torr (torr) to millibar (mbar) conversion

What is torr?

Torr is a unit of pressure measurement commonly used in vacuum applications. Let's delve into its definition, origin, and relevance.

Definition of Torr

The torr is a unit of pressure defined as 1/760 of standard atmospheric pressure. In other words, 760 torr is approximately equal to one atmosphere (atm).

$$1 \text{ torr} \approx \frac{1}{760} \text{ atm}$$

It is also nearly equal to one millimeter of mercury (mmHg). More precisely:

$$1 \text{ torr} \approx 1 \text{ mmHg}$$

Origin and History

The torr is named after Italian physicist and mathematician Evangelista Torricelli (1608–1647), who invented the barometer in 1643. Torricelli's experiment demonstrated that air pressure could support a column of mercury, paving the way for pressure measurement.

Relation to Pascal (Pa)

The pascal (Pa) is the SI unit of pressure. The relationship between torr and pascal is as follows:

$$1 \text{ torr} \approx 133.322 \text{ Pa}$$

Therefore, to convert from torr to pascals, you can use the formula:

$$\text{Pressure in Pa} = \text{Pressure in torr} \times 133.322$$

Real-World Examples and Applications

Torr is commonly used in fields that involve vacuum systems, such as:

• Vacuum pumps: Vacuum pump performance is often rated in torr or millitorr (mTorr). For example, a roughing pump might achieve a vacuum of 10$^{-3}$ torr.
• Scientific instruments: Mass spectrometers, electron microscopes, and other analytical instruments require high vacuum conditions, often specified in torr or microtorr (µTorr).
• Semiconductor manufacturing: Vacuum processes, such as chemical vapor deposition (CVD) and sputtering, use vacuum levels measured in torr to control deposition rates and film quality.
• Space research: Simulating space environments requires extremely low pressures, which are measured in torr or even smaller units like picotorr (pTorr).
• Vacuum Furnaces: Sintering, brazing, and heat treating of materials at reduced pressures, which improves the properties of the final product.

Interesting Facts

• While torr and mmHg are often used interchangeably, they are technically slightly different due to variations in the definition of standard gravity.
• The unit "micron" (µ) is sometimes used as a unit of pressure, where 1 micron = 1 mTorr.
• The lowest pressure ever achieved in a laboratory setting is on the order of $10^{-17}$ torr.

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.