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Energy sodium

Maintenance of the appropriate concentrations of K and N.i1 in the intra- and extracellular fluids involves active transport, i.e.. a process requiring energy. Sodium ion in Ihe extracellular fluid (0.176-0.I45 If Na t diffuses passively and continuously into the intracellular fluid kO.BI M Na l and must he removed. This sodium ion is pumped front the intracellular to the extracellular fluid, while K is pumped from the extracellular tea 0.004 M K l to the Intracellular fluid (ea 0.14 M K t. The energy for these processes is provided by hydrolysis of adenosine triphosphate (ATP) and requires (he enzyme Na -K ATPasc. a membrane bound enzyme which is widely distributed in the body. In some cells, c.g.. brain and kidney. 60-70 wl of (he ATP is used to mainiain Ihe required Na -K distribution. [Pg.1002]

Table XXIII-4.—Calculation op Electrostatic Energy, Sodium Chloride... Table XXIII-4.—Calculation op Electrostatic Energy, Sodium Chloride...
S = Heat of sublimation of sodium D = Dissociation energy of chlorine / = Ionization energy of sodium = Electron affinity of chlorine Uq = Lattice energy of sodium chloride AHf = Heat of formation of sodium chloride. [Pg.64]

The excess heat of solution of sample A of finely divided sodium chloride is 18 cal/g, and that of sample B is 12 cal/g. The area is estimated by making a microscopic count of the number of particles in a known weight of sample, and it is found that sample A contains 22 times more particles per gram than does sample B. Are the specific surface energies the same for the two samples If not, calculate their ratio. [Pg.286]

Let us consider the formation of sodium chloride from its elements. An energy (enthalpy) diagram (called a Born-Haber cycle) for the reaction of sodium and chlorine is given in Figure 3.7. (As in the energy diagram for the formation of hydrogen chloride, an upward arrow represents an endothermic process and a downward arrow an exothermic process.)... [Pg.73]

A/ij the lattice energy of sodium chloride this is the heat liberated when one mole of crystalline sodium chloride is formed from one mole of gaseous sodium ions and one mole of chloride ions, the enthalpy of formation of sodium chloride. [Pg.74]

To date there is no evidence that sodium forms any chloride other than NaCl indeed the electronic theory of valency predicts that Na" and CU, with their noble gas configurations, are likely to be the most stable ionic species. However, since some noble gas atoms can lose electrons to form cations (p. 354) we cannot rely fully on this theory. We therefore need to examine the evidence provided by energetic data. Let us consider the formation of a number of possible ionic compounds and first, the formation of sodium dichloride , NaCl2. The energy diagram for the formation of this hypothetical compound follows the pattern of that for NaCl but an additional endothermic step is added for the second ionisation energy of sodium. The lattice energy is calculated on the assumption that the compound is ionic and that Na is comparable in size with Mg ". The data are summarised below (standard enthalpies in kJ) ... [Pg.75]

Ah second ionisation energy for sodium (additional) +4561 A/13 enthalpy of atomisation of chlorine, x 2 (since two... [Pg.75]

Although the data for the silver halides suggest that silver(I) fluoride is likely to be more soluble than the other silver halides (which is in fact the case), the hydration enthalpies for the sodium halides almost exactly balance the lattice energies. What then is the driving force which makes these salts soluble, and which indeed must be responsible for the solution process where this is endothermic We have seen on p. 66 the relationship AG = — TAS and... [Pg.79]

In view of the ionisation energies the electrode potentials for lithium and beryllium might be expected to be higher than for sodium and magnesium. In fact... [Pg.134]

The production of both an alcohol and the sodium salt of an acid might easily be confused with the hydrolysis products of an ester (in the above instance benzyl benzoate). Such an error would soon be discovered (e.g., by reference to the b.p. and other physical properties), but it would lead to an unnecessary expenditure of time and energy. The above example, however, emphasises the importance of conducting the class reactions of neutral oxygen-containing compounds in the proper order, viz., (1) aldehydes and ketones, (2) esters and anhydrides, (3) alcohols, and (4) ethers. [Pg.1063]

Were we to simply add the ionization energy of sodium (496 kJ/mol) and the electron affin ity of chlorine (—349 kJ/mol) we would conclude that the overall process is endothermic with AH° = +147 kJ/mol The energy liberated by adding an electron to chlorine is msuf ficient to override the energy required to remove an electron from sodium This analysis however fails to consider the force of attraction between the oppositely charged ions Na" and Cl which exceeds 500 kJ/mol and is more than sufficient to make the overall process exothermic Attractive forces between oppositely charged particles are termed electrostatic, or coulombic, attractions and are what we mean by an ionic bond between two atoms... [Pg.12]

What is the energy per photon of the sodium D line ( i = 589 nm) SOLUTION... [Pg.371]

Absorption of a photon is accompanied by the excitation of an electron from a lower-energy atomic orbital to an orbital of higher energy. Not all possible transitions between atomic orbitals are allowed. For sodium the only allowed transitions are those in which there is a change of +1 in the orbital quantum number ) thus transitions from s—orbitals are allowed, but transitions from s d orbitals are forbidden. The wavelengths of electromagnetic radiation that must be absorbed to cause several allowed transitions are shown in Figure 10.18. [Pg.383]

The 3 Pi/2, 3 P2/2 excited states involved in the sodium D lines are the lowest energy excited states of the atom. Consequently, in a discharge in the vapour at a pressure that is sufficiently high for collisional deactivation of excited states to occur readily, a majority of atoms find themselves in these states before emission of radiation has taken place. Therefore... [Pg.215]

However, because of the avoided crossing of the potential energy curves the wave functions of Vq and Fi are mixed, very strongly at r = 6.93 A and less strongly on either side. Consequently, when the wave packet reaches the high r limit of the vibrational level there is a chance that the wave function will take on sufficient of the character of Na + 1 that neutral sodium (or iodine) atoms may be detected. [Pg.390]

Sodium acetate reacts with carbon dioxide in aqueous solution to produce acetic anhydride and sodium bicarbonate (49). Under suitable conditions, the sodium bicarbonate precipitates and can be removed by centrifugal separation. Presumably, the cold water solution can be extracted with an organic solvent, eg, chloroform or ethyl acetate, to furnish acetic anhydride. The half-life of aqueous acetic anhydride at 19°C is said to be no more than 1 h (2) and some other data suggests a 6 min half-life at 20°C (50). The free energy of acetic anhydride hydrolysis is given as —65.7 kJ/mol (—15.7 kcal/mol) (51) in water. In wet chloroform, an extractant for anhydride, the free energy of hydrolysis is strangely much lower, —50.0 kJ/mol (—12.0 kcal/mol) (51). Half-life of anhydride in moist chloroform maybe as much as 120 min. Ethyl acetate, chloroform, isooctane, and / -octane may have promise for extraction of acetic anhydride. Benzene extracts acetic anhydride from acetic acid—water solutions (52). [Pg.78]


See other pages where Energy sodium is mentioned: [Pg.26]    [Pg.517]    [Pg.97]    [Pg.324]    [Pg.26]    [Pg.517]    [Pg.97]    [Pg.324]    [Pg.158]    [Pg.35]    [Pg.269]    [Pg.271]    [Pg.272]    [Pg.368]    [Pg.1787]    [Pg.2589]    [Pg.28]    [Pg.65]    [Pg.74]    [Pg.75]    [Pg.75]    [Pg.76]    [Pg.121]    [Pg.123]    [Pg.124]    [Pg.11]    [Pg.371]    [Pg.383]    [Pg.383]    [Pg.434]    [Pg.12]    [Pg.57]    [Pg.74]    [Pg.215]    [Pg.271]    [Pg.391]    [Pg.69]   
See also in sourсe #XX -- [ Pg.66 ]




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Energy level diagram, for sodium

Sodium atom energy level diagram

Sodium atom energy levels

Sodium binding energy curve

Sodium bond dissociation energies

Sodium bond energy

Sodium bonding energy

Sodium chloride bond energy

Sodium chloride lattice energy

Sodium clusters binding energy

Sodium clusters stabilization energies

Sodium clusters total energies

Sodium dodecyl sulfate energy

Sodium energy bands

Sodium energy level

Sodium energy transfer processes

Sodium energy-level diagram

Sodium fluoride lattice energy, 154

Sodium free energy change

Sodium ionization energy

Sodium lattice energy

Sodium potential energy curves

Sodium second ionization energy

Sodium, binding energies

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