling, are an excellent cardiovascular exercise. They help improve heart health, build muscle endurance, and burn calories. One of the most appealing aspects of spin workouts is their versatility.

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Delve into the world of Jablonski Diagram through a comprehensive e-content prepared by Prof. Minakshi Panwar at Christian Eminent College, Indore. Understand energy states, spin, and spin multiplicity in molecules. Discover the concepts of absorbance, non-radiative transitions, and the conversion o

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In this workshop, new measurements of the EMC Effect at 12 GeV were discussed, shedding light on one of the biggest unsolved mysteries in nuclear physics. The discovery, prediction, and quantification of the EMC Effect were explored, raising questions about modifications in nucleon structure within

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Recognize an erect spin as an oscillatory movement about the three aircraft axes with high and low speed AOA. Follow the Corrective Action Procedures (C.A.P.) of throttle idle, full opposite rudder direction, and stick neutral. When the spins stop, maintain rudder neutral, adjust throttle and stick

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Stress management is essential for overall health. Regular physical activity, especially high-intensity workouts like spin classes, is known to reduce stress levels. A 30 Minute Spin Workout provides a concentrated burst of exercise that stimulates t

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Quark Sivers function, a key aspect in quantum chromodynamics, plays a role in capturing orbital angular momentum and spin-orbit coupling. Spin-dependent Odderon, an elusive three-gluon exchange, contributes to cross sections in high-energy collisions. Small-$? TMDs from polarized Wilson lines provi

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Exploring the mechanics of nucleons and the physics goals of the Electron-Ion Collider (EIC), this content delves into the origin of nucleon mass and spin, emergent properties of dense gluon systems, and energy-momentum tensor in QCD. It discusses the role of gluons in understanding nucleon structur

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Explore the intricate details of the three-dimensional structure of nucleons, TMDs, and parton distribution functions in this informative compilation. Delve into the necessity of various distributions to fully characterize proton structure, recommended textbooks for understanding symmetry properties

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Exploration of diffraction dissociation of nuclear nucleons in nucleus-nucleus interactions using Geant4 FTF model and NA61/SHINE results for various nucleus combinations. Insights into meson production in argon-nucleus interactions at different energies and the impact of models like DCM/AGT, UrQMD,

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The discussion covers the relevance and applications of EPR spectroscopy in studying electron behavior, spin-orbit coupling effects, and molecular symmetry. Key concepts include anisotropy, nuclear spin coupling, and deviations in electron g-factors. It delves into how these factors impact the obser

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Understanding how drag and spin influence the flight of a baseball is crucial in explaining phenomena like why fly balls carry better to center field and how sidespin affects distance. Sidespin reduces distance by increasing drag, which competes with lift generated by backspin. The dependence of sid

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Uncover the fascinating world of fidget spinners with a science lesson on spin time measurement techniques, calculating averages, and factors influencing spin time. Dive into hands-on activities, investigations, and discussions on materials used, bearing types, and spinner weights.

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Explore the complex realm of nucleon spin decomposition and the enigmatic proton spin problem, delving into concepts like orbital angular momentum, quarks and gluons' helicity, and longitudinal double spin asymmetry in polarized deep inelastic scattering. Learn about the spin crisis, gluon polarizat

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This study delves into the concept of nuclear symmetry energy through the lens of QCD Sum Rule, discussing its implications in Rare Isotope Accelerator Plan and nucleon-nucleus scattering. Utilizing mean field approximation and Borel transformation, the research aims to understand asymmetric nuclear

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Investigating the modification of nucleon properties in the nuclear medium using QCD sum rules, focusing on hadron properties, mass spectrum, and chiral symmetry restoration. The study discusses the mass differences, non-perturbative contributions, and the analysis of QCD sum rule in nuclear matter.

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Delve into the world of spin magnetism in NMR as we explore the concepts of angular momentum, magnetic moments, Stern-Gerlach experiments, and the quantization of spin. Learn about spin projections, spin relaxation, and the relationship between spin particles and external magnetic fields.

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Featuring various colorful numbers and a spin element, the Tekhnologic image collection includes images of green, yellow, blue, and red elements. The series showcases a playful and vibrant aesthetic, with each number highlighted in a different color. With a total of four sets, the collection offers

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Short-range correlations in nuclei play a crucial role in understanding the properties of nuclear wave functions and the transition from baryonic to quark-gluon degrees of freedom. Early theoretical work emphasized the importance of short-range correlations, particularly in modeling the nucleon spec

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Investigate the nucleon and nuclei structure through inclusive electron scattering at 22 GeV, delving into formalisms and structure functions. Discussions on the Electron Ion Collider, nuclear PDFs, world data comparisons, and definitive proof of three-nucleon short-range correlations at Jefferson L

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This content covers various aspects of nuclear reactions, including nuclear fission, fusion reactions, the Manhattan Project, and examples of reactions involving different particles and elements. It explains concepts like exoergic and endoergic reactions, conservation of charge and nucleon number, a

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Measurements of spin observables in elastic pp and p(bar)p scattering at 16 GeV will be conducted at the SPASCHARM program using a unique setup with polarized proton and antiproton beams. The experiment aims to extend the energy range for spin studies and compare elastic scattering in pp and p(bar)p

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Delve into the fascinating world of higher spin gauge theory, Vasiliev theory, and their applications in AdS/CFT correspondence. Discover the complexity and tractability of higher spin states in superstring theory, as well as the concrete relations between superstrings and higher spin fields in AdS

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Explore the tactics of political spin and propaganda as tools used to shape public perception and manipulate information. Learn about the techniques politicians employ to navigate media dynamics and the covert spin tactics employed in the realm of communication and journalism.

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Theoretical approaches in NMR spectroscopy encompass diverse methods, each with varying degrees of approximation but yielding correct results within their validity. Techniques such as transition probabilities using the time-dependent perturbation theory, Zeeman interaction for energy level transitio

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Single-nucleon knock-out reactions in neutron-rich medium-mass nuclei were studied to investigate the reduction of proton-removal cross section. Short-range correlated nucleon pairs, especially protons, were found to impact the probability of single-proton removal processes. Experimental measurement

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The comparison between Polarized Gas Targets (PGT) at the Large Hadron Collider (LHC) and HERA for spin studies is discussed. Key considerations such as beam-induced depolarization, beam parameters, and design aspects are highlighted. The importance of using a polarized gas target similar to HERMES

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Exploring the Dirac equation for spin particles within the framework of special theory of relativity. Topics covered include energy-momentum relationships, basics of special relativity, Lorentz transformations, and relativistic effects on particles. The lecture delves into the interplay between quan

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