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Right rectangles

The bottom right rectangle with 7 is an area investigated by which includes Dubrovinsky et al. [Pg.34]

You can split the screen into four portions in a 2 x 2 array. To do this, select the cell that wUl be in the center, that is, the upper left comer of the lower right rectangle. Then choose Windows/Split. You can later choose Windows/Remove Split if you want. In Figure A.2, the cursor was placed in cell F3 before choosing Windows/Split. Sometimes the... [Pg.231]

Figure 2-4. A simplified scheme of the proposed water-gated mechanism of proton translocation. Each numbered state shows haem a and the binuclear site (left and right rectangles, respectively) the A-propionate of haem is shown schematically. Three water molecules (oxygen in red hydrogen in yellow) are shown to mediate Grotthuss proton transfer from the glutamic acid (GLU-OH) to the propionate or the binuclear site, respectively. In state 1, an electron is transferred to haem a. The formed electric field between the redox sites orientates the water molecules towards the propionate (state 2). In state 3, electron transfer to the binuclear site is accompanied by proton transfer via the propionate a proton is deposited above haem and the glutamate is reprotonated via the D-pathway (state 4). The switch of electric field orientation reorientates the water array towards the binuclear site (state 5). Finally, a proton is transferred to this site, and the first proton is ejected (state 6). Reprotonation of the glutamate transfers the system back to state 1. For details, see the text and ref. 17. Figure 2-4. A simplified scheme of the proposed water-gated mechanism of proton translocation. Each numbered state shows haem a and the binuclear site (left and right rectangles, respectively) the A-propionate of haem is shown schematically. Three water molecules (oxygen in red hydrogen in yellow) are shown to mediate Grotthuss proton transfer from the glutamic acid (GLU-OH) to the propionate or the binuclear site, respectively. In state 1, an electron is transferred to haem a. The formed electric field between the redox sites orientates the water molecules towards the propionate (state 2). In state 3, electron transfer to the binuclear site is accompanied by proton transfer via the propionate a proton is deposited above haem and the glutamate is reprotonated via the D-pathway (state 4). The switch of electric field orientation reorientates the water array towards the binuclear site (state 5). Finally, a proton is transferred to this site, and the first proton is ejected (state 6). Reprotonation of the glutamate transfers the system back to state 1. For details, see the text and ref. 17.
Figure 3.8. The transformation of a rectangular into a normal distribution. The rectangle at the lower left shows the probability density (idealized observed frequency of events) for a random generator versus x in the range 0 < jc < 1. The curve at the upper left is the cumulative probability CP versus deviation z function introduced in Section 1.2.1. At right, a normal distribution probability density PD is shown. The dotted line marked with an open square indicates the transformation for a random number smaller or equal to 0.5, the dot-dashed line starting from the filled square is for a random number larger than 0.5. Figure 3.8. The transformation of a rectangular into a normal distribution. The rectangle at the lower left shows the probability density (idealized observed frequency of events) for a random generator versus x in the range 0 < jc < 1. The curve at the upper left is the cumulative probability CP versus deviation z function introduced in Section 1.2.1. At right, a normal distribution probability density PD is shown. The dotted line marked with an open square indicates the transformation for a random number smaller or equal to 0.5, the dot-dashed line starting from the filled square is for a random number larger than 0.5.
In this diagram, a series of hexagon-shaped planes are shown which are orthogonal, or 90 degrees, to each of the corners of the cubic cell. Each plane connects to cuiother plane (here shown as a rectangle) on each fiace of the unit-cell. Thus, the faces of the lattice unit-cell and those of the reciprocal unit-cell can be seen to lie on the same pltme while those at the corners lie at right angles to the corners. [Pg.38]

Band structure for a chain of H atoms. Left, with equidistant atoms right, after PEIERLS distortion to H2 molecules. The lines in the rectangles symbolize energy states occupied by electrons... [Pg.95]

A rectangle is a parallelogram with four right angles. Refer to figure III, above. [Pg.182]

Fig. 1. Top Scheme of an inversion recovery experiment 5rielding the longitudinal relaxation time (inversion is achieved by mean of the (re) radiofrequency (rf) pulse, schematized by a filled vertical rectangle). Free induction decays (fid represented by a damped sine function) resulting from the (x/2) read pulse are subjected to a Fourier transform and lead to a series of spectra corresponding to the different t values (evolution period). Spectra are generally displayed with a shift between two consecutive values of t. The analysis of the amplitude evaluation of each peak from — Mq to Mq provides an accurate evaluation of T. Bottom the example concerns carbon-13 Tl of irans-crotonaldehyde with the following values (from left to right) 20.5 s, 19.8 s, 23.3 s, and 19.3 s. Fig. 1. Top Scheme of an inversion recovery experiment 5rielding the longitudinal relaxation time (inversion is achieved by mean of the (re) radiofrequency (rf) pulse, schematized by a filled vertical rectangle). Free induction decays (fid represented by a damped sine function) resulting from the (x/2) read pulse are subjected to a Fourier transform and lead to a series of spectra corresponding to the different t values (evolution period). Spectra are generally displayed with a shift between two consecutive values of t. The analysis of the amplitude evaluation of each peak from — Mq to Mq provides an accurate evaluation of T. Bottom the example concerns carbon-13 Tl of irans-crotonaldehyde with the following values (from left to right) 20.5 s, 19.8 s, 23.3 s, and 19.3 s.
See other pages where Right rectangles is mentioned: [Pg.84]    [Pg.20]    [Pg.22]    [Pg.34]    [Pg.470]    [Pg.84]    [Pg.20]    [Pg.22]    [Pg.34]    [Pg.470]    [Pg.225]    [Pg.269]    [Pg.459]    [Pg.119]    [Pg.359]    [Pg.4]    [Pg.519]    [Pg.547]    [Pg.116]    [Pg.388]    [Pg.101]    [Pg.69]    [Pg.78]    [Pg.223]    [Pg.223]    [Pg.200]    [Pg.9]    [Pg.22]    [Pg.254]    [Pg.182]    [Pg.253]    [Pg.473]    [Pg.65]    [Pg.476]    [Pg.110]    [Pg.11]    [Pg.57]    [Pg.282]    [Pg.284]    [Pg.287]    [Pg.288]    [Pg.203]    [Pg.38]    [Pg.485]    [Pg.266]   
See also in sourсe #XX -- [ Pg.287 , Pg.288 , Pg.294 ]



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