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Torr

The torr (symbol: Torr) is a non-SI unit of pressure defined as exactly 1/760 of one standard atmosphere (101325 Pa), equivalent to 133.3224 pascals.^[1] It is approximately equal to one millimeter of mercury (mmHg) under standard conditions and is widely used in vacuum technology, scientific instrumentation, and measurements of low pressures.^[1] Named in honor of the Italian physicist and mathematician Evangelista Torricelli (1608–1647), who in 1643–1644 invented the mercury barometer and demonstrated the existence of atmospheric pressure, the torr provides a convenient scale for expressing pressures relative to the height of a mercury column.^[2] Torricelli's experiment involved filling a glass tube with mercury and inverting it into a dish, creating a vacuum above the mercury column that balanced at about 760 mm, establishing the basis for the unit.^[3] Although the pascal (Pa) is the SI unit for pressure, the torr remains prevalent in fields like analytical chemistry, mass spectrometry, and semiconductor manufacturing due to its historical ties to mercury manometers and ease of use in partial vacuum ranges (typically from 10⁻³ to 760 Torr).^[4] The unit's definition was refined in 1954 alongside updates to the standard atmosphere, ensuring its exact relation to the pascal, and it continues to serve as a bridge between traditional and modern pressure measurement systems.^[5]

Definition and Fundamentals

Definition

The torr is a non-SI unit of pressure defined as exactly 1/760 of one standard atmosphere (atm).^[1] Its origin is tied to experiments involving mercury barometers.^[5] The standard atmosphere is defined as exactly 101325 pascals (Pa).^[6] Therefore, one torr equals \frac{101325}{760} Pa, which is approximately 133.322 Pa.^[1] The torr is particularly suited for measuring low pressures in the range of fractions to several atmospheres, with widespread application in vacuum systems for processes such as semiconductor manufacturing and scientific instrumentation.^[7]^[5]

Relation to Atmospheric Pressure

The value of one standard atmosphere being equivalent to 760 torr originates from the pressure exerted by a column of mercury exactly 760 mm high under standard conditions of 0°C temperature and a gravitational acceleration of 980.665 cm/s² (defined at 45° latitude and sea level).^[8] This mercury column height, with a density of 13.5951 g/cm³ at 0°C, balances the force of atmospheric pressure at sea level, establishing the foundational relationship between torr and atmospheric pressure.^[8] The torr unit is thereby defined such that 1 torr equals exactly 1/760 of one atmosphere (1 torr = 1 mmHg).^[8] Under standard temperature and pressure (STP) conditions—defined as 0°C (273.15 K) and exactly 1 atm (101.325 kPa)—the pressure is precisely 760 torr.^[9] This exact equivalence ensures consistent reference in scientific measurements, particularly for gases and vacuum systems, where STP provides a baseline for volume and density calculations.^[9] The 760 mm mercury height reflects historical barometric observations at sea level under typical weather conditions, where the column equilibrates at this level to counter atmospheric force.^[8]

Historical Background

Torricelli's Contribution

Evangelista Torricelli, an Italian physicist and mathematician who served as an assistant to Galileo Galilei, conducted a pivotal experiment in 1643 that revolutionized the understanding of atmospheric pressure. Working in the aftermath of Galileo's inquiries into the nature of vacuums and the limits of water pumps, Torricelli sought to determine why water could not be raised more than about 10 meters in suction pumps. He devised an apparatus using mercury, a denser liquid than water, filling a long glass tube sealed at one end with mercury and then inverting it into a dish containing more mercury. Upon inversion, the mercury in the tube descended partially, leaving a space above it devoid of air or liquid, which Torricelli observed to be approximately 76 centimeters in height under normal conditions.^[10] This setup, now recognized as the first mercury barometer, demonstrated the existence of what became known as the Torricellian vacuum—the empty space at the top of the tube. Torricelli interpreted this phenomenon as evidence that the column of mercury was supported not by any inherent property of the liquid or tube, but by the weight of the surrounding air pressing down on the mercury in the dish. The experiment implied that air possesses weight and exerts a downward force, counterbalancing the mercury's tendency to flow out, thus providing the first quantitative insight into atmospheric pressure.^[10]^[11] Torricelli's innovation marked a departure from prevailing Aristotelian views that denied the possibility of a true vacuum, instead positing "horror vacui" as the force at play. By showing that the vacuum could be sustained and measured, his work laid the empirical foundation for modern pneumatics and barometry, influencing subsequent scientists like Blaise Pascal. This 1643 experiment in Italy ultimately inspired the naming of the torr unit of pressure in his honor centuries later.^[12]^[10]

Evolution into a Standard Unit

In the 19th century, the millimeter of mercury (mmHg) emerged as a widely accepted proxy for pressure measurement in scientific and engineering contexts, with the convention that 760 mmHg approximates one standard atmosphere becoming firmly established by the early 1800s through empirical observations and barometric standardization efforts.^[13] The 20th century marked a shift toward formalizing and naming this unit in honor of Evangelista Torricelli, whose barometer laid the groundwork for such measurements. The name "torr" was introduced around 1949 for the unit equivalent to 1 mmHg of mercury at 0 °C, promoting consistency in vacuum and low-pressure applications.^[14] This gained traction, and in 1954, the 10th General Conference on Weights and Measures (CGPM) precisely defined the standard atmosphere as 101 325 Pa, thereby establishing the torr exactly as 1/760 of this value, or 133.322 Pa. Further refinement occurred in 1971 when the 14th CGPM recognized the standard atmosphere as an accepted non-SI unit and adopted "pascal" (Pa) as the special name for the SI coherent unit of pressure (1 N/m²), solidifying the torr's precise alignment with the International System of Units while preserving its practical utility in fields like vacuum technology. By 1982, IUPAC reinforced the torr's role within modern metrology by incorporating the fixed standard atmosphere value into its recommendations for thermodynamic data tabulation, distinguishing it from the newly preferred standard pressure of 1 bar (10⁵ Pa) for certain calculations, though the torr retained its direct tie to the atmosphere for continuity in specialized measurements.^[15]

Nomenclature and Usage

Etymology and Symbol

The term "torr" originates from the surname of the Italian physicist and mathematician Evangelista Torricelli (1608–1647), who invented the mercury barometer in 1644 and laid the groundwork for understanding atmospheric pressure.^[14] The unit itself was introduced in 1949 within the field of vacuum technology to honor his contributions.^[14] In scientific literature, the standard symbol for the torr is "Torr," typically capitalized when used as an abbreviation following a numerical value, while the full unit name is written in lowercase as "torr" to conform to conventions for derived units.^[16] Although the single-letter abbreviation "T" has occasionally appeared, it is discouraged due to potential confusion with the SI unit symbol for the tesla (T), which measures magnetic flux density.^[16] The torr is accepted for use with the SI by the International Committee for Weights and Measures (CIPM).^[17] For clarity in vacuum technology publications, where precise low-pressure readings are essential, the torr is often denoted alongside manometric equivalents, such as "mmHg" to explicitly reference the millimeter-of-mercury scale (noting that 1 torr ≈ 1 mmHg under standard conditions).^[18] This notation helps distinguish vacuum measurements from other pressure contexts and ensures unambiguous interpretation in experimental reports and instrumentation specifications.^[19]

Common Errors in Application

One common error in applying the torr unit arises from conflating it with the millimeter of mercury (mmHg), particularly in manometric measurements where temperature effects are overlooked. While 1 torr is defined exactly as \frac{1}{760} of a standard atmosphere (101325 Pa), equivalent to 133.322368421 Pa, the mmHg represents the pressure exerted by a 1 mm column of mercury at 0°C under standard gravity (9.80665 m/s²) with a density of 13.5951 g/cm³, yielding exactly 133.322387415 Pa. This results in a small but non-zero difference: 1 torr ≈ 0.999999897 mmHg at 0°C. However, for manometers operated at elevated temperatures, such as room temperature (around 20°C), the mercury density decreases due to thermal expansion (coefficient ≈ 1.818 × 10^{-4} /°C), requiring a correction factor to report accurate mmHg values standardized to 0°C. Failure to apply this correction—approximately 0.9964 at 20°C for brass scales, meaning the observed height must be multiplied by this factor to obtain the equivalent 0°C reading—can introduce errors up to 0.36% in pressure measurements.^[8] A related misconception is assuming a universal exact equivalence of 1 torr = 1 mmHg regardless of conditions, ignoring both the intrinsic definitional discrepancy and temperature-dependent variations in mercury density. The slight offset between the units (on the order of 1.3 × 10^{-7} relative difference) is negligible for most applications, but when combined with temperature effects, uncorrected manometer readings at 20°C can deviate by about 0.0035 in the correction factor for scale and mercury expansion, leading to systematic overestimation of pressure if the observed height is taken as is. For instance, a reading of 760 mmHg at 20°C corresponds to approximately 757 mmHg when corrected to 0°C standards, highlighting the need for explicit temperature adjustments in precise work such as vacuum systems or barometry. This error is particularly problematic in fields like chemistry and meteorology, where unadjusted conversions propagate inaccuracies in gas law calculations or atmospheric data.^[8]^[1] Another frequent misuse occurs in high-pressure contexts, where the torr unit is not conventionally used for values exceeding 1000 torr, as it is primarily suited to low-pressure and vacuum applications due to its historical ties to mercury manometers. Although 760 torr = 1 atm exactly by definition, for pressures above 1 atm, units like pascals or bars provide finer resolution and align with SI standards in engineering fields such as compressor design or hyperbaric systems. Relying on torr in these ranges can lead to unnecessary conversion errors or inconsistencies with international practices, with recommendations to switch to SI units for better applicability beyond atmospheric pressures.^[1]^[20]

Manometric Units

Manometric units of pressure are empirical measures derived from the hydrostatic pressure exerted by a column of liquid, providing a straightforward means to quantify pressure through observable physical dimensions. These units stem from the fundamental relationship in fluid statics, where the pressure P at the base of a fluid column is given by the equation

P = \rho g h

with \rho denoting the density of the fluid, g the acceleration due to gravity, and h the height of the column.^[8]^[21] This approach allows for direct calibration using gravitational effects, making manometers—devices that exploit this principle—essential tools in pressure measurement across various scientific and engineering contexts. Prominent examples of manometric units include the millimeter of mercury (mmHg), based on a column of mercury (density approximately 13,600 kg/m³ at 0°C), and the centimeter of water (cmH₂O), utilizing water (density approximately 1,000 kg/m³ at standard conditions). The mmHg unit reflects the pressure supported by a 1 mm height of mercury under standard gravity, while cmH₂O corresponds to a 1 cm water column, offering suitability for lower pressure ranges due to water's lower density. The torr, defined equivalently to 1 mmHg under these conditions, integrates seamlessly into this framework, particularly in applications requiring precise vacuum assessments.^[8]^[21] In vacuum technology, manometric units like torr and mmHg excel due to their direct readability from barometric instruments, such as U-tube manometers or mercury barometers, where the fluid column height provides an immediate visual indication of pressure without necessitating complex density corrections for approximate measurements. This simplicity facilitates rapid assessments in rough vacuum regimes, from atmospheric pressure down to about 1 Torr, enhancing practicality in laboratory and industrial settings where portability and minimal setup are prioritized. Mercury-based units, in particular, benefit from the fluid's high density, allowing compact instruments compared to water-based alternatives, which require taller columns for equivalent pressures.^[8]^[21]

Comparison with SI Units

The pascal (Pa), the SI derived unit of pressure, is defined as exactly one newton per square meter, equivalent to one kilogram per meter-second squared (1 Pa = 1 kg·m⁻¹·s⁻²). This absolute definition ensures high precision and coherence within the SI system, making it suitable for scientific and engineering applications requiring exact force-per-area measurements. In contrast, the torr is a non-SI unit accepted for use with the SI, defined exactly as 1/760 of one standard atmosphere, or (101325/760) Pa ≈ 133.322 Pa. This relation positions the torr as a larger unit than the pascal, with one torr corresponding to roughly 133 Pa, which provides a convenient scale for pressures where pascals would require cumbersome prefixes like kilo- or millipascals. For instance, standard atmospheric pressure is exactly 101325 Pa or 760 torr, rendering the torr coarser than the pascal—by a factor of about 133—but finer than the atmosphere for intermediate ranges, particularly in vacuum technology where pressures from roughly 10^{-3} to 1000 Pa (about 7.5 × 10^{-6} to 7.5 torr) are common.^[22] Although the modern definition of the torr establishes an exact conversion to the pascal, its historical basis in mercury manometry introduced minor rounding discrepancies relative to the physical millimeter of mercury (mmHg), with 1 torr differing from the standard mmHg by approximately 0.000015% due to mercury's density at 0°C.^[23] This legacy can limit its precision in ultra-accurate SI-compliant contexts compared to the pascal's fundamental definition. Consequently, the torr is recommended primarily for non-SI environments, such as altimetry (where barometric pressures near 760 torr are routine) and mass spectrometry (where vacuum levels of 10^{-5} to 10^{-8} torr are standard for ion handling).^[24]

Conversion Formulas

To Pascal and Atmosphere

The torr is defined relative to the standard atmosphere as exactly $1/760 atm, providing a direct and precise conversion between the two units.^[5] This relationship yields $1 torr = 1/760 atm, or equivalently, to convert torr to atmospheres, divide the value in torr by 760.^[25] For conversion to the SI unit of pressure, the pascal (Pa), the exact value is derived from the fixed definition of 1 atm = 101325 Pa, established by Resolution 4 of the 10th Conférence Générale des Poids et Mesures (CGPM) in 1954 to ensure consistent and reproducible measurements.^[26] Thus,

$1 \text{ torr} = \frac{101325}{760} \text{ Pa} = 133.322368421 \text{ Pa}.

This exact equivalence allows for straightforward multiplication: to convert a pressure P in torr to pascals, compute P \times 133.322368421.^[5] In practical applications requiring three significant figures, such as preliminary engineering estimates or vacuum technology specifications, 1 torr \approx [133.3](/page/Approximation) Pa serves as a reliable approximation without significant loss of accuracy.^[27] This rounded value simplifies mental arithmetic while maintaining alignment with the exact derivation.^[5]

Practical Conversion Examples

In vacuum systems, a pressure of 100 torr represents a low vacuum level commonly encountered in rough vacuum applications, such as initial pump-down stages in industrial processes. To convert this to pascals, multiply by the standard factor of 133.322 Pa per torr, yielding approximately 13,332 Pa.^[28]^[29] In meteorology, standard atmospheric pressure at sea level is defined as 760 torr, which equates exactly to 101,325 Pa or 1 atmosphere. At higher altitudes, such as 5,000 feet (approximately 1,524 meters), the pressure drops to about 632 torr due to the decrease in air density with elevation.^[30] In medical contexts, blood pressure measurements are typically reported in millimeters of mercury (mmHg), where 1 mmHg is conventionally treated as equivalent to 1 torr for practical purposes. For example, a typical systolic blood pressure of 120 mmHg corresponds to approximately 120 torr, or about 16,000 Pa when converted using the torr-to-pascal factor. This equivalence assumes standard conditions and is widely used in clinical settings despite minor technical differences in the units' definitions.^[31]^[28]

References

[1]
Pressure and Gas Flow Unit Conversions | NIST
1 Torr ˜ 1.33 mbar ˜ 1 mbar. Chemistry, Chemical engineering and processing, Metrology, Pressure and vacuum metrology, Standards and Calibration services ...
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Evangelista Torricelli
To recognize Torricelli's contributions, some scientists describe pressure in units of "torr," which are defined as follows. 1 torr = 1 mmHg. fig4_5.gif ...
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Evangelista Torricelli and the mercury barometer - Leybold USA
Torricelli died in Florence in 1647 and the unit of pressure 1mmHg was named as 1 Torr, in his honour.
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Sep 22, 2014 · The Torr unit (named after Torricelli) has been defined as 1 millimeter of mercury (1 Torr = 1 mmHg). This unit, as well as the use of the ...
[5]
Torr Pressure Unit - SensorsONE
Torr is a pressure unit which is defined as 1 standard atmosphere divided by 760 (1 atm/760 or 101325 Pa/760). Used mostly for measuring high vacuum.
[6]
atm – Standard Atmosphere Pressure Unit - SensorsONE
1 standard atmosphere is defined as being exactly equal to 101,325 pascals. Since the atmospheric pressure varies with changes in weather and altitude, it ...
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Vacuum Measurement Principles - MKS Instruments
A derivative of the Torr often used in semiconductor process vacuum measurements is the millitorr or 1/1000th Torr.
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[PDF] Mercury barometers and manometers
... Standard conditions are defined and the pertinent properties of mercury ... mercury barometers in which the height of a column of mercruy is a measure ...
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Mar 26, 2019 · of 2 L/min at standard temperature and pressure (STP), defined as 0 °C and 101.33 kPa. In subsequent discussions, gas flow rates are ...
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Torricelli was the first to make a mercury barometer and understand that the mercury was supported by the pressure of the air.
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The measurement of atmospheric pressure has a long history, which begins with the famous experiment of Evangelista Tor- ricelli in 1643. It was not long ...<|control11|><|separator|>
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In 1643 Evangelista Torricelli, who had studied under Galileo, began wondering if the 33-foot limit had more to do with the weight of the air outside the ...
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Feb 8, 2017 · In this blog post, I will discuss the basics of different pressure units and different pressure unit families.What Is Pressure? · What Is Pascal? · Liquid Column Units
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IUPAC recommendation since 1982 [1.j], and is recommended for tabulating ... torr (unit of pressure), 81, 131, 138 u displacement vector, 42 u velocity ...
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torr (n.) unit of pressure, 1949, named for Italian physicist Evangelista Torricelli (1608-1647), inventor of the barometer.Missing: name IUPAC
[16]
Torr Definition in Science - ThoughtCo
Jun 9, 2025 · A torr is a unit of pressure defined to be exactly 1/760 of one standard atmosphere. One torr is approximately 133.32 Pa.
[17]
[PDF] GENERAL INFORMATION For 14033 & 14034 - Ace Glass, Inc.
All pressures (vacuum) are referenced to absolute zero pressure using millimeters. (mm) of mercury for scale measurements. 760 mm (Torr) is the sea level ...
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Dec 1, 2016 · The partial pressure of a certain gas or vapor is the pressure ... mm (torr) if d and V are measured in mm or mm3. If the scale is to ...
[19]
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One “torr,” a unit named in honor of Torricelli, is equivalent to one millimeter of mercury, yielding the figure of 760 torr as normal atmospheric pressure ...
[20]
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This brochure is meant to provide an easy to read overview covering the entire range of vacuum technology and is inde- pendent of the current Oerlikon Leybold ...
[21]
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Feb 1, 2016 · NIST Guide to the SI, Appendix A: Definitions of the SI Base Units ... torr (Torr), pascal (Pa), 1.333 224, E+02. Scroll. Return to top ...
[22]
Overview of Mass Spectrometry for Protein Analysis
Mass spectrometry is a sensitive technique used to detect, identify and ... This entire process is performed under an extreme vacuum (10-6 to 10-8 torr) ...
[23]
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Aug 12, 2019 · The unit millimeters of mercury is also called a torr, named after the Italian scientist Evangelista Torricelli, who invented the barometer in ...Missing: 1982 | Show results with:1982
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10th meeting of the CGPM (1954). 5 to 14 October 1954. Meeting report. 10th ... Definition of the standard atmosphere. DOI : 10.59161/CGPM1954RES4E. CGPM ...
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Feb 1, 2016 · NIST Guide to the SI, Appendix A: Definitions of the SI Base Units ... torr (Torr), pascal (Pa), 1.333 224, E+02. Scroll. Return to top. U. To ...
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torr (Torr) pascal. (Pa). 133.322 4. 5.2.10. Viscosity (dynamic) centipoise ... For print copies of NIST SP 330, NIST SP 811 or NIST SP 814 or other assistance ...
[27]
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Convert between vacuum units - torr, mm Mercury and psi. The vacuum level is the difference in pressure between atmospheric pressure and pressure in the ...
[28]
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FEET. MBAR (1). TORR. PSIA IN. Hg.(2). ALTITUDE. FEET. PRESSURE. MBAR (1). TORR. PSIA ... 5,000. 843.1. 632.5. 12.23. 24.90. 80,000. 27.84. 20.88. 404. 822. -1 ...
[29]
Convert mmHg to Torr - Pressure Conversions - CheckYourMath
Millimeters of mercury is a non-SI unit of Pressure. The symbol for millimeters of mercury is mmHg. There is 1 mmHg in a torr.