molar conductivity involves concentration of electrolyte also....but electrolytic conductivity doesn't
The thermal conductivity temperature of different objects vary from one object to another. When the two objects are placed together, there will be a change in temperature through heat conduction.
Electricity can travel about 100 meters in water, but this distance can vary depending on factors like the concentration of ions in the water, temperature, and pressure. These factors influence the conductivity of water, which determines how well it can conduct electricity.
The electrical conductivity of a semiconductor typically increases with temperature. As the temperature rises, more charge carriers are generated in the semiconductor, leading to higher conductivity. This is due to the increased thermal energy that excites electrons into the conduction band.
The electrical conductivity of gas can vary based on factors such as temperature, pressure, and the presence of impurities. Generally, higher temperatures and pressures can increase conductivity, while impurities can either increase or decrease conductivity depending on their nature.
No, not all electrical conductors conduct current equally well. The ability of a material to conduct electricity is determined by its conductivity, which can vary depending on factors such as the material's composition, structure, and temperature. Metals like copper and silver are known for their high conductivity, while materials like plastic and rubber have low conductivity.
The molar concentration of nitric acid can vary depending on the specific solution. However, a common concentration of nitric acid used in laboratories is around 16 M (molar). This means there are 16 moles of nitric acid in 1 liter of solution.
The thermal conductivity temperature of different objects vary from one object to another. When the two objects are placed together, there will be a change in temperature through heat conduction.
That will vary with both the compound and its concentration in the solution (neither of which were specified in the question).
Electricity can travel about 100 meters in water, but this distance can vary depending on factors like the concentration of ions in the water, temperature, and pressure. These factors influence the conductivity of water, which determines how well it can conduct electricity.
The electrical conductivity of a semiconductor typically increases with temperature. As the temperature rises, more charge carriers are generated in the semiconductor, leading to higher conductivity. This is due to the increased thermal energy that excites electrons into the conduction band.
The electrical conductivity of gas can vary based on factors such as temperature, pressure, and the presence of impurities. Generally, higher temperatures and pressures can increase conductivity, while impurities can either increase or decrease conductivity depending on their nature.
Temperature decreases with increasing altitude, Also air concentration decreases with altitude.
The molar volume of water at standard temperature and pressure (STP) is approximately 18.02 liters/mol. This value can vary slightly with changes in temperature and pressure, but it is commonly used as a rough estimate for calculations.
Resistivity is a constant for any particular material, and independent of that material's physical dimensions or shape. However, it does vary with temperature which is why resistivity is always quoted at a particular temperature. Variations in resistivity due to temperature change is the reason that the resistance of a material varies with temperature. In SI, resistivity is expressed in ohm metres.
Conductivity is the reciprocal of resistivity, and is expressed in siemens per metre (S/m). Resistivity and, therefore, conductivity vary with temperature so are usually quoted at a specified temperature.Resistance is expressed in ohms. If you accurately measure the resistance, length, and cross-sectional area of a conductor, then you could determine its resistivity and, from that, its conductivity.
Freshwater conductivity typically ranges from 50 to 1500 µS/cm (microsiemens per centimeter). The exact measurement can vary depending on factors such as dissolved ions and temperature. High conductivity levels may indicate contamination or high mineral content in the water.
No, the concentration of a saturated citric acid solution depends on the amount of citric acid that can dissolve in the solvent at a given temperature. If the two solutions have different amounts of citric acid dissolved, their concentrations and volumes may vary.