Dynomak is a

spheromak A spheromak is an arrangement of plasma formed into a toroidal shape similar to a smoke ring. The spheromak contains large internal electric currents and their associated magnetic fields arranged so the magnetohydrodynamic forces within the s ...

fusion reactor Fusion power is a proposed form of power generation that would generate electricity by using heat from nuclear fusion reactions. In a fusion process, two lighter atomic nuclei combine to form a heavier nucleus, while releasing energy. Devices ...

concept developed by the

University of Washington The University of Washington (UW, simply Washington, or informally U-Dub) is a public research university in Seattle, Washington. Founded in 1861, Washington is one of the oldest universities on the West Coast; it was established in Seattl ...

using U.S. Department of Energy funding.Michelle Ma
"UW fusion reactor concept could be cheaper than coal"
''

'', October 8, 2014Evan Ackerman
"Inside the Dynomak"
''

IEEE Spectrum ''IEEE Spectrum'' is a magazine edited by the Institute of Electrical and Electronics Engineers. The first issue of ''IEEE Spectrum'' was published in January 1964 as a successor to ''Electrical Engineering''. The magazine contains peer-reviewe ...

'', November 26, 2014 A dynomak is defined as a

that is started and maintained by magnetic flux injection. The dynomak is formed when an alternating current is used to induce a magnetic flux into plasma. A transformer uses the same induction process to create a secondary current. Once formed, the plasma inside the Dynomak relaxes into its lowest energy state, while conserving overall flux.Taylor, J. Brian. "Relaxation of toroidal plasma and generation of reverse magnetic fields." Physical Review Letters 33.19 (1974): 1139. This is known as a Taylor state and inside the machine what is formed is a plasma structure called a

. The Dynomak is a kind of

Spheromak A spheromak is an arrangement of plasma formed into a toroidal shape similar to a smoke ring. The spheromak contains large internal electric currents and their associated magnetic fields arranged so the magnetohydrodynamic forces within the s ...

that is started and driven by externally induced magnetic fields.

Technical Roots

Plasma is a fluid that conducts electricity, which gives it the unique property that it can be self-structured into smoke-ring-like objects such as

Field-reversed configuration A field-reversed configuration (FRC) is a type of plasma device studied as a means of producing nuclear fusion. It confines a plasma on closed magnetic field lines without a central penetration. In an FRC, the plasma has the form of a self-stabl ...

s and

s. A structured plasma has the advantage that it is hotter, denser and more controllable which makes it a good choice for a fusion reactor. But forming these plasma structures has been challenging since the first structures were observed in 1959 because they are inherently unstable. In 1974, Dr. John B Taylor proposed that a spheromak could be formed by inducing a magnetic flux into a loop plasma. The plasma would then relax naturally into a

also known as a Taylor State. This process worked if the plasma: * Conserved the total magnetic flux * Minimized the total energy These claims were later checked by Marshall Rosenbluth in 1979. In 1974, Dr. Taylor could only use results from the ZETA pinch device to back up these claims. But, since then, Taylor states have been formed in multiple machines including: * Compact Torus Experiment (CTX) at Los Alamos. The CTX operated from ~1979 to ~1987 at Los Alamos. It reached electron temperatures of 4.6 million kelvin ran for 3 microseconds and had a plasma to magnetic pressure ratio of 0.2. * Sustained Spheromak Physics Experiment (SSPX) at Livermore was a more advanced version of the CTX that was used to measure the relaxation process that led to a Taylor state. The SSPX was working at Livermore from 1999 until 2007. * Caltech Spheromak Experiment at Caltech was a small experiment run by Dr. Paul Bellans’ lab at Caltech from ~2000 to ~2010. * Helicity Injected Torus-Steady Inductive (HIT-SI) at the University of Washington was run by Dr. Jarboe from 2004 to 2012 and was the precursor to the Dynomak. This machine created 90 kiloamps of stable plasma current over several (<2) microseconds. This machine also showed the first demonstration of Imposed-Dynamo Current Drive (IDCD) in 2011. The IDCD breakthrough enabled Dr. Jarboes’ group to envision the first reactor-scale version of this machine; called the Dynomak. The Dynomak evolved from the Helicity Injected Torus-Steady Inductive (HIT-SI) (~2004 to ~2012) experiment that was operated by the University of Washington. The HIT-SI machine went through several upgrades, the HIT-SI3 (~2013 to ~2020) and HIT-SIU (Post ~2020) were both variations on the same machine. These machines demonstrated that an inductive current could be used to make and sustain the Spheromak plasma structure.

Magnetic Induction Drive

By definition, a Dynomak is a plasma structure that is started, formed, and sustained using magnetic flux injection.

Transformer A transformer is a passive component that transfers electrical energy from one electrical circuit to another circuit, or multiple circuits. A varying current in any coil of the transformer produces a varying magnetic flux in the transformer' ...

s use a similar process; a magnetic flux is created on the primary loop, and this makes an alternating current on the secondary side. Because of Faraday's law of induction, only a ''changing'' magnetic field can induce a secondary current – this is why there is no such thing as a direct current transformer. In the case of the Dynomak, magnetic induction is used to create a plasma current inside a plasma filled chamber. This gets the plasma moving and the system eventually relaxes into a Taylor state or

. The relaxation process involves the flow of

Magnetic helicity In plasma physics, magnetic helicity is a measure of the linkage, twist, and writhe of a magnetic field. In ideal magnetohydrodynamics, magnetic helicity is conserved. When a magnetic field contains magnetic helicity, it tends to form large-scal ...

(a twist in the field lines) from the injectors into the center of the machine.Fisch, Nathaniel J. "Theory of current drive in plasmas." Reviews of Modern Physics 59.1 (1987): 175 Supporters of this heating approach have argued that induction is 2-3 orders of magnitude more efficient than RF or neutral beam heating.Jarboe, T. R., et al. "Recent results from the HIT-SI experiment." Nuclear Fusion 51.6 (2011): 063029 If this is true, it gives the Dynomak several distinct advantages over other fusion approaches like

tokamak A tokamak (; russian: токамáк; otk, 𐱃𐰸𐰢𐰴, Toḳamaḳ) is a device which uses a powerful magnetic field to confine plasma in the shape of a torus. The tokamak is one of several types of magnetic confinement devices being ...

s or

Magnetic mirror A magnetic mirror, known as a magnetic trap (магнитный захват) in Russia and briefly as a pyrotron in the US, is a type of magnetic confinement device used in fusion power to trap high temperature plasma using magnetic fields. T ...

s. But this is an open area of research; below are some examples of how effective inductive drive was in creating plasma current inside the dynomak. The Dynomak uses injectors, which are curved arms that are attached to the main chamber. An alternating current is applied around the curve of these arms, which creates the magnetic flux that drives the dynomak. The University of Washington experimented with two and three numbers of injectors. The

phase Phase or phases may refer to: Science *State of matter, or phase, one of the distinct forms in which matter can exist *Phase (matter), a region of space throughout which all physical properties are essentially uniform * Phase space, a mathematic ...

of the alternating current is offset to allow for the continuous injection of flux into the dynomak. In the case of two injectors the drive is offset by 90 degrees, while the case of three injectors offsets the current by 60 degrees.

Advantages

Because the

plasma structure forms naturally, supporters have argued that it has several inherent advantages, these are listed below. * Because the structure forms naturally, it may avoid the kink, interchange, and other plasma instabilities that normally plague structures. For this reason, it has been argued that the dynomak can pressurize and heat its plasma up to the Mercer limit on beta number. If true, this could ultimately shrink the reactor when compared to other fusion approaches. * Supporters have argued that the inductive drive is 2-3 orders of magnitude more efficient then RF heating or neutral beam heating. But this is an open area of research. * The Dynomak has no central solenoid, when compared to a Tokamak; lower the cost and power requirements for the reactor. * It has been argued that this machine does not need additional heating hardware like neutral beam injection. As of 2014 plasma densities reached 5x10¹⁹ m⁻³, temperatures of 60 eV, and maximum operation time of 1.5 ms. No confinement time results were available. At those temperatures no fusion, alpha heating or neutron production were expected.

Commercialization

Once the technical principals were proven in the HIT-SI machine, Dr. Jarboe challenged his students in a University of Washington class to come up with a fusion reactor based on this approach. The students designed the Dynomak as a reactor-level power plant that built off the discoveries made from the HIT-SI and earlier machines. Eventually, these students formed CT Fusion as a spin out from the University of Washington to commercialize the Dynomak in 2015. The company has exclusive rights to 3 University of Washington patents and raised over 3.6 million from 2015 to 2019 in public and private funding. The acronym CT stands for Compact Toroid, which is what spheromaks were referred to for decades. The company has received funding as part of an

ARPA-E ARPA-E, or Advanced Research Projects Agency–Energy is a United States government agency tasked with promoting and funding research and development of advanced energy technologies. It is modeled after the Defense Advanced Research Projects Agenc ...

funding award for fusion. Unlike other fusion reactor designs (such as ITER), the Dynomak would be, according to its engineering team, comparable in costs to a conventional

coal plant A coal-fired power station or coal power plant is a thermal power station which burns coal to generate electricity. Worldwide, there are about 8,500 coal-fired power stations totaling over 2,000 gigawatts capacity. They generate about a th ...

. Dynomak was expected to cost a tenth of ITER and produce five times as much energy at an efficiency of 40 percent. A one gigawatt Dynomak would cost US$2.7 billion compared to US$2.8 billion for a coal plant.

Design

Dynomak incorporates an ITER-developed cryogenic pumping system. Spheromak use an oblate

spheroid A spheroid, also known as an ellipsoid of revolution or rotational ellipsoid, is a quadric surface obtained by rotating an ellipse about one of its principal axes; in other words, an ellipsoid with two equal semi-diameters. A spheroid has ...

instead of a

configuration without a central core and without ITER's large, complex superconducting magnets. The magnetic fields are produced by putting electrical fields into the center of the plasma using superconducting tapes wrapped around the vessel, such that the plasma contains itself. Dynomak is smaller simpler and cheaper to build than ITER, while producing more power. The fusion reaction is self-sustaining as excess heat is drawn off by a

molten salt Molten salt is salt which is solid at standard temperature and pressure but enters the liquid phase due to elevated temperature. Regular table salt has a melting point of 801 °C (1474°F) and a heat of fusion of 520 J/g.Journal of Chemical T ...

blanket to power a steam turbine. The prototype was about one tenth the scale of a commercial project, is able to sustain plasma efficiently. Higher output would require increased scale and higher plasma temperature.

Criticisms

The Dynomak relies on a copper wall to conserve and direct the magnetic flux that is injected into the machine. This wall butts right up against the plasma, creating the possibility of high conduction losses through the metal. The HIT-SI coated the inside of the copper wall with an aluminum-oxide insulator to reduce these losses, but this could still be a major loss mechanism if the machine goes to fusion reactor conditions.Sieck, P. E., et al. "First Plasma Results from the HIT-SI Spheromak." APS Division of Plasma Physics Meeting Abstracts. Vol. 45. 2003 Additionally, the injection of magnetic helicity into the field forces the machine to break the magnetic flux surfaces that hold and sustain the plasma structure. The breaking of these surfaces has been cited as a reason that the Dynomaks' heating mechanism does not work as efficiently as predicted. Lastly, the Dynomak has a complex chamber geometry, which presents challenges for maintainability and vacuum formation.

References

{{reflist Research projects Fusion power University of Washington Plasma physics