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Fahrenheit to Rankine Converter

Convert degrees Fahrenheit to degrees Rankine with our free online temperature converter.

Quick Answer

1 Fahrenheit = 460.67 degrees Rankine

Formula: Fahrenheit × conversion factor = Rankine

Use the calculator below for instant, accurate conversions.

Our Accuracy Guarantee

All conversion formulas on UnitsConverter.io have been verified against NIST (National Institute of Standards and Technology) guidelines and international SI standards. Our calculations are accurate to 10 decimal places for standard conversions and use arbitrary precision arithmetic for astronomical units.

Last verified: February 2026Reviewed by: Sam Mathew, Software Engineer

Fahrenheit to Rankine Calculator

How to Use the Fahrenheit to Rankine Calculator:

  1. Enter the value you want to convert in the 'From' field (Fahrenheit).
  2. The converted value in Rankine will appear automatically in the 'To' field.
  3. Use the dropdown menus to select different units within the Temperature category.
  4. Click the swap button (⇌) to reverse the conversion direction.
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How to Convert Fahrenheit to Rankine: Step-by-Step Guide

Temperature conversions like Fahrenheit to Rankine use specific non-linear formulas.

Formula:

°R = °F + 459.67

Example Calculation:

Convert 10°F: 10 + 459.67 = 469.67°R

Disclaimer: For Reference Only

These conversion results are provided for informational purposes only. While we strive for accuracy, we make no guarantees regarding the precision of these results, especially for conversions involving extremely large or small numbers which may be subject to the inherent limitations of standard computer floating-point arithmetic.

Not for professional use. Results should be verified before use in any critical application. View our Terms of Service for more information.

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What is a Fahrenheit and a Rankine?

Degree Fahrenheit (symbol: °F) is a unit of temperature on the Fahrenheit scale, developed by physicist Daniel Gabriel Fahrenheit in 1724. It is one of the most commonly used temperature scales in the United States.

Key reference points:

  • Water freezing point: 32°F (at standard atmospheric pressure)
  • Water boiling point: 212°F (at standard atmospheric pressure)
  • Degree span: 180°F between freezing and boiling (212 - 32 = 180)
  • Absolute zero: -459.67°F (theoretical lowest temperature)

Conversion formulas:

Common temperature ranges:

  • Below 0°F: Extremely cold
  • 0-32°F: Very cold (below freezing)
  • 32-50°F: Cold
  • 50-65°F: Cool
  • 65-75°F: Comfortable/room temperature
  • 75-85°F: Warm
  • 85-95°F: Hot
  • Above 95°F: Very hot

Note: The degree symbol (°) is always used with Fahrenheit. Write "32°F" not "32F" or "32 degrees F."

Convert between temperature units: Fahrenheit converter

What Is the Rankine Scale?

The Rankine scale (symbol: °R or °Ra) is an absolute thermodynamic temperature scale where:

  • Zero point: Absolute zero (0 °R = −459.67 °F), the theoretical lowest possible temperature where all molecular kinetic energy ceases
  • Degree size: Equal to Fahrenheit degrees (1 °R increment = 1 °F increment)
  • Named after: William John Macquorn Rankine (1820-1872), Scottish engineer and physicist

Absolute Temperature Scales

An absolute temperature scale begins at absolute zero rather than an arbitrary freezing point:

Absolute scales (start at absolute zero):

  • Kelvin (K): Uses Celsius-sized degrees, 0 K = absolute zero, used worldwide in science
  • Rankine (°R): Uses Fahrenheit-sized degrees, 0 °R = absolute zero, used in some U.S. engineering

Relative scales (start at arbitrary points):

  • Celsius (°C): 0 °C = water's freezing point (at standard pressure)
  • Fahrenheit (°F): 0 °F = freezing point of brine solution, 32 °F = water's freezing point

Why Absolute Scales Matter

Many fundamental physics equations require absolute temperatures because ratios and products become meaningful only when zero truly means "no thermal energy":

Ideal gas law: PV = nRT (T must be absolute) Carnot efficiency: η = 1 - T_cold/T_hot (requires absolute temperatures) Stefan-Boltzmann law: Power radiated ∝ T⁴ (absolute temperature to fourth power) Entropy calculations: ΔS = Q/T (T must be absolute to avoid division by zero)

Using relative scales (Fahrenheit, Celsius) in these equations produces nonsensical results. Absolute scales (Rankine, Kelvin) make the mathematics work correctly.

Official Definition

1 degree Rankine = 1 degree Fahrenheit (in size)

Relationship to Fahrenheit: °R = °F + 459.67

Relationship to Kelvin: °R = K × 9/5 (or °R = K × 1.8)

Relationship to Celsius: °R = (°C + 273.15) × 9/5

Note: The Fahrenheit is part of the imperial/US customary system, primarily used in the US, UK, and Canada for everyday measurements. The Rankine belongs to the imperial/US customary system.

History of the Fahrenheit and Rankine

  • Daniel Gabriel Fahrenheit (1686-1736): A Polish-German physicist and instrument maker who invented the mercury thermometer and developed the Fahrenheit temperature scale.

  • Early Development (1724): Fahrenheit proposed his temperature scale with three reference points:

    • 0°F: Temperature of a brine solution (mixture of ice, water, and ammonium chloride salt) - the coldest temperature he could reliably reproduce in his laboratory
    • 32°F: Freezing point of water (later standardized)
    • 96°F: Human body temperature (later adjusted to 98.6°F)

  • Original Rationale: Fahrenheit chose these points to:

    • Avoid negative numbers in normal weather (unlike earlier scales)
    • Create finer graduations for better precision (180 degrees between freezing and boiling vs 100 in Celsius)
    • Use easily reproducible reference points with 18th-century technology

  • Refinements (1750s onward): The scale was gradually standardized:

    • Water's freezing point: exactly 32°F
    • Water's boiling point: exactly 212°F (at standard atmospheric pressure)
    • This created 180 degrees between the two points
    • Human body temperature was remeasured at 98.6°F (not 96°F)

  • Rapid Adoption (1700s-1800s): The Fahrenheit scale quickly became popular:

    • Adopted throughout the British Empire
    • Standard in English-speaking countries
    • Used in scientific work until the late 19th century
    • Mercury thermometers using Fahrenheit became widespread

  • Celsius Competition (1742): Anders Celsius proposed the centigrade scale (later renamed Celsius) with 0° at water freezing and 100° at boiling. Simpler, but both scales coexisted.

  • Metric Movement (1900s): As the metric system spread globally:

    • Most countries switched from Fahrenheit to Celsius
    • Scientific community adopted Celsius/Kelvin
    • UK officially switched to Celsius in the 1960s-1970s
    • Canada switched to Celsius in the 1970s

  • United States Today: The US remains the only major country using Fahrenheit for everyday temperatures:

    • Weather forecasts in °F
    • Thermostats and home heating/cooling in °F
    • Cooking temperatures in °F
    • Medical thermometers in °F (though hospitals also use Celsius)
    • Scientific and medical research uses Celsius/Kelvin

  • Why the US Kept Fahrenheit:

    • Deeply ingrained in culture and infrastructure
    • Costly to replace all thermostats, ovens, signs
    • Public resistance to metric conversion
    • Fahrenheit provides finer resolution for weather (1°F = 0.56°C)

  • Global Usage Today:

    • Primary users: United States, some Caribbean nations (Bahamas, Belize, Cayman Islands), Palau, Federated States of Micronesia, Marshall Islands
    • Former users: UK, Canada, Australia (all switched to Celsius)
    • Rest of world: Uses Celsius exclusively

  • Cultural Impact: Fahrenheit remains a distinctive American characteristic, like miles and pounds, symbolizing resistance to metric adoption.

Historical Anecdote: The Case of the Missing 2.6 Degrees

Why did the body temperature change from Fahrenheit's original 96°F to the modern 98.6°F?

  1. Measurement Error: Early 18th-century thermometers were not yet standardized.
  2. The Brine Mystery: Fahrenheit used the freezing point of brine for 0°F, but the concentration of ammonium chloride and ice varies.
  3. Wunderlich's Research: In 1851, German physician Carl Reinhold August Wunderlich measured the temperatures of 25,000 patients and established the "new" average of 37°C, which was converted to 98.6°F.

Fahrenheit in Science Fiction: The Branding of Heat

The Fahrenheit scale has entered popular culture as a symbol of intense heat. Ray Bradbury's novel Fahrenheit 451 refers to the temperature at which book paper catches fire and burns. While scientists argue that the actual ignition temperature of paper varies with the type of paper and the oxygen levels, "451°F" has become an iconic cultural reference for censorship and destruction.

William John Macquorn Rankine (1820-1872)

William Rankine was a Scottish engineer, physicist, and professor at the University of Glasgow who made foundational contributions to thermodynamics, civil engineering, and molecular physics.

Key contributions:

  • Formulated the Rankine cycle (1859), describing the ideal thermodynamic cycle for steam engines
  • Developed the Rankine temperature scale (1859) as an absolute scale compatible with Fahrenheit
  • Wrote influential textbooks on applied mechanics, steam engines, and civil engineering
  • Co-founded the science of thermodynamics alongside Carnot, Clausius, Kelvin, and Joule

Rankine was a contemporary and correspondent of William Thomson (Lord Kelvin), who proposed the Kelvin absolute scale in 1848. The two scientists worked on similar thermodynamic problems but approached them from different engineering traditions—Kelvin from metric/Celsius contexts, Rankine from British imperial/Fahrenheit contexts.

The Need for an Absolute Scale (1840s-1850s)

The mid-19th century saw rapid developments in thermodynamics driven by the Industrial Revolution's reliance on steam engines:

Carnot's theorem (1824): Sadi Carnot demonstrated that heat engine efficiency depends on the temperature ratio between hot and cold reservoirs, implicitly requiring an absolute temperature scale

Joule's mechanical equivalent of heat (1843-1850): James Prescott Joule established that heat and mechanical work are interconvertible, laying foundations for the first law of thermodynamics

Thomson's (Kelvin's) absolute scale (1848): William Thomson proposed an absolute scale based on Carnot's theorem, using Celsius degree increments, with zero at −273.15 °C

These developments made clear that thermodynamic calculations required absolute temperature measurements, but Thomson's Kelvin scale was impractical for British and American engineers who worked exclusively in Fahrenheit.

Rankine's Proposal (1859)

In 1859, Rankine published his absolute temperature scale in engineering papers, presenting it as the practical solution for engineers who needed absolute temperatures but worked in imperial units:

Rankine's logic:

  1. Thermodynamic calculations require absolute zero as the baseline
  2. British and American engineers measure temperature in Fahrenheit
  3. Constantly converting Fahrenheit ↔ Celsius ↔ Kelvin introduces errors and inefficiency
  4. An absolute scale with Fahrenheit-sized degrees solves the problem elegantly

The result: 0 °R = absolute zero (−459.67 °F), with degree increments matching Fahrenheit

This allowed engineers to use familiar Fahrenheit measurements while accessing the mathematical benefits of absolute temperature.

Adoption in Engineering (1860s-1960s)

The Rankine scale became standard in British and American engineering disciplines throughout the late 19th and first half of the 20th centuries:

Steam engineering: Rankine cycle analysis (for steam turbines, power plants) used Rankine temperatures for efficiency calculations

ASME standards: The American Society of Mechanical Engineers incorporated Rankine into standard tables for steam properties, refrigeration cycles, and combustion calculations

Aerospace engineering: Early rocket and jet engine development (1940s-1960s) used Rankine for combustion chamber and exhaust nozzle temperature calculations

Cryogenics: Liquefied gas industries (oxygen, nitrogen, hydrogen) used Rankine when working with U.S. measurement systems

Thermodynamics textbooks: Engineering thermodynamics texts published in the U.S. and U.K. through the 1960s routinely presented equations in both Kelvin and Rankine

Decline and Modern Usage (1960s-Present)

Several factors led to Rankine's decline:

International metrication (1960s-1980s): Most countries adopted SI units (including Kelvin), making Rankine unnecessary outside the United States

Scientific standardization: The global scientific community standardized on Kelvin, making it the universal absolute scale for research and international collaboration

U.S. engineering education shift: Even American engineering programs increasingly taught Kelvin as the primary absolute scale, relegating Rankine to historical footnotes

Computing and automation: Modern engineering software typically works in SI units (Kelvin), reducing incentive to maintain Rankine compatibility

Where Rankine Survives Today

Despite its decline, Rankine persists in specific niches:

American aerospace engineering: NASA and aerospace contractors occasionally use Rankine in rocket propulsion calculations when working with U.S. customary units (pounds-force, BTU, etc.)

Cryogenic engineering: Liquefied natural gas (LNG) facilities and industrial gas companies in the U.S. may use Rankine for process calculations

Legacy documentation: Older engineering manuals, equipment specifications, and technical standards still reference Rankine, requiring continued familiarity

Thermodynamics education: Some U.S. engineering thermodynamics courses teach Rankine alongside Kelvin to demonstrate absolute temperature concepts with Fahrenheit context

Historical research: Engineers and historians studying 19th-20th century technology encounter Rankine in original documents and must understand conversions

Common Uses and Applications: degrees Fahrenheit vs degrees Rankine

Explore the typical applications for both Fahrenheit (imperial/US) and Rankine (imperial/US) to understand their common contexts.

Common Uses for degrees Fahrenheit

Fahrenheit is the standard temperature scale for daily life in the United States:

Weather Reporting

Primary temperature scale for weather forecasts and reporting in the United States and its territories.

Weather applications:

  • Daily temperature forecasts (high/low)
  • Current temperature readings
  • Heat index calculations
  • Wind chill factor
  • Severe weather alerts (heat advisories, freeze warnings)
  • Historical climate data
  • Weather maps and graphics

Why Fahrenheit in weather:

  • Finer resolution (1°F increments vs 1°C)
  • Human comfort range (0-100°F covers most livable temps)
  • Cultural familiarity in the US
  • All infrastructure uses Fahrenheit

Convert for international weather: Fahrenheit to Celsius

Home Heating and Cooling

Standard for thermostats, HVAC systems, and climate control in American homes and buildings.

HVAC uses:

  • Thermostat settings (heat/cool)
  • Programmable temperature schedules
  • Smart home temperature control
  • Zone heating/cooling
  • Energy efficiency monitoring
  • Comfort optimization

Typical settings:

  • Winter: 68-70°F daytime, 65°F night
  • Summer: 75-78°F when home, 82-85°F when away
  • Energy saving: Adjust 7-10°F from comfort level when absent

Cooking and Food Preparation

Universal standard for oven temperatures, cooking instructions, and food safety in American kitchens.

Cooking applications:

  • Oven temperature settings
  • Recipe instructions
  • Meat thermometer readings
  • Food safety guidelines
  • Candy/deep-fry thermometers
  • Sous vide cooking

Why Fahrenheit in cooking:

  • All US recipes use °F
  • All ovens manufactured for US in °F
  • Food safety standards in °F
  • Cookbooks and packaging use °F

Medical Temperature

Standard for body temperature measurement in US healthcare and home use.

Medical uses:

  • Fever detection and monitoring
  • Patient vital signs
  • Hypothermia/hyperthermia diagnosis
  • Pediatric care (baby temperature)
  • Home health monitoring
  • Medical charts and records

Key thresholds:

  • Normal: 98.6°F (97-99°F range)
  • Fever: Above 100.4°F
  • High fever: Above 103°F
  • Hypothermia: Below 95°F

Note: US hospitals often use both Fahrenheit and Celsius for international standardization.

Swimming Pools and Spas

Standard for pool heating, hot tubs, and aquatic facilities in the US.

Pool/spa uses:

  • Pool heater settings
  • Spa/hot tub temperature
  • Chemical effectiveness (temperature-dependent)
  • Comfort optimization
  • Energy cost management

Standard temperatures:

  • Swimming pool: 78-82°F
  • Competitive swimming: 77-82°F
  • Hot tub: 100-104°F (max 104°F)
  • Therapy pool: 92-98°F

Automotive

Used for engine monitoring and climate control in US vehicles.

Automotive uses:

  • Engine temperature gauge
  • Coolant temperature warning
  • Cabin climate control
  • Outside temperature display
  • Oil temperature monitoring

Everyday Decisions

Influences daily choices in clothing, activities, and comfort throughout the US.

Daily decisions based on temperature:

  • What to wear (shorts vs jacket)
  • Indoor/outdoor activities
  • Exercise safety
  • Pet care (walk dog or not)
  • Home comfort adjustments

Use our Fahrenheit converter for everyday conversions.

When to Use degrees Rankine

1. Thermodynamic Cycle Analysis

Engineers analyzing heat engines and refrigeration cycles use Rankine when working in U.S. customary units:

Carnot efficiency calculation: η = 1 - T_cold/T_hot

Example (using Rankine for compatibility with imperial units):

  • Hot reservoir: 1160 °R (700 °F, combustion chamber)
  • Cold reservoir: 540 °R (80 °F, ambient air)
  • Maximum efficiency: η = 1 - 540/1160 = 1 - 0.465 = 53.5%

If you incorrectly used Fahrenheit (relative scale) instead: η = 1 - 80/700 = 88.6% ← Wrong! (impossibly high)

Rankine (absolute scale) gives the correct physical result.

Ideal gas law (PV = nRT): Requires absolute temperature T in Rankine or Kelvin Refrigeration coefficient of performance: COP = T_cold/(T_hot - T_cold), requires absolute T Entropy change: ΔS = Q/T, requires absolute T

2. Aerospace and Rocket Propulsion

NASA and aerospace contractors sometimes use Rankine in rocket engine calculations when working entirely in imperial units:

Rocket nozzle expansion:

  • Combustion chamber temperature: 6000 °R (5540 °F, liquid hydrogen/oxygen combustion)
  • Nozzle exit temperature: 1500 °R (1040 °F, after expansion)
  • Temperature ratio used in thrust calculations: 1500/6000 = 0.25

Specific impulse calculations: Rocket performance metrics sometimes expressed in U.S. units (pounds-force, BTU, Rankine)

Reentry heating analysis: Atmospheric friction temperatures calculated in Rankine for Space Shuttle and Apollo programs

3. Cryogenic and Liquefied Gas Engineering

Engineers working with liquefied natural gas (LNG), liquid nitrogen, or liquid oxygen may use Rankine in American industrial contexts:

LNG storage:

  • Methane boiling point: 201.1 °R (−258.6 °F, 111.7 K)
  • Storage tank insulation must maintain temperatures below 210 °R

Nitrogen liquefaction: Process temperatures from ambient (528 °R) down to liquid nitrogen (140 °R)

Oxygen separation: Cryogenic air separation units cool air from 520 °R to 163 °R (oxygen boiling point)

4. Steam Power and HVAC Engineering

Historical and some modern steam system calculations use Rankine:

Steam turbine efficiency: Calculating ideal Rankine cycle efficiency for power plants Boiler performance: Heat transfer calculations involving steam temperatures in Rankine HVAC refrigeration cycles: Coefficient of performance calculations requiring absolute temperatures

5. Combustion and Internal Combustion Engines

Engine designers analyzing combustion processes may use Rankine when working in U.S. units:

Compression ratio effects: Calculating temperature rise during compression stroke Exhaust temperatures: Modeling exhaust gas temperatures for turbocharger design Flame temperatures: Analyzing combustion chamber temperatures in Rankine for compatibility with BTU energy units

6. Materials Science and Heat Treatment

Metallurgists and materials engineers working with U.S. specifications:

Heat treatment processes: Tempering, annealing, and hardening temperatures sometimes specified in Rankine in older American standards Thermal expansion: Calculating expansion coefficients with temperature in Rankine Phase transitions: Melting and solidification temperatures in absolute scale for thermodynamic calculations

7. Historical Engineering and Technical Documentation

Engineers working with legacy systems, historical restoration, or archival research:

Old ASME standards: Early 20th century steam tables and equipment specifications used Rankine Vintage aviation: WWII and early jet age aircraft engine documentation may use Rankine Technical history: Understanding historical engineering achievements requires Rankine fluency

Additional Unit Information

About Fahrenheit (°F)

Why does the US use Fahrenheit?

The United States uses Fahrenheit due to historical adoption, infrastructure investment, and cultural resistance to change.

Historical reasons:

  • Fahrenheit scale adopted in 1700s when US was British colony
  • Became deeply embedded in American culture
  • All infrastructure built around Fahrenheit (thermostats, ovens, etc.)

Why didn't US switch to Celsius?

  • Cost: Replacing millions of thermostats, ovens, signs would cost billions
  • Cultural resistance: Americans prefer familiar system
  • Perceived complexity: Relearning temperature reference points
  • Failed metric conversion: 1970s Metric Conversion Act was voluntary and largely unsuccessful

Advantages of Fahrenheit (often cited):

  • Finer resolution (1°F = 0.56°C) for everyday temps
  • Human comfort range fits roughly 0-100°F
  • Weather forecasts use whole numbers more often

Current status:

  • US is only major country using Fahrenheit daily
  • Science and medicine use Celsius/Kelvin
  • Unlikely to change in near future

How do you convert Fahrenheit to Celsius?

Use the formula: °C = (°F - 32) × 5/9

Step-by-step:

  1. Subtract 32 from the Fahrenheit temperature
  2. Multiply the result by 5
  3. Divide by 9 (or multiply by 5/9)

Examples:

  • 68°F: (68 - 32) × 5/9 = 36 × 5/9 = 20°C
  • 86°F: (86 - 32) × 5/9 = 54 × 5/9 = 30°C
  • 32°F: (32 - 32) × 5/9 = 0°C (freezing point)
  • 212°F: (212 - 32) × 5/9 = 100°C (boiling point)
  • -40°F: (-40 - 32) × 5/9 = -40°C (same in both!)

Quick approximations:

  • Rough estimate: Subtract 30, then divide by 2
  • Example: 80°F ≈ (80-30)/2 = 25°C (actual: 26.7°C)

Use our Fahrenheit to Celsius converter for accurate conversions.

What is normal body temperature in Fahrenheit?

Normal human body temperature is 98.6°F (37°C), though the normal range is 97-99°F.

Details:

  • Average: 98.6°F (37°C) when measured orally
  • Normal range: 97-99°F (individuals vary)
  • Varies by: Time of day, activity, measurement method
  • Morning: Typically lower (97.0-97.5°F)
  • Afternoon: Typically higher (98.5-99.5°F)

Fever thresholds:

  • 99-100.4°F: Low-grade fever
  • 100.4°F and above: Fever
  • 103°F and above: High fever (call doctor)
  • Above 105°F: Medical emergency

Measurement variations:

  • Oral: 98.6°F (standard)
  • Rectal: 99.6°F (1°F higher, most accurate)
  • Armpit: 97.6°F (1°F lower, least accurate)
  • Ear: ~98.6°F (when done correctly)

At what temperature does water freeze in Fahrenheit?

Water freezes at 32°F (0°C) at standard atmospheric pressure (sea level).

Freezing point details:

  • Pure water: Exactly 32°F at sea level
  • Salt water: Lower than 32°F (28°F for ocean water)
  • Higher elevation: Slightly lower than 32°F
  • Lower elevation: Slightly higher than 32°F

Related temperatures:

  • Frost formation: 32°F or below
  • Black ice: Forms around 32°F
  • Sleet: 32-34°F (rain freezing on contact)
  • Snow: Requires below 32°F air temperature

Why 32°F?

  • Fahrenheit's original scale placed water freezing at 32° based on his reference points
  • Not as intuitive as 0°C, but historically established

At what temperature does water boil in Fahrenheit?

Water boils at 212°F (100°C) at standard atmospheric pressure (sea level).

Boiling point details:

  • Sea level: 212°F exactly
  • Higher elevation: Lower than 212°F (198°F in Denver, CO)
  • Lower elevation: Higher than 212°F
  • Pressure cooker: Above 212°F (250°F at high pressure)

Elevation effects:

  • For every 500 feet above sea level, boiling point drops ~1°F
  • Denver (5,280 ft): Water boils at ~202°F
  • Mount Everest (29,000 ft): Water boils at ~160°F

Cooking implications:

  • High altitude: Longer cooking times needed
  • Pressure cookers: Faster cooking due to higher temp

Why 212°F?

  • Another fixed point on Fahrenheit's original scale
  • 180 degrees between freezing (32°F) and boiling (212°F)

What temperature is considered a fever?

A temperature of 100.4°F (38°C) or higher is generally considered a fever in adults.

Fever categories:

  • Normal: 97-99°F
  • Low-grade fever: 99-100.4°F
  • Mild fever: 100.4-102°F
  • Moderate fever: 102-103°F
  • High fever: 103-104°F
  • Very high fever: Above 104°F (seek medical care)

In children/infants:

  • Newborn (0-3 months): 100.4°F or higher (call doctor immediately)
  • Infant (3-36 months): 102°F or higher (call doctor)
  • Child: 103°F or higher (call doctor)

When to seek medical attention:

  • Adult fever above 103°F
  • Fever lasting more than 3 days
  • Infant under 3 months with any fever
  • Fever with severe symptoms (confusion, difficulty breathing)

Measurement note: Rectal temperatures are ~1°F higher, armpit ~1°F lower than oral.

Is -40°F the same as -40°C?

Yes! -40°F = -40°C exactly. This is the only temperature where both scales intersect.

Why this happens:

  • The conversion formula: °C = (°F - 32) × 5/9
  • At -40: (-40 - 32) × 5/9 = -72 × 5/9 = -40°C
  • Mathematically, this is the unique intersection point

Other relationships:

  • Below -40: Fahrenheit numbers are smaller than Celsius (e.g., -50°F = -45.6°C)
  • Above -40: Fahrenheit numbers are larger (e.g., 0°F = -17.8°C)

Practical context:

  • 40° is extremely cold (Arctic/Antarctic conditions)
  • Dangerous to humans without proper protection
  • Few places on Earth regularly reach this temperature

Fun fact: This is the most commonly cited "trivia" about temperature scales!

What is a comfortable room temperature in Fahrenheit?

68-72°F (20-22°C) is generally considered comfortable room temperature for most people.

Comfort ranges by activity:

  • Sleeping: 60-67°F (cooler is better)
  • Living areas: 68-72°F
  • Working: 68-76°F
  • Exercising indoors: 65-68°F

Factors affecting comfort:

  • Humidity: Lower humidity feels warmer
  • Air movement: Fans make it feel cooler
  • Clothing: Dress code affects ideal temp
  • Personal preference: Varies significantly
  • Age: Elderly prefer warmer (72-78°F)

Energy recommendations:

  • Department of Energy: 78°F summer, 68°F winter
  • OSHA workplace: 68-76°F
  • Energy saving: Adjust 7-10°F when away or sleeping

International differences:

  • US comfort: 68-72°F average
  • Europe comfort: 68-73°F (20-23°C)
  • Tropical regions: 75-80°F normal

How do you convert Celsius to Fahrenheit?

Use the formula: °F = (°C × 9/5) + 32

Step-by-step:

  1. Multiply the Celsius temperature by 9
  2. Divide by 5 (or multiply by 9/5 = 1.8)
  3. Add 32

Examples:

  • 20°C: (20 × 9/5) + 32 = 36 + 32 = 68°F
  • 30°C: (30 × 9/5) + 32 = 54 + 32 = 86°F
  • 0°C: (0 × 9/5) + 32 = 32°F (freezing point)
  • 100°C: (100 × 9/5) + 32 = 212°F (boiling point)
  • -40°C: (-40 × 9/5) + 32 = -40°F (same in both!)

Quick approximations:

  • Double the Celsius temp and add 30
  • Example: 20°C ≈ (20×2)+30 = 70°F (actual: 68°F)

Use our Celsius to Fahrenheit converter for accurate conversions.

What countries use Fahrenheit?

Very few countries use Fahrenheit today. The United States is the primary user.

Current Fahrenheit users:

  • United States (primary user for daily temperatures)
  • Bahamas (some usage)
  • Belize (some usage)
  • Cayman Islands
  • Palau
  • Federated States of Micronesia
  • Marshall Islands

US territories using Fahrenheit:

  • Puerto Rico
  • US Virgin Islands
  • Guam
  • American Samoa

Former users (switched to Celsius):

  • United Kingdom: Switched 1960s-1970s
  • Canada: Switched 1970s
  • Australia: Switched 1970s
  • New Zealand: Switched 1970s
  • South Africa: Switched 1960s-1970s

Rest of world: Uses Celsius exclusively (195+ countries)

In science/medicine: Even US uses Celsius and Kelvin for scientific work.

What is the difference between Fahrenheit and Celsius?

Fahrenheit and Celsius are different temperature scales with different zero points and degree sizes.

Key differences:

| Feature | Fahrenheit | Celsius | |---------|-----------|---------| | Freezing point of water | 32°F | 0°C | | Boiling point of water | 212°F | 100°C | | Degrees between | 180° | 100° | | Absolute zero | -459.67°F | -273.15°C | | Degree size | Smaller (1°F = 0.56°C) | Larger (1°C = 1.8°F) | | Primary users | USA, few others | Rest of world (195+ countries) |

Conversion:

  • °C = (°F - 32) × 5/9
  • °F = (°C × 9/5) + 32

Intersection point: -40°F = -40°C (only place scales match)

Practical differences:

  • Celsius is simpler (0° freeze, 100° boil)
  • Fahrenheit provides finer resolution
  • Celsius aligned with metric system
  • Fahrenheit embedded in US culture

Convert between them: F to C | C to F

About Rankine (°R)

What is absolute zero on the Rankine scale?

Answer: 0 °R (exactly)

Absolute zero is the lowest possible temperature, where all classical molecular motion ceases and a system has minimal quantum mechanical zero-point energy. On the Rankine scale, this is defined as exactly 0 °R.

Absolute zero in other scales:

  • Rankine: 0 °R (by definition)
  • Fahrenheit: −459.67 °F
  • Kelvin: 0 K (by definition)
  • Celsius: −273.15 °C

The Rankine scale, like Kelvin, is an absolute scale, meaning its zero point represents true zero thermal energy (in the classical thermodynamic sense), not an arbitrary freezing point like Celsius or Fahrenheit.

How does Rankine relate to Fahrenheit?

Answer: °R = °F + 459.67 (Rankine is Fahrenheit shifted to start at absolute zero)

The Rankine and Fahrenheit scales use identical degree sizes—a change of 1 °R equals a change of 1 °F. The only difference is where zero is placed:

  • Fahrenheit: 0 °F is the freezing point of a brine solution (arbitrary choice from 1724)
  • Rankine: 0 °R is absolute zero, the lowest possible temperature

Key reference points:

  • Absolute zero: −459.67 °F = 0 °R
  • Water freezes: 32 °F = 491.67 °R
  • Water boils: 212 °F = 671.67 °R
  • Room temperature: 68 °F = 527.67 °R

Temperature changes: Because degree sizes are equal, a temperature rise of 50 °F is also a rise of 50 °R.

How does Rankine relate to Kelvin?

Answer: °R = K × 9/5 (or K = °R × 5/9)

Rankine and Kelvin are both absolute scales (zero at absolute zero), but they use different degree sizes:

  • Kelvin: Uses Celsius-sized degrees
  • Rankine: Uses Fahrenheit-sized degrees (which are 9/5 the size of Celsius degrees)

Conversion formula: °R = K × 9/5 (or K × 1.8)

Examples:

  • 0 K = 0 °R (absolute zero aligns)
  • 273.15 K (water freezes) = 491.67 °R
  • 373.15 K (water boils) = 671.67 °R
  • 300 K (room temp) = 540 °R

No offset needed: Unlike Fahrenheit-Celsius (which requires both multiplication AND addition), Rankine-Kelvin only requires multiplication because both start at absolute zero.

Why was the Rankine scale created?

Answer: To provide an absolute temperature scale compatible with Fahrenheit for British and American engineers

William Rankine created the scale in 1859 to solve a practical problem:

The problem:

  • Thermodynamic calculations (heat engines, gas laws, entropy) require absolute temperatures
  • Lord Kelvin had created an absolute scale in 1848, but it used Celsius degree intervals
  • British and American engineers worked in Fahrenheit, not Celsius
  • Constantly converting Fahrenheit → Celsius → Kelvin was error-prone and inefficient

Rankine's solution:

  • Create an absolute scale (zero at absolute zero) using Fahrenheit-sized degrees
  • Result: Engineers could use familiar Fahrenheit measurements with the benefits of an absolute scale

Historical context: In the 19th and early 20th centuries, this was essential for steam engine design, refrigeration engineering, and thermodynamic analysis in imperial-unit countries.

Is the Rankine scale still used today?

Answer: Rarely—primarily in specialized American engineering contexts and legacy documentation

Rankine has largely been replaced by Kelvin in modern engineering and science, but persists in specific niches:

Where Rankine is still used:

  • American aerospace engineering: Some NASA and contractor calculations when working in U.S. customary units
  • Cryogenic engineering: U.S. liquefied gas industries (LNG, liquid nitrogen/oxygen)
  • Legacy documentation: Older ASME standards, vintage equipment manuals, historical references
  • Thermodynamics education: Some U.S. engineering courses teach both Rankine and Kelvin

Why it declined:

  • Global metrication (1960s onward) made Kelvin the international standard
  • Scientific community exclusively uses Kelvin
  • Modern engineering software typically works in SI units
  • International collaboration requires Kelvin for compatibility

Current status: Rankine is a "legacy unit" maintained primarily for continuity with older American engineering systems, not for new designs.

What are the key temperatures on the Rankine scale?

Answer: Important reference temperatures in Rankine:

| Physical Point | Rankine | Fahrenheit | Description | |----------------|---------|------------|-------------| | Absolute zero | 0 °R | −459.67 °F | Theoretical minimum temperature | | Liquid helium boils | 7.6 °R | −451.9 °F | Coldest commonly used cryogenic liquid | | Liquid nitrogen boils | 139.3 °R | −320.4 °F | Common cryogenic refrigerant | | Dry ice sublimes | 389.0 °R | −109.3 °F | Solid CO₂ turns directly to gas | | Water freezes | 491.67 °R | 32 °F | Ice point at standard pressure (exact) | | Room temperature | 527.67 °R | 68 °F | Typical comfortable indoor temp | | Human body | 558.27 °R | 98.6 °F | Normal body temperature | | Water boils | 671.67 °R | 212 °F | Boiling point at standard pressure (exact) |

Exact values: Water's freezing and boiling points are defined exactly in Fahrenheit (32 °F and 212 °F), so they're also exact in Rankine (491.67 °R and 671.67 °R).

How do I convert Rankine to Celsius?

Answer: °C = (°R × 5/9) − 273.15

Step-by-step process:

  1. Convert Rankine to Kelvin: K = °R × 5/9
  2. Convert Kelvin to Celsius: °C = K − 273.15

Combined formula: °C = (°R × 5/9) − 273.15

Examples:

  • 491.67 °R (water freezes) = (491.67 × 5/9) − 273.15 = 273.15 − 273.15 = 0 °C
  • 671.67 °R (water boils) = (671.67 × 5/9) − 273.15 = 373.15 − 273.15 = 100 °C
  • 527.67 °R (room temp) = (527.67 × 5/9) − 273.15 = 293.15 − 273.15 = 20 °C

Alternative method: First convert to Fahrenheit, then to Celsius:

  1. °F = °R − 459.67
  2. °C = (°F − 32) × 5/9

Both methods give the same result.

Can I use negative numbers in Rankine?

Answer: No—negative temperatures don't exist on the Rankine scale (or Kelvin)

Because Rankine is an absolute scale starting at absolute zero (0 °R), there are no temperatures below zero. Negative Rankine temperatures would represent temperatures colder than absolute zero, which is physically impossible according to thermodynamics.

Comparison to other scales:

  • Rankine/Kelvin (absolute): Only positive values (0 and up)
  • Fahrenheit/Celsius (relative): Can have negative values (arbitrary zero points)

Lowest possible temperature: 0 °R (absolute zero) = −459.67 °F = −273.15 °C = 0 K

Note on exotic physics: In specialized quantum systems, "negative absolute temperatures" can exist in a technical sense (inverted population distributions), but this is a quantum statistical mechanics concept unrelated to everyday thermodynamics, and still doesn''t produce Rankine values below zero in the conventional thermal sense.

What''s the difference between °R and °Ra symbols?

Answer: Both °R and °Ra represent Rankine; °R is more common in American usage

Symbol variations:

  • °R: Most common symbol in American engineering contexts
  • °Ra: Sometimes used to avoid confusion with other units (electrical resistance in ohms: Ω or R)
  • R (without degree symbol): Occasionally seen in older texts but discouraged

Current standard: Most modern references use °R (with degree symbol), matching the pattern of °F, °C, and K (though Kelvin dropped its degree symbol in 1968).

Avoiding confusion:

  • Electrical resistance: ohm (Ω), not R
  • Gas constant: R (universal gas constant, context makes it clear)
  • Rankine temperature: °R or °Ra (degree symbol helps distinguish)

Recommendation: Use °R for Rankine temperatures in modern technical writing.

Why doesn''t Kelvin use a degree symbol but Rankine does?

Answer: In 1968, the kelvin was redefined as a base SI unit, dropping the degree symbol; Rankine wasn''t part of SI and retained its symbol

Historical evolution:

Before 1968: Both scales used degree symbols

  • Kelvin: °K (degrees Kelvin)
  • Rankine: °R or °Ra (degrees Rankine)

After 1968: The 13th General Conference on Weights and Measures (CGPM) redefined the kelvin as a base SI unit (like meter, kilogram, second), removing the degree symbol:

  • Kelvin: K (kelvin, no degree symbol)
  • Rankine: °R (still degrees Rankine, not an SI unit)

Reasoning: Celsius (°C) retained its degree symbol because it's defined relative to kelvin (°C = K − 273.15). But kelvin itself, as a fundamental unit, doesn't use degrees—you say "300 kelvin" not "300 degrees kelvin."

Rankine status: Since Rankine isn't part of the International System of Units (SI), it never underwent this redefinition and still uses the degree symbol: °R.

Is Rankine more accurate than Fahrenheit for engineering?

Answer: Neither is more "accurate"—Rankine is better for thermodynamic calculations because it''s an absolute scale

Accuracy vs. suitability:

  • Both Rankine and Fahrenheit can be measured to arbitrary precision (accuracy)
  • The difference is mathematical correctness for thermodynamic equations

Why Rankine is better for thermodynamics:

  • Equations like PV = nRT, η = 1 - T_cold/T_hot, and ΔS = Q/T require absolute temperature
  • Using Fahrenheit (or Celsius) produces physically meaningless results (negative efficiency, division by zero, etc.)
  • Using Rankine (or Kelvin) produces correct physical results

Example (ideal gas law: PV = nRT):

  • At 0 °F (459.67 °R), pressure P is proportional to 459.67
  • If you incorrectly used 0 °F in the equation, you'd get P = 0 (no pressure), which is wrong!
  • Using 459.67 °R gives the correct pressure

Conclusion: For everyday temperature measurement, Fahrenheit is fine. For thermodynamic calculations, you must use Rankine (or Kelvin).

Will Rankine ever become obsolete?

Answer: Likely yes—it''s already obsolete in most contexts and will fade as U.S. engineering fully metrifies

Current trajectory:

  • 1960s-1990s: Rapid decline as global metrication occurred
  • 2000s-present: Niche survival in specific American engineering contexts
  • Future: Continued decline as remaining U.S. industries standardize on SI units (Kelvin)

Factors driving obsolescence:

  • International collaboration: Global engineering requires common units (Kelvin)
  • Software standardization: Modern CAD/simulation tools default to SI units
  • Educational shift: Engineering schools increasingly teach only Kelvin
  • Generational change: Engineers trained primarily in Rankine are retiring

Where it might persist longest:

  • Historical preservation (understanding old documents)
  • Legacy systems (maintaining equipment with Rankine specifications)
  • Specialized American aerospace/cryogenics (slow to change due to established procedures)

Likely outcome: Rankine will become a "historical unit" known primarily to engineering historians, similar to how the "degree Réaumur" (°Ré) is now obsolete despite 18th-19th century prominence.

People Also Ask

How do I convert Fahrenheit to Rankine?

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What is the conversion factor from Fahrenheit to Rankine?

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Can I convert Rankine back to Fahrenheit?

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What are common uses for Fahrenheit and Rankine?

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Celsius to FahrenheitCelsius to KelvinCelsius to RankineCelsius to RéaumurCelsius to RømerCelsius to NewtonCelsius to DelisleFahrenheit to CelsiusFahrenheit to KelvinFahrenheit to RéaumurFahrenheit to RømerFahrenheit to NewtonFahrenheit to DelisleKelvin to CelsiusKelvin to FahrenheitKelvin to RankineKelvin to RéaumurKelvin to RømerKelvin to NewtonKelvin to DelisleRankine to CelsiusRankine to FahrenheitRankine to KelvinRankine to RéaumurRankine to RømerRankine to NewtonRankine to DelisleRéaumur to CelsiusRéaumur to FahrenheitRéaumur to KelvinRéaumur to RankineRéaumur to RømerRéaumur to NewtonRéaumur to DelisleRømer to CelsiusRømer to FahrenheitRømer to KelvinRømer to RankineRømer to RéaumurRømer to NewtonRømer to DelisleNewton to CelsiusNewton to FahrenheitNewton to KelvinNewton to RankineNewton to RéaumurNewton to RømerNewton to DelisleDelisle to CelsiusDelisle to FahrenheitDelisle to KelvinDelisle to RankineDelisle to RéaumurDelisle to RømerDelisle to Newton

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Last verified: February 19, 2026