Explanation: Salinity specifically refers to the concentration of dissolved salts and ions in water. Dissolved gases like oxygen and nitrogen, while important for aquatic ecosystems, are distinct from the constituents that define salinity.

Explanation: Parts per thousand (‰) is a standard unit for expressing salinity, directly equivalent to grams per kilogram (g/kg) of water, providing a dimensionless measure of salt concentration.

Explanation: Salinity is fundamentally defined as the saltiness or the total amount of dissolved salt present in a body of water.

Explanation: Salinity is commonly quantified using units such as grams per liter (g/L) or grams per kilogram (g/kg), which are directly equivalent to parts per thousand (‰).

Explanation: Sodium Chloride (NaCl) is a primary salt compound contributing to the salinity of water. Other significant dissolved salts include magnesium sulfate and potassium nitrate.

Explanation: Although 'psu' (practical salinity unit) is frequently employed in oceanographic contexts, it is not a formally recognized SI unit and its use is discouraged in favor of dimensionless ratios or specific units like g/kg.

Explanation: Accurate and standardized salinity measurements are essential for physical oceanographers to ensure the comparability of data across different studies and instruments, especially when analyzing deep ocean environments.

Explanation: Before the 1980s, the predominant method for determining seawater salinity relied on titration-based chemical analysis. Electrical conductivity measurements became more widespread with the development of the Practical Salinity Scale 1978 (PSS-78).

Explanation: Under the TEOS-10 standard, absolute salinity is defined and expressed as a mass fraction, specifically in grams per kilogram (g/kg) of solution, providing a more direct physical measure.

Explanation: While electrical conductivity is often used as a proxy or for estimation in freshwater systems, limnologists and chemists may also define salinity in terms of mass of salt per unit volume (e.g., mg/L or g/L) for lakes and rivers, especially when precise values are needed.

Explanation: A salinometer is a dedicated device engineered to determine the salt concentration within a water sample, serving as a key tool in oceanographic and hydrological studies.

Explanation: The PSS-78 scale was established to standardize salinity determinations based on electrical conductivity, reflecting a shift from older chemical titration methods towards more efficient instrumental measurements.

Explanation: Operationally, dissolved matter for salinity determination is defined as substances that *can* pass through a fine filter, typically with a pore size of 0.45 micrometers or smaller, distinguishing them from suspended particles.

Explanation: The Thermodynamic Equation of Seawater 2010 (TEOS-10) introduced a revised framework, replacing the practical salinity scale with absolute salinity and potential temperature with conservative temperature for enhanced accuracy.

Explanation: The precise definition and measurement of salinity are complicated by the complex mixture of dissolved substances in natural waters, whose chemical forms can vary with environmental conditions.

Explanation: Chlorinity, the measure of dissolved chloride ions, was historically employed as a proxy for estimating total salinity due to its abundance and relative ease of measurement.

Explanation: Operationally, dissolved matter relevant to salinity is defined as substances capable of passing through a fine filter, typically with a pore size of 0.45 micrometers, distinguishing them from suspended particulate matter.

Explanation: Oceanographers utilize IAPSO Standard Seawater as a reference material to calibrate instruments and ensure the high precision and intercomparability of salinity measurements.

Explanation: The calculation of salinity in natural waters often relies on considering the concentrations of eight major ions, which collectively account for the vast majority of dissolved salts.

Explanation: The Practical Salinity Scale 1978 (PSS-78) was developed to standardize salinity determinations based on electrical conductivity, becoming the international standard for oceanography.

Explanation: The suffix 'psu' or 'PSU' denotes 'practical salinity unit,' a term historically associated with the PSS-78 scale, though it is not a formal SI unit and its use is discouraged in precise scientific communication.

Explanation: The TEOS-10 (Thermodynamic Equation of Seawater 2010) standard was introduced to offer a more precise and physically rigorous definition of seawater properties, including salinity and temperature.

Explanation: Absolute salinities within the TEOS-10 framework are expressed as a mass fraction, quantified in grams per kilogram (g/kg) of solution.

Explanation: Electrical conductivity is frequently employed by limnologists as a practical proxy for estimating salinity in freshwater systems like lakes and rivers, as it correlates well with dissolved ion concentrations.

Explanation: Seawater typically exhibits a mass salinity of approximately 35 g/kg, representing a widely accepted average for the salt concentration in the global ocean.

Explanation: Observations since the 1950s indicate that human-caused climate change has demonstrably influenced both surface and subsurface ocean salinity patterns globally.

Explanation: Climate change projections indicate an intensification of salinity contrasts: regions with currently low salinity are expected to become fresher, and regions with high salinity are expected to become saltier.

Explanation: The application of road salt and de-icers leads to increased salinity in lakes and rivers through runoff, rather than a decrease, posing environmental concerns for freshwater ecosystems.

Explanation: The Dead Sea is renowned for its extremely high salinity, significantly exceeding that of typical freshwater lakes and even standard seawater, with concentrations often surpassing 200 g/kg.

Explanation: Salinity values are typically lower near coasts where rivers enter the ocean because the influx of freshwater dilutes the saltwater. Salinity increases with distance from the freshwater source towards the open ocean.

Explanation: The average mass salinity of the world's oceans is approximately 35 grams per kilogram (g/kg), a value commonly used as a reference standard.

Explanation: Areas near coasts where freshwater rivers discharge into the sea exhibit lower salinity due to dilution. These estuarine environments represent a transition zone from freshwater to marine conditions.

Explanation: Rivers and lakes generally exhibit low salinities, typically ranging from less than 0.01 g/kg up to a few grams per kilogram, classifying them as freshwater or oligohaline environments.

Explanation: The Dead Sea is distinguished by its exceptionally high salinity, often exceeding 200 g/kg, making it one of the saltiest bodies of water on Earth.

Explanation: Precipitation, such as rain and snow, typically contains very low concentrations of Total Dissolved Solids (TDS), generally 20 mg/L or less.

Explanation: Climate change projections indicate an intensification of salinity contrasts, meaning areas that are currently fresher will become even fresher, and areas that are saltier will become even saltier.

Explanation: Salinity distribution is a fundamental driver of oceanic circulation, acting in concert with temperature to influence water density and buoyancy, thereby initiating thermohaline circulation.

Explanation: Elevated salt concentrations in water typically render it unsuitable for direct human consumption (potability) and can be detrimental to agricultural crops and soil health, thus posing significant challenges for irrigation.

Explanation: Conversely, more saline waters exhibit lower solubility for carbon dioxide than less saline waters. This relationship influences the ocean's capacity to absorb atmospheric CO2.

Explanation: Ocean stratification, potentially exacerbated during glacial periods due to altered hydrography, can impede vertical water mass movement, leading to a reduction in thermohaline circulation.

Explanation: Salinity is a critical environmental factor that profoundly impacts water chemistry, dictates the viability of aquatic life, and influences physiological processes in organisms inhabiting diverse aquatic environments.

Explanation: Salinity is a critical factor as it governs the chemical milieu, impacts biological organisms, and determines physical properties such as water density, which is fundamental to ocean circulation.

Explanation: Variations in salinity, along with temperature, alter the density of seawater. These density differences drive ocean circulation by causing water masses to sink in high-density areas and rise in low-density areas.

Explanation: High salinity in water poses significant concerns for human use, primarily by compromising its potability and suitability for agricultural irrigation, potentially harming crops and soil structure.

Explanation: Isohalines are contour lines that represent areas of constant salinity, analogous to isotherms representing constant temperature.

Explanation: Brackish waters generally range from 0.5 to 29 parts per thousand (‰), whereas metahaline seas have higher salinities, typically between 36 and 40 ‰.

Explanation: Homoiohaline environments are defined by relatively stable salinity levels that do not vary significantly over time, in contrast to poikilohaline environments where salinity fluctuates considerably.

Explanation: Halophytes are plants specifically adapted to survive in saline environments. While bacteria can also be adapted to high-salt conditions (termed halophiles), halophytes refer to the plant kingdom.

Explanation: Euryhaline organisms are characterized by their ability to tolerate a wide range of salinity fluctuations, whereas stenohaline organisms are restricted to narrow salinity ranges.

Explanation: 'Euhaline seas' refer to oceanic waters with typical salinity ranges (approximately 30-35 ‰), not waters significantly lower than freshwater.

Explanation: Brine refers to water with a salinity level significantly higher than typical freshwater, often to the point where salts begin to crystallize.

Explanation: A contour line representing areas of constant salinity on a map or chart is termed an isohaline.

Explanation: Brackish waters are defined by a salinity range intermediate between freshwater and seawater, typically between 0.5 and 29 parts per thousand (‰).

Explanation: Water bodies experiencing significant temporal fluctuations in salinity are classified as poikilohaline environments.

Explanation: A plant species exhibiting adaptations for survival in saline environments is termed a halophyte.

Explanation: Organisms capable of tolerating a broad spectrum of salinity levels are designated as euryhaline.