Heat transfer methods overview

B. J. Davidson and M. Rowe, Simulation of Power Plant Condenser Performance by Computational Methods An Overview, in P. J. Marto and R. H. Nunn (eds), Power Condenser Heat Transfer Technology, pp. 17-49, Hemisphere Publishing Corp., New York, 1981. 

Oxidation and reduction are fundamental processes in the synthesis of organic and inorganic compounds. Some oxidation and reduction reactions are difficult to control in macro-scale batch reactors and in such cases microflow reactors serve as powerful tools for accomplishing the reactions in a highly controlled manner. This is especially true for many oxidation reactions because of their exothermic nature. It should also be noted that the danger of unexpected explosions can be avoided by the use of microflow reactors because of the small volume and highly efficient heat transfer ability of microflow systems. This chapter provides an overview of oxidation and reduction reactions using chemical, electrochemical and biochemical methods in microflow reactors. 

One of the methods of studying the composition of macromolecular sedimentary organic matter in more detail is the molecular analysis of pyrolysis products. For this purpose, the pyrolysis products are transferred to a gas chromatographic column and analyzed as described for extractable organic matter in Sect. 4.5.5, with or without the combination with a mass spectrometer. Both flash pyrolysis (Curie-point pyrolysis samples are heated on a magnetic wire by electrical induction almost instantaneously, e.g., to 610°C) or off-line pyrolysis at various heating rates have been applied to geological samples (see Larter and Horsfield 1993 for an overview of various pyrolysis techniques). 

In order to stndy the short time vibrational energy transfer behavior of a vibra-tionally excited system, we employ a non-Markovian time-dependent perturbation theory [83]. Onr approach builds on the successful application of Markovian time-dependent pertnrbation theory by Leitner and coworkers to explore heat flow in proteins and glasses, and Tokmakoff, Payer, and others, in modeling vibrational population relaxation of selected modes in larger molecules. In a separate chapter in this volnme, Leitner provides an overview of the development of normal mode-based methods, snch as the one employed here, for the study of energy flow in solids and larger molecnlar systems. 

---