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Cryogenics
Understanding the Concept of Cryogenics
What Cryogenics
Is and How It's Used
by Anne Marie
Helmenstine, Ph.D.
Cryogenics is defined as the scientific study of materials
and their behavior at extremely low temperatures.
The word comes from the Greek cryo, which means "cold", and genic, which means "producing".
The term is usually encountered in the context of physics,
materials science, and medicine.
A scientists who studies cryogenics is called a cryogenicist.
A cryogenic material may be termed a cryogen.
Although cold temperatures may be reported using any temperature
scale, the Kelvin and Rankine scales are most common because
they are absolute scales that have positive numbers.
Exactly how cold a substance has to be to be considered
"cryogenic" is a matter of some debate by the scientific community.
The U.S. National Institute of Standards and Technology
(NIST) considers cryogenics to include temperatures below −180 °C (93.15
K; −292.00 °F), which is a temperature above which common refrigerants (e.g.,
hydrogen sulfide, freon) are gases and below which "permanent gases"
(e.g., air, nitrogen, oxygen, neon, hydrogen, helium) are liquids.
There is also a field of study called "high
temperature cryogenics", which involves temperatures above the boiling
point of liquid nitrogen at ordinary pressure (−195.79 °C
(77.36 K; −320.42 °F), up to −50 °C (223.15 K; −58.00 °F).
Measuring the temperature of cryogens requires special
sensors.
Resistance temperature detectors (RTDs) are used to take
temperature measurements as low as 30 K. Below 30 K, silicon diodes are often
used.
Cryogenic particle detectors are sensors that operate a few
degrees above absolute zero and are used to detect photons and
elementary particles.
Cryogenic liquids are typically stored in devices called
Dewar flasks. These are double-walled containers that have a vacuum between the
walls for insulation.
Dewar flasks intended for use with extremely cold liquids
(e.g., liquid helium) have an additional insulating container filled with
liquid nitrogen.
Dewar flasks are named for their inventor, James Dewar.
The flasks allow gas to escape the container to prevent
pressure buildup from boiling that could lead to an explosion.
Cryogenic Fluids
The following fluids are most often used in cryogenics:
Fluid
|
Boiling
Point (K)
|
Helium-3
|
3.19
|
Helium-4
|
4.214
|
Hydrogen
|
20.27
|
Neon
|
27.09
|
Nitrogen
|
77.36
|
Air
|
78.8
|
Fluorine
|
85.24
|
Argon
|
87.24
|
Oxygen
|
90.18
|
Methane
|
111.7
|
Uses of Cryogenics
There are several applications of cryogenics. It is used to
produce cryogenic fuels for rockets, including liquid hydrogen and liquid
oxygen (LOX).
The strong electromagnetic fields needed for nuclear
magnetic resonance (NMR) are usually produced by supercooling electromagnets
with cryogens.
Magnetic resonance imaging (MRI) is an application of NMR
that uses liquid helium.
Infrared cameras frequently require cryogenic cooling.
Cryogenic freezing of food is used to transport or store
large quantities of food.
Liquid nitrogen is used to produce fog for special
effects and even specialty cocktails and food.
Freezing materials using cryogens can make them brittle
enough to be broken into small pieces for recycling.
Cryogenic temperatures are used to store tissue and blood
specimens and to preserve experimental samples.
Cryogenic cooling of superconductors may be used
to increase electric power transmission for big cities.
Cryogenic processing is used as part of some alloy
treatments and to facilitate low temperature chemical reactions (e.g., to make
statin drugs).
Cryomilling is used to mill materials that may be too soft
or elastic to be milled at ordinary temperatures.
Cooling of molecules (down to hundreds of nano Kelvins) may
be used to form exotic states of matter. The Cold Atom Laboratory (CAL) is an
instrument designed for use in microgravity to form Bose Einstein condensates
(around 1 pico Kelvin temperature) and test laws of quantum mechanics and other
physics principles.
Cryogenic Disciplines
Cryogenics is a broad field that encompasses several
disciplines, including:
Cryonics -
Cryonics is the cryopreservation of animals and humans with the goal of
reviving them in the future.
Cryosurgery - This
is a branch of surgery in which cryogenic temperatures are used to kill
unwanted or malignant tissues, such as cancer cells or moles.
Cryoelectronics - This is
the study of superconductivity, variable-range hopping, and other electronic
phenomena at low temperature. The practical application of cryoelectronics is
called cryotronics.
Cryobiology - This
is the study of the effects of low temperatures on organisms, including the
preservation of organisms, tissue, and genetic material using cryopreservation.
Cryogenics Fun Fact
While cryogenics usually involves temperature below the
freezing point of liquid nitrogen yet above that of absolute zero, researchers
have achieved temperatures below absolute zero (so-called negative Kelvin
temperatures).
In 2013 Ulrich Schneider at the University of Munich
(Germany) cooled gas below absolute zero, which reportedly made it hotter
instead of colder!
Anne
Marie Helmenstine, Ph.D.
Introduction
Ph.D.
in biomedical sciences from the University of Tennessee at Knoxville - Oak
Ridge National Laboratory.
Science
educator with experience teaching chemistry, biology, astronomy, and
physics at the high school, college, and graduate levels.
ThoughtCo
and About Education chemistry expert since 2001.
Widely-published
graphic artist, responsible for printable periodic tables and other
illustrations used in science.
Experience
Anne
Helmenstine, Ph.D. has covered chemistry for ThoughtCo and About Education
since 2001, and other sciences since 2013. She taught chemistry, biology,
astronomy, and physics at the high school, college, and graduate levels.
She has worked as a research scientist and also abstracting and indexing
diverse scientific literature for the Department of Energy.
In
addition to her work as a science writer, Dr. Helmenstine currently serves as a
scientific consultant, specializing in problems requiring an interdisciplinary
approach. Previously, she worked as a research scientist and college
professor.
Education
Dr.
Helmenstine holds a Ph.D. in biomedical sciences from the University of
Tennessee at Knoxville and a B.A. in physics and mathematics with a minor
in chemistry from Hastings College. In her doctoral work, Dr. Helmenstine
developed ultra-sensitive chemical detection and medical diagnostic tests.
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