Norris

Kothe G, Weber S, BittI R, Ohmes E, Thurnauer M and Norris J 1991 Transient EPR of light-induced radical pairs in plant photosystem I observation of quantum beats Chem. Rhys. Lett. 186 474-80... 

Weber S, Ohmes E, Thurnauer M C, Norris J R and Kothe G 1995 Light-generated nuclear quantum beats a signature of photosynthesis Proc. Natl Acad. Sc/. USA 92 7789-93... 

Trifunac A D, Thurnauer M C and Norris J R 1978 Submicrosecond time-resolved EPR in laser photolysis Chem. Rhys. Lett. 57 471-3... 

Closs G L, Forbes M D E and Norris J R 1987 Spin-polarized electron paramagnetic resonance spectra of radical pairs in micelles. Observation of electron spin-spin interactions J. Phys. Chem. 91 3592-9... 

Norris J R, Morris A L, Thurnauer M C and Tang J 1990 A general model of electron spin polarization arising from the interactions within radical pairs J. Chem. Phys. 92 4239—49... 

Thurnauer M C and Norris J R 1980 An electron spin echo phase shift observed in photosynthetic algae. Possible evidence for dynamic radical pair interactions Chem. Phys. Lett. 76 557-61... 

Empedocles S A, Norris D J and Bawendi M G 1996 Photoluminescence spectroscopy of single CdSe nanocrystallite quantum dots Phys. Rev. Lett. 77 3873-6... 

Vaillancourt G, Norris T B, Coe J S, Bade P and Mourou G 1990 Operation of a 1 kHz pulse-pumped Tfsapphire regenerative amplifier Opf. Lett. 15 317-19... 

Norris T B 1992 Femtosecond pulse amplification at 250 kHz with a Ti sapphire regenerative amplifier and application to continuum generation Opt. Lett. 17 1009-11... 

Brakenhoff G J, Squier J, Norris T, Bliton A C, Wade M FI and Athey B 1996 Real-time two-photon confocal microscopy using a femtosecond, amplified Ti sapphire system J. Microscopy 181 253-9... 

Norris D J, Kuwata-Gonokami M and Moerner W E 1997 Excitation of a single molecule on the surface of a spherical microcavity Appl. Phys. Lett. 71 297-9... 

Diokson R M, Norris D J and Moerner W E 1998 Simuitaneous imaging of individuai moieouies aiigned both paraiiei and perpendiouiar to the optio axis Phys. Rev. Lett. 81 5322-5... 

Diokson R M, Norris D J, Tzeng Y-L and Moerner W E 1996 Three-dimensionai imaging of singie moieouies soivated in pores of poiy(aoryiamide) geis Science 274 966-9... 

Leadbetter A J and Norris E K 1979 Distribution functions in hree liquid crystals from x-ray diffraction measurements Moiec. Phys. 38 669-86... 

A challenging task in material science as well as in pharmaceutical research is to custom tailor a compound s properties. George S. Hammond stated that the most fundamental and lasting objective of synthesis is not production of new compounds, but production of properties (Norris Award Lecture, 1968). The molecular structure of an organic or inorganic compound determines its properties. Nevertheless, methods for the direct prediction of a compound s properties based on its molecular structure are usually not available (Figure 8-1). Therefore, the establishment of Quantitative Structure-Property Relationships (QSPRs) and Quantitative Structure-Activity Relationships (QSARs) uses an indirect approach in order to tackle this problem. In the first step, numerical descriptors encoding information about the molecular structure are calculated for a set of compounds. Secondly, statistical and artificial neural network models are used to predict the property or activity of interest based on these descriptors or a suitable subset. 

R. Smith and T. Norris, eds., TAPPI Proceedings 1988 Paper Preservation Symposium, Technical Association of the Paper and Pulp Industry, Washington, D.C., 1988. 

D. A. Flint and C. Norris, 1986 Capacity and Generation of Non-Utility Sources of Energy, Edison Electric Institute, Washington, D.C., July 1988. 

R. Norris Shreve andj. A. Brink, "Chemical Process Industries," in Perry s Chemical Engineers Handbook, 4th ed., McGraw-HiU Book Co., Inc., New York, 1977. 

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