Sulfuric acid constant humidity solutions

Inorganic oxide layers can be adjusted to a defined activity level by exposure to a defined gas phase in an enclosed chamber. This is best performed after sample application in a developing chamber that allows both conditioning and development of the layer in the same chamber (e.g. a twin trough chamber). Alternatively, separate conditioning and development chambers can be used. Atmospheres of different constant relative humidity can be obtained by exposure to the vapor phase in equilibrium with solutions of concentrated sulfuric acid or saturated solutions of various salts [100]. In the same way, acid or base deactivation is carried out by exposure to concentrated ammonia or hydrochloric acid fumes. 

Equilibrium moisture content of a hygroscopic material may be determined in a number of ways, the only requirement being a source of constant-temperature and constant-humidity air. Determination may be made under static or dynamic conditions, although the latter case is preferred. A simple static procedure is to place a number of samples in ordinaiy laboratoiy desiccators containing sulfuric acid solutions of known concentrations which produce atmospheres of known relative humidity. The sample in each desiccator is weighed periodically until a constant weight is obtained. Moisture content at this final weight represents the equilibrium moisture content for the particular conditions. 

Bindings covered with vegetable-tanned leather are washed with pure toilet soap, saddle soap, or mild, high quality surgical toilet soap and a 7-10% solution of potassium lactate. 0.25% of p-nitrophenol can be added as a fungicide, but this is not necessary if the temperature and relative humidity are constantly satisfactory (see p. 5). The lactate, when applied to new vegetable-tanned leather, is thought to protect the leather from the deleterious action of sulfuric acid which usually forms in leather when sulfur dioxide is absorbed. It is. probable that it has little efficacy once chemical deterioration has started, and for some years doubt has been cast on its effectiveness, even on new leather, despite favorable results in laboratory tests. However, it is used, and its use is advocated just in case it is beneficial. 

Saturated salt solutions and sulfuric acid solutions establish relative humidity by reducing the vapor pressure above an aqueous solution (a colligative effect). Saturated salt solutions at controlled temperature maintain a constant relative humidity as long as excess salt and bulk solution are present. As water is added or removed from the solution, moisture from the head-space will either condense or evaporate (as appropriate), with subsequent dissolution or precipitation of salt to maintain the equilibrium vapor pressure. Because the degree of vapor pressure depression is dependent on the number of species in solution and, further, since the solubility of most salts is somewhat dependent on temperature, the relative humidity generated is also temperature dependent. Hence, use of the same salt at different temperatures can result in different relative humidities. Refs. can be consulted for specific saturated salt solutions that result in defined relative humidities as a function of... 

Good activity control is obtained by plate development in a chamber equilibrated with the vapors of a humidity-controlling solution such as aqueous sulfuric acid or a saturated salt solution. A solution of 50% sulfuric acid will provide a relative humidity of —40%, which has proven optimum for reproducibility. In addition, Hahn-Deinstrop (1993) has tubulated saturated salt solutions that will establish constant relative humidities ranging from 15 to 95% in closed chambers. These solutions can be used by placement in either section of a twin-trough chamber or in the inner portion of a horizontal chamber (Chapter 7). 

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