Explanation: The metric system is indeed fundamentally based on decimal (base-10) relationships between units, employing prefixes to denote multiplicative factors, which contributes to its coherence and ease of use.

Explanation: The modern metric system is officially known as the International System of Units (SI). It standardizes rules for prefixes and defines seven base units for fundamental physical quantities.

Explanation: There is a general convention where prefixes for multiples (e.g., kilo-, mega-) are derived from Greek, and prefixes for sub-multiples (e.g., centi-, milli-) are derived from Latin. However, this convention has exceptions and has evolved over time.

Explanation: For derived units like area (m²) or volume (m³), when a prefix is used, the exponent applies to the entire prefixed unit. For example, 1 mm² is equal to (1 mm)², which is (0.001 m)², resulting in 10⁻⁶ m².

Explanation: The systematic decimal nature, coherent structure, and standardized prefixes are key factors contributing to the metric system's widespread adoption and ease of application.

Explanation: A coherent system of units ensures that derived units are formed directly from base units through multiplication and division, without introducing arbitrary numerical factors, simplifying physical equations.

Explanation: As of 2022, the SI system introduced 'quetta-' (10^30) and 'quecto-' (10^-30) as the most recent extensions to the prefix nomenclature.

Explanation: The metric system's core strength lies in its decimal structure, standardized base units, and the systematic application of prefixes to denote multiples and sub-multiples.

Explanation: Prefixes denoting multiples of ten in the metric system are generally derived from Greek words (e.g., 'kilo-' from 'khilioi' meaning thousand).

Explanation: When a prefix is applied to a derived unit involving powers, such as area (m²) or volume (m³), the exponent applies to the entire prefixed unit. For example, 1 mm² = (1 mm)² = (10⁻³ m)² = 10⁻⁶ m².

Explanation: Coherence in a unit system means that derived units are formed from base units by multiplication and division alone, without the introduction of numerical factors, thus simplifying equations.

Explanation: The most recent SI prefixes, adopted in November 2022, are 'quetta-' for 10^30 and 'quecto-' for 10^-30. 'Ronna-' and 'ronto-' were also introduced at the same time.

Explanation: The metre (m) for length, kilogram (kg) for mass, and second (s) for time are indeed among the seven base units defined by the International System of Units (SI).

Explanation: SI derived units are constructed by combining base units through multiplication, division, or both. For example, the newton (N), a unit of force, is defined as kg⋅m/s², illustrating this principle.

Explanation: The candela (cd) is the SI unit for luminous intensity. A standard 60-watt incandescent bulb, when radiating light uniformly, produces approximately 64 candelas.

Explanation: This statement reflects the concept of molar mass: one mole of any substance contains Avogadro's number of particles and has a mass in grams numerically equal to its atomic or molecular mass.

Explanation: This approximation is valid because the average molecular mass of air is approximately 29 g/mol. Thus, a gas with a molecular mass greater than 29 will be denser than air.

Explanation: The Joule (J) is an SI derived unit used for energy, defined as the work done when a force of one newton is applied over one metre (N⋅m). The seven SI base units are the metre, kilogram, second, ampere, kelvin, mole, and candela.

Explanation: SI derived units are formed by combining the seven base units through algebraic relations, typically involving multiplication and division, to express quantities like force, energy, or power.

Explanation: The molar mass of a substance, defined as the mass of one mole of that substance, is numerically equivalent to its atomic or molecular mass expressed in grams per mole (g/mol).

Explanation: The relative density of a gas compared to air can be approximated by dividing the gas's molecular mass by the average molecular mass of air, which is approximately 29 g/mol.

Explanation: The metre, ampere, and second are SI base units. The Newton (N), used to measure force, is an example of an SI derived unit, defined as kg⋅m/s².

Explanation: The introduction of units like the 'katal' for catalytic activity exemplifies the SI system's capacity for extension and adaptation to new scientific fields and measurement needs.

Explanation: The SI system evolved from the metre-kilogram-second (MKS) system, refining and standardizing definitions, particularly for electrical units, and establishing a more comprehensive framework.

Explanation: The history of the metric system includes various forms such as the CGS (centimetre-gram-second), MTS (metre-tonne-second), and gravitational metric systems, each with different base units or conventions.

Explanation: The CGS system faced challenges with coherence, particularly concerning energy, as it used distinct units for mechanical energy (erg) and thermal energy (calorie), whereas SI employs a single coherent unit, the joule.

Explanation: In the CGS system, the dyne is the unit of force, and the erg is the unit of energy. The statement incorrectly reverses these.

Explanation: The CGS system included distinct sets of units for electrostatic phenomena (cgs-esu) and electromagnetic phenomena (cgs-emu), which often led to cumbersome conversions and practical difficulties.

Explanation: The 1893 International Electrical Congress defined the 'international' ampere and ohm using the mechanical units of the metre, kilogram, and second, marking a significant step towards a coherent system including electrical units.

Explanation: Giovanni Giorgi's proposal in the early 20th century to add an electrical unit (ampere) as a fourth base unit to the metric system (leading to the MKSA system) was pivotal in unifying mechanics and electromagnetism.

Explanation: While the SI system was promulgated in 1960, the metre was redefined based on the wavelength of light emitted by krypton-86 atoms at that time. The definition based on the speed of light was adopted later, in 1983.

Explanation: The metre-tonne-second (MTS) system was indeed developed in France for industrial use and was officially adopted in the Soviet Union from 1933 until 1955.

Explanation: The International System of Units (SI) is largely based on the metre-kilogram-second (MKS) system, which provided a foundation for defining units in mechanics and later incorporated electrical units.

Explanation: The CGS system lacked coherence in energy units, employing the erg for mechanical energy and the calorie for thermal energy. SI resolved this by defining the joule as a single, coherent unit for all forms of energy.

Explanation: In the CGS system, the unit of force is the dyne, defined as the force required to accelerate a mass of one gram by one centimetre per second squared (g⋅cm/s²).

Explanation: The CGS system was characterized by having two distinct sets of units for electricity and magnetism: electrostatic units (esu) and electromagnetic units (emu), which often required complex conversion factors.

Explanation: Giovanni Giorgi proposed incorporating an electrical unit, specifically the ampere, as a fourth base unit to the existing metre-kilogram-second (MKS) system, leading to the development of the MKSA system.

Explanation: The metre was redefined in 1960, coinciding with the promulgation of the SI system, based on the wavelength of the orange-red emission line of krypton-86.

Explanation: The metre-tonne-second (MTS) system was developed in France for industrial applications and was adopted for use in the Soviet Union from 1933 to 1955.

Explanation: Upon the promulgation of the SI system in 1960, the definition of the metre was updated to be based on the wavelength of the spectral line of krypton-86.

Explanation: The centimetre-gram-second (CGS) system, developed in the 1860s and championed by prominent scientists like James Clerk Maxwell and Lord Kelvin, is recognized as the first coherent metric system.

Explanation: A significant advancement in the SI system is the redefinition of its base units based on invariant physical constants, such as the speed of light and the Planck constant, ensuring universal and stable definitions.

Explanation: The definition of the kilogram transitioned from the physical International Prototype of the Kilogram to a definition based on the exact value of the Planck constant, enhancing its stability and universality.

Explanation: The '*mise en pratique*' provides the detailed practical guidance necessary for laboratories to realize and measure each SI base unit, ensuring consistency and reproducibility.

Explanation: The modern definitions of SI base units are anchored in fundamental physical constants, providing a stable, universally accessible, and highly accurate basis for measurement.

Explanation: The modern SI framework defines its base units based on fundamental physical constants, ensuring greater precision, stability, and universality compared to earlier definitions tied to physical prototypes or specific measurements.

Explanation: The kilogram is now defined by the exact numerical value of the Planck constant (h), linking the unit of mass to a fundamental constant of quantum mechanics.

Explanation: The '*mise en pratique*' consists of the practical procedures and experimental methods that allow laboratories worldwide to realize and measure each SI base unit, ensuring consistency and traceability.

Explanation: The physical artefact defining the kilogram exhibited minute changes over time (drift), compromising the long-term stability and accuracy required for a fundamental unit. Redefining it based on the Planck constant resolved this issue.

Explanation: Units like the litre (L) and the degree (°), along with minutes and hours for time, are accepted for use with the SI system, even though they are not among the seven SI base units themselves.

Explanation: Oliver Heaviside advocated for 'rationalisation' in electromagnetic units to eliminate the factor of 1/(4π) that appeared frequently in Maxwell's equations, thereby simplifying the formulation.

Explanation: Despite the SI system's decimal foundation, common units of time such as minutes and hours retain their historical sexagesimal (base-60) relationships, rather than adopting decimal multipliers.

Explanation: The relationship between volume and mass for water is notably convenient: one litre of cold water has a mass very close to one kilogram.

Explanation: The metric system provides a simple relationship for water: one millilitre (mL) is equivalent to one cubic centimetre (cm³), and one millilitre of water has a mass of approximately one gram (g).

Explanation: The magnitude of a temperature difference is the same on both the Celsius and Kelvin scales; a change of 1°C corresponds to a change of 1 K. However, the Kelvin scale's zero point (absolute zero) is at -273.15°C.

Explanation: Gravitational metric systems, characterized by units such as the kilogram-force (kgf), are distinct from and not included within the framework of the International System of Units (SI).

Explanation: Units of time (minute, hour) and angle (degree, arcminute, arcsecond) are accepted for use with SI but retain their historical sexagesimal (base-60) structure, contrasting with the SI's decimal foundation.

Explanation: Heaviside's rationalisation aimed to remove the factor of 1/(4π) from equations involving electromagnetism, particularly those derived from Coulomb's law and Gauss's law, to simplify their appearance.

Explanation: Units such as minutes and hours, commonly used for time, are derived from ancient systems that employ sexagesimal (base-60) multipliers, despite the SI system's decimal foundation.

Explanation: Water exhibits a convenient property where one millilitre (which is equivalent to one cubic centimetre) has a mass of approximately one gram, simplifying many calculations.

Explanation: To convert a temperature from degrees Celsius (°C) to Kelvin (K), one adds approximately 273.15 to the Celsius value (K = °C + 273.15).

Explanation: The size of one degree Celsius is identical to the size of one Kelvin. Therefore, a temperature difference of 1°C is equivalent to a temperature difference of 1 K.

Explanation: Gravitational metric systems, which often employ units like the kilogram-force (kgf), are not officially recognized or included within the International System of Units (SI).

Explanation: The International System of Units (SI) is the predominant system of measurement globally. The United States is recognized as a primary example of a country that has not fully adopted the metric system for general use.

Explanation: Metrication is the established term used to describe the process by which a country or industry transitions to using the metric system of measurement.

Explanation: The initial definition of the metre, established during the French Revolution, was set as one ten-millionth of the distance from the North Pole to the Equator along the meridian passing through Paris.

Explanation: Gabriel Mouton, a vicar in Lyons, France, proposed a decimal system around 1665-1670, suggesting a unit of length based on one minute of arc of the Earth's circumference.

Explanation: The influential scientists Antoine and Marie-Anne Lavoisier were instrumental in developing an early version of the metric system during the French Revolution, grounding units in natural phenomena like the Earth's dimensions and the properties of water.

Explanation: The principal driver for reforming French weights and measures was the need to replace the chaotic and inconsistent array of local systems then in use, aiming for a unified, rational system, not alignment with British standards.

Explanation: In 1790, the French National Assembly resolved to establish a new system of weights and measures that was uniform, based on natural and invariable standards, and intended for universal adoption.

Explanation: Charles Maurice de Talleyrand-Périgord played a role in advocating for the adoption of a new, unified system of weights and measures, presenting proposals to the French National Assembly.

Explanation: The United States is widely recognized as a country that has not fully adopted the metric system for widespread use in commerce and daily life, despite its use in scientific and technical fields.

Explanation: The initial definition of the metre, established during the French Revolution, was based on the Earth's dimensions, specifically one ten-millionth of the distance from the North Pole to the Equator along a meridian.

Explanation: Gabriel Mouton, a French abbé, proposed a decimal system of measurement in the late 17th century, suggesting a unit of length derived from the Earth's circumference.

Explanation: The French Revolution sought to unify the nation by replacing the multitude of inconsistent and localized weights and measures with a single, rational, and universally applicable system.