• Liquid Helium Tank
• List Of Cryogenic Liquids
• Liquid Helium Density
• Helium Cryogenic Temperature

Cryogenic storage vessels range from general purpose open dewars, to multi-coded liquid nitrogen, argon, oxygen & helium vessels, intermodal ISO tank containers and road tankers. Spares and accessories range from replacement valves to full automatic liquid level control equipment. Cryogenics Closed cycle helium cryogenic systems serve a number of purposes within modern industry, but the primary applications are in temperature control and vacuum. Cryogenic coldheads are used in a number of cooling applications involving electronics and superconducting magnets. CTI-CRYOGENICS 8300 Compressor NP 8052000 + 8001 Controller NP 8052001 $ 2500.00 Brand: CTI-CRYOGENICS 8300 Helium Compressor NP 8052000 + CTI-CRYOGENICS. More 8001 Controller NP 8052001 Price: $ 2500.00-Shipping costs will vary depending on location. If you have any questions please call 713-644-4011. Everything is sold as-is. Additionally, AET’s cryogenic adsorbtion helium gas purifiers can be utilized in full recovery systems to recycle processed helium that has been collected from system vents. For more information on how our cryogenic purifiers work, please see our main cryogenic purifier unit page.

Since 1984, Wessington Cryogenics have established themselves as a leading cryogenic vessel manufacturer with an ever growing reputation for Quality and Reliability.

Indeed this has been formally recognised by the granting of ISO 9001 and ASME U & R Stamp approval, and build vessels to PED & TPED among many other pressure vessel code requirements.

Cryogenic storage vessels range from general purpose open dewars, to multi-coded liquid nitrogen, argon, oxygen & helium vessels, intermodal ISO tank containers and road tankers. Spares and accessories range from replacement valves to full automatic liquid level control equipment. We at Wessington pride ourselves in our ability to meet the customers special requirements for cryogenic equipment. We are able to manufacture a host of 'specials' for specific applications where a standard product does not exist. These vessels can be for 'one-off' projects or the development of a new concept for a potentially new market. Custom designed cryostats, liquid nitrogen vessels, cryogenic valve boxes and phase separators also available.

Our repair and refurbishment facilities allow us to repair virtually all makes of liquid nitrogen, argon, oxygen or helium cryogenic vessels, returning them to an 'As New' condition. We are also able to examine and recertify vessels in accordance with the Pressure Systems Safety Regulations (PSSR). We are also able to offer various training courses to suit a variety of end applications and needs. The workshops presented are designed to focus the delegates attention via practical and interactive sessions to the importance of adopting safe working practices in line with Codes of Practice, Guidance Notes, and Legislation.

Should you find anything on the Wessington Home Pages which interest you, or indeed require something which you feel we may be able to offer, please do not hesitate to contact us

In the field of cryogenics, helium [He] is utilized for a variety of reasons. The combination of helium’s extremely low molecular weight and weak interatomic reactions yield interesting properties when helium is cooled below its critical temperature of 5.2 K to form a liquid. Even at absolute zero (0K), helium does not condense to form a solid under ambient pressure. In this state, the zero point vibrational energies of helium are comparable to very weak interatomic binding interactions, thus preventing lattice formation and giving helium its fluid characteristics.^[1] Within this liquid state, helium has two phases referred to as helium I and helium II. Helium I displays thermodynamic and hydrodynamic properties of classical fluids, along with quantum characteristics. However, below its lambda point of 2.17 K, helium transitions to He II and becomes a quantum superfluid with zero viscosity.^[2]

Under extreme conditions such as when cooled beyond T_λ, helium has the ability to form a new state of matter, known as a Bose–Einstein condensate (BEC), in which the atoms virtually lose all their energy. Without energy to transfer between molecules, the atoms begin to aggregate creating a volume of equivalent density and energy.^[3] From observations, liquid helium only exhibits super-fluidity because it contains isolated islands of BECs, which have well-defined magnitude and phase, as well as well-defined phonon–roton (P-R) modes.^[4] A phonon refers to a quantum of energy associated with a compressional wave such as the vibration of a crystal lattice while a roton refers to an elementary excitation in superfluid helium. In the BEC’s, the P-R modes have the same energy, which explains the zero point vibrational energies of helium in preventing lattice formation.^[5]

When helium is below T_λ, the surface of the liquid becomes smoother, indicating the transition from liquid to superfluid.^[6] Experiments involving neutron bombardment correlate with the existence of BEC’s, thereby confirming the source of liquid helium’s unique properties such as super-fluidity and heat transfer.^[6][7]

Liquid Helium Tank

Though seemingly paradoxical, cryogenic helium systems can move heat from a volume of relatively low temperature to a volume of relatively high temperature.^[8] Though this phenomenon appears to violate the second law of thermodynamics, experiments have shown this to prevail in systems where the volume of low temperature is constantly heated, and the volume of high temperature is constantly cooled. It is believed this phenomenon is related to the heat associated with the phase change between liquid and gaseous helium.^[8]

Applications[edit]

Superconductors[edit]

Liquid helium is used as a coolant for various superconducting applications. Notable are particle accelerators where magnets are used for steering charged particles. If large magnetic fields are required then superconducting magnets are used. In order for superconductors to be efficient, they must be kept below their respective critical temperature. This requires very efficient heat transfer. Because of the reasons discussed previously, superfluid helium can be used to effectively transfer heat away from superconductors.^[9]

Quantum computing[edit]

One proposed use for superfluid helium is in quantum computing. Quantum computers utilize the quantum states of matter, such as the electron spin, as individual quantum bits (qubits), a quantum analogue of the bit used in traditional computers to store information and perform processing tasks. The spin states of the electrons present on the surface of superfluid helium in a vacuum show promise as excellent qubits. In order to be considered a usable qubit, a closed system of individual quantum objects must be created that interact with each other, but whose interaction with the outside world is minimal. In addition, the quantum objects must be able to be manipulated by the computer, and the quantum system’s properties must be readable by the computer to signal the termination of a computational function.^[10] It is believed that in vacuum, superfluid helium satisfies many of these criteria since a closed system of its electrons can be read and easily manipulated by the computer in a similar fashion as electrostatically manipulated electrons in semiconductor heterostructures. Another beneficial aspect of the liquid helium quantum system is that application of an electrical potential to liquid helium in a vacuum can move qubits with little decoherence. In other words, voltage can manipulate qubits with little effect on the ordering of the phase angles in the wave functions between the components of the liquid helium quantum system.^[11]

X-ray crystallography[edit]

List Of Cryogenic Liquids

The advent of high-flux X-rays provides a useful tool for developing high-resolution structures of proteins. However, higher energy crystallography incurs radiation damage to the proteins studied. Cryogenic helium systems can be used with greater efficacy than nitrogen cryogenic systems to prevent radical damage to protein crystals.^[12]

See also[edit]

Liquid Helium Density

References[edit]

1. ^Yang, Shengfu, and Andrew M. Ellis. 'Helium Droplets: A Chemistry Perspective.' Chemical Society Reviews 42.2 (2012): 472-84. Print.
2. ^Woods, A. D B, and R. A. Cowley. 'Structure and Excitations of Liquid Helium.' Reports on Progress in Physics 36.9 (1973): 1135-231. Print.
3. ^Penrose, Oliver, and Lars Onsager. 'Bose–Einstein Condensation and Liquid Helium.' Physical Review 104.3 (1956): 576-84. Print.
4. ^Haussmann, R. 'Properties of a Fermi Liquid at the Superfluid Transition in the Crossover Region between BCS Superconductivity and Bose–Einstein Condensation.' Physical Review B 49.18 (1994): 12975-2983. Print.
5. ^Bossy, Jacques, Jonathan Pearce, Helmut Schober, and Henry Glyde. 'Phonon–Roton Modes and Localized Bose–Einstein Condensation in Liquid Helium under Pressure in Nanoporous Media.' Physical Review Letters 101.2 (2008): n. pag. Print.
6. ^ ^abCharlton, T. R., R. M. Dalgliesh, O. Kirichek, S. Langridge, A. Ganshin, and P. V. E. Mcclintock. 'Neutron Reflection from a Liquid Helium Surface.' Low Temperature Physics 34.4 (2008): 316-19. Print.
7. ^Tsipenyuk, Yu. M., O. Kirichek, and O. Petrenko. 'Small-angle Scattering of Neutrons on Normal and Superfluid Liquid Helium.' Low Temperature Physics 39.9 (2013): 777. Print.
8. ^ ^abPavel Urban; David Schmoranzer; Pavel Hanzelka; Katepalli R. Sreenivasan & Ladislav Skrbek (2013). 'Anomalous heat transport and condensation in convection of cryogenic helium'. Proceedings of the National Academy of Sciences. 110 (20): 8036–8039. Bibcode:2013PNAS..110.8036U. doi:10.1073/pnas.1303996110. PMC3657834. PMID23576759.
9. ^Pier Paolo Granieri “Heat Transfer between the Superconducting Cables of the LHC Accelerator Magnets and the Superfluid Helium Bath” Swiss Federal Institute of Technology in Lausanne Thesis No. 5411 (2012): 1–2 August 29, 2012 http://infoscience.epfl.ch/record/180620/files/EPFL_TH5411.pdf
10. ^Dykman, M. I., P. M. Platzman. “Quantum Computing with Electrons Floating on Liquid Helium.” Science 284 (1999): 1967-69. Print.
11. ^Lyon, S. A. “Spin-based quantum computing using electrons on liquid helium.” Physical Review A 74.5 (2006): 52338-2344. Print.
12. ^Cryogenic (<20 K) helium cooling mitigates radiation damage to protein crystals” Acta Crystallographica Section D. 2007 63 (4) 486-492

Helium Cryogenic Temperature