IJSRP, Volume 3, Issue 1, January 2013 Edition [ISSN 2250-3153]
Sir Allan Zade, Dr. K.N.Prasanna Kumar
Abstract:
Systems of Z-Theory and Quantum Field Theory are investigated. It is shown that the time independence of the contributions portrays another system by itself and constitutes the equilibrium solution of the original time independent system. Further papers extensively draw inferences upon such concatenation process, ipso facto fait accompli. One work that relates Structural stability, electronic properties, and quantum conductivity of small-diameter silicon nanowires is that of Inna Ponomareva, Madhu Menon, Ernst Richter, and Antonis N. Andriotis, wherein they study structures and energetics of various types of silicon nanowires have been investigated using quantum molecular dynamics simulations to determine the most stable forms. The tetrahedral type nanowires oriented in the ⟨111⟩ direction are found to be the most stable. The stability of the cage like nanowires is determined to lie somewhere between this and tetrahedral nanowires oriented in other directions. Furthermore, their electrical conducting properties are found to be better than those of tetrahedral nanowires, suggesting useful molecular electronic applications. quantum dots which we shall later concatenate and with Z-Theory is Stability of quantum dots in live cells by Zheng-Jiang Zhu, etal. Quantum dots are highly fluorescent and photostable, making them excellent tools for imaging. When using these quantum dots in cells and animals, however, intracellular biothiols (such as glutathione and cysteine) can degrade the quantum dot monolayer, compromising function. Here, we describe a label-free method to quantify the intracellular stability of monolayers on quantum dot surfaces that couples laser desorption/ionization mass spectrometry with inductively coupled plasma mass spectrometry.