millibar (mbar) to millimeters of mercury (mmHg) conversion

What is millibar?

The millibar (mbar) is a unit of pressure commonly used in meteorology to measure atmospheric pressure. Understanding millibars helps in interpreting weather patterns and forecasts. Below is an overview of millibars, their relation to other units, and their significance.

Definition of Millibar

A millibar is defined as 100 Pascals (Pa), where a Pascal is the SI unit of pressure (force per unit area). The prefix "milli-" indicates one-thousandth, so:

$$1 \text{ mbar} = 100 \text{ Pa} = 1 \text{ hPa}$$

Another unit of pressure is standard atmosphere (atm)

$$1 \text{ atm} = 1013.25 \text{ mbar}$$

Formation and History

The term "bar" comes from the Greek word "báros," meaning weight. The bar was introduced by the British physicist Napier Shaw in 1909, and the millibar soon followed as a more practical unit for meteorology because typical atmospheric pressures on Earth are close to 1000 mbar.

Relation to Other Units

• Pascal (Pa): The SI unit of pressure. $1 \text{ mbar} = 100 \text{ Pa}$.
• Hectopascal (hPa): $1 \text{ hPa} = 1 \text{ mbar}$. Hectopascals are numerically equivalent to millibars and are commonly used in aviation.
• Atmosphere (atm): Standard atmospheric pressure at sea level is approximately $1013.25 \text{ mbar}$.
• Inches of Mercury (inHg): Commonly used in aviation in the United States. $1 \text{ mbar} \approx 0.02953 \text{ inHg}$.

Significance in Meteorology

Atmospheric pressure is a critical factor in weather forecasting. Here's how millibars are used:

• Weather Maps: Isobars (lines of equal pressure) on weather maps are often labeled in millibars, showing high and low-pressure systems.
• High-Pressure Systems: Associated with stable weather conditions, typically ranging from 1015 mbar to 1035 mbar or higher.
• Low-Pressure Systems: Associated with unsettled weather, such as storms and rain, typically ranging from 980 mbar to 1000 mbar or lower.
• Storm Intensity: The central pressure of a hurricane or cyclone is measured in millibars; lower pressures indicate stronger storms. For example, Hurricane Wilma in 2005 had a record low central pressure of 882 mbar.
• Aviation: Altitude is determined by measuring atmospheric pressure

Real-World Examples

• Standard Sea Level Pressure: The standard atmospheric pressure at sea level is approximately $1013.25 \text{ mbar}$.
• Hurricane Central Pressure: Intense hurricanes can have central pressures below $950 \text{ mbar}$. For example, Hurricane Katrina (2005) had a minimum central pressure of around $902 \text{ mbar}$.
• Mount Everest Summit Pressure: The atmospheric pressure at the summit of Mount Everest is roughly $330 \text{ mbar}$.
• Typical House Pressure: The pressure inside buildings is near $1013.25 \text{ mbar}$.

Interesting Facts and Associations

• Torricelli's Experiment: Evangelista Torricelli, an Italian physicist, invented the barometer in the 17th century, paving the way for accurate pressure measurement. Though he didn't use millibars (as the unit wasn't invented yet), his work laid the foundation for understanding atmospheric pressure. Learn more at Britannica.
• Beaufort Scale: While the Beaufort scale primarily measures wind speed, it indirectly relates to pressure gradients. Steeper pressure gradients (indicated by closely spaced isobars) typically result in stronger winds. More information is on the National Weather Service.

What is millimeters of mercury?

Millimeters of mercury (mmHg) is a unit of pressure, often used in medicine (especially blood pressure) and meteorology. It represents the pressure exerted by a column of mercury one millimeter high at a standard temperature. Let's delve into its definition, history, and applications.

Definition and Formation

Millimeters of mercury (mmHg) is a manometric unit of pressure. Specifically, it's the pressure exerted at the base of a column of mercury exactly 1 millimeter high when the density of mercury is 13,595.1 kg/m³ and the local acceleration of gravity is exactly 9.80665 m/s². It's not an SI unit, but it is accepted for use with the SI.

While not an official SI unit (Pascal is the SI unit for pressure), mmHg remains widely used due to its historical significance and practical applications, especially in fields like medicine.

History and Torricelli's Experiment

The unit originates from Evangelista Torricelli's experiments in the 17th century. Torricelli, an Italian physicist and mathematician, invented the mercury barometer in 1643. He filled a glass tube with mercury and inverted it into a dish of mercury. The mercury column would fall, leaving a vacuum at the top, and the height of the column was proportional to the atmospheric pressure. This led to the standardized measurement of pressure using the height of a mercury column. Read more about it in Britannica.

Relation to Other Units

• Pascal (Pa): The SI unit of pressure. 1 mmHg is approximately equal to 133.322 Pascals.

  $$1 \, mmHg \approx 133.322 \, Pa$$

• Atmosphere (atm): A standard unit of pressure. 1 atm is equal to 760 mmHg.

  $$1 \, atm = 760 \, mmHg$$

• Torr: Named after Torricelli, 1 Torr is very close to 1 mmHg. For most practical purposes, they are considered equivalent.

  $$1 \, Torr \approx 1 \, mmHg$$

Real-World Examples and Applications

• Blood Pressure: In medicine, blood pressure is commonly measured in mmHg. For example, a blood pressure reading of 120/80 mmHg indicates a systolic pressure of 120 mmHg and a diastolic pressure of 80 mmHg. The first number represents the pressure in the arteries when the heart beats (systolic pressure) and the second number represents the pressure in the arteries between beats (diastolic pressure).

• Atmospheric Pressure: Meteorologists often use mmHg to report atmospheric pressure. Standard atmospheric pressure at sea level is 760 mmHg. Changes in atmospheric pressure are often precursors to changes in weather.

• Vacuum Gauges: Many vacuum gauges, particularly older or specialized instruments, display pressure in mmHg. Low pressures in vacuum systems, such as those used in scientific experiments or manufacturing processes, are often expressed in mmHg or fractions thereof (e.g., milliTorr, which is approximately 1/1000 of a mmHg).

• Aircraft Altimeters: Aircraft altimeters use atmospheric pressure to determine altitude. While the actual scale on the altimeter might be in feet or meters, the underlying pressure measurement is often related to mmHg.

Important Considerations

While mmHg is widely used, it's essential to be aware of its limitations:

• Temperature Dependence: The density of mercury varies with temperature, so precise measurements require temperature corrections.
• Local Gravity: Although standardized, the local acceleration due to gravity can vary slightly depending on location, potentially affecting accuracy.