A high temperature W2B–W composite for fusion reactor shielding

Athanasakis-Kaklamanakis, Michail; Ivanov, Eugene; Río, Eduardo del; Humphry-Baker, Samuel A.

doi:10.1016/j.jnucmat.2020.152062

Cited by 15 publications

(6 citation statements)

References 70 publications

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“…Theoretical densities are taken from reference [10]. The densities are at 98% of the theoretical values, based on data on W 2 B-based materials in reference [11], which included 2% porosity. The last column gives densities measured by x-rays for this paper [16], multiplied by 0.98. neutron energy is therefore appreciably reduced but there will be a new gamma flux leading to its own transmitted energy and needing extra gamma shielding.…”

Section: The Advantages Of Tungsten and Boron As Shield Materialsmentioning

confidence: 99%

“…It has been shown that the inclusion of boron within a tungstenbased shield is advantageous, with its high neutron absorption cross section at lower energies [4]. Various practical efforts to fabricate and test the properties of such materials have begun [10][11][12][13] but the search is on to find the optimal boroncontaining material, and optimal parameters for a tokamak shield of specified lifetime.…”

Section: Introductionmentioning

confidence: 99%

“…For tungsten the total (black), elastic (green, dashed), inelastic (red, dash-dot), (n, 2n) (blue, dotted) and (n, γ) (yellow) cross sections are shown. For boron the minority (20%)10 B isotope (black) and the majority11 B isotope cross section (blue dashed) are shown. Below 10 keV the 10 B cross section follows an inverse velocity increase with decreasing neutron energy as show in the curve labelled 10 B abs .…”

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confidence: 99%

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Tungsten boride shields in a spherical tokamak fusion power plant

et al. 2021

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The favourable properties of tungsten borides for shielding the central high temperature superconductor (HTS) core of a spherical tokamak fusion power plant are modelled using the MCNP code. The objectives are to minimize the power deposition into the cooled HTS core, and to keep HTS radiation damage to acceptable levels by limiting the neutron and gamma fluxes. The shield materials compared are W2B, WB, W2B5 and WB4 along with a reactively sintered boride B0.329C0.074Cr0.024Fe0.274W0.299, monolithic W and WC. Five shield thicknesses between 253 and 670 mm were considered, corresponding to plasma major radii between 1400 and 2200 mm. W2B5 gave the most favourable results with a factor of ∼10 or greater reduction in neutron flux and gamma energy deposition as compared to monolithic W. These results are compared with layered water-cooled shields, giving the result that the monolithic shields, with moderating boron, gave comparable neutron flux and power deposition, and (in the case of W2B5) even better performance. Good performance without water-coolant has advantages from a reactor safety perspective due to the risks associated with radio-activation of oxygen. 10B isotope concentrations between 0% and 100% are considered for the boride shields. The naturally occurring 20% fraction gave much lower energy depositions than the 0% fraction, but the improvement largely saturated beyond 40%. Thermophysical properties of the candidate materials are discussed, in particular the thermal strain. To our knowledge, the performance of W2B5 is unrivalled by other monolithic shielding materials. This is partly as its trigonal crystal structure gives it higher atomic density compared with other borides. It is also suggested that its high performance depends on it having just high enough 10B content to maintain a constant neutron energy spectrum across the shield.

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Section: The Advantages Of Tungsten and Boron As Shield Materialsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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Tungsten boride shields in a spherical tokamak fusion power plant

et al. 2021

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“…This includes the use of Li-containing components, such as Li 2 TiO 3 [9], and neutron-multiplying materials containing isotopes of Be and Pb [10]. Efficient thermal neutron absorber materials based upon borides (for example, tungsten borides [11]), are being considered alongside other high-neutron cross-section materials and gamma shielding materials with high Z values.…”

Section: Tritium Transmutation and Neutron Bombardment ('The Triple W...mentioning

confidence: 99%

Materials challenges for successful roll-out of commercial fusion reactors

Quadling¹,

Lee²,

Astbury³

2022

J. Phys. Energy

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As members of the UK fusion community (covering national laboratories, academia and industry), we approached various colleagues to put together articles for this special issue of the Journal of Physics: Energy covering the materials challenges through to successful roll-out of fusion reactors. This paper serves to introduce the special issue and gives our opinion on the key challenges, many of which are covered in more detail in the submitted papers. Others may have differing opinions about what the key challenges are, but what we will all agree on is that they are substantial and will require sizeableresources to be addressed. Further, while we are all UK-based, all humankind will benefit from successful commercial roll-out of fusion for energy production, and the effort has been and will continue to be global. Fusion has entered the engineering era. Moving from plasma science to experiments demonstrating the benefits of modified torus shapes and advanced divertor geometries, the ‘field’ has become an ‘industry’. Investors now focus on whether superconducting magnet joints are feasible in large tokamak designs and how to deliver net energy to the grid. As with all technology trajectories, materials (both structural and functional) are the key enablers. For fusion materials, the three major challenges remain resilience to the combined damaging effects of tritium, transmutation and neutron bombardment (a veritable ‘triple whammy’), achieving suitable irradiation strategies for adequate damage studies (with optimal use of modelling as complementary science) and defining material safety and waste guidance in an era of evolving regulation. In the following, we highlight issues around ‘the triple whammy’, the resulting need for testing facilities and modelling proxies, and aspects of regulating materials in, and waste generated from, operating fusion reactors.

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“…[22] B2O3-Pb3O4-ZnO camlarının nükleer zırhlama özelliklerini, Athanasakis vd. [23] Füzyon reaktör zırhlama malzemesi olarak yüksek sıcaklıklı W2BeW kompozitin özelliklerini çalışmışlardır. Song vd.…”

Section: Giriş (Introduction)unclassified

Magnezyotermik indirgeme ile sentezlenen Lantanyum hekzaborür (LaB6) ve Seryum hekzaborür (CeB6) malzemelerinin gama zırhlama özelliklerinin Monte Carlo simülasyonu

Özcan

Türkan

Aksu

et al. 2022

Gazi Üniversitesi Mühendislik Mimarlık Fakültesi Dergisi

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Radyasyon kullanımı tıp, sanayi, tarım ve nükleer santraller alanında günden güne artarak gelişmeye devam etmektedir. Bu alanlardaki iş kollarında çalışanların ve halkın radyasyonun zararlı etkilerinden korunması, nükleer teknolojilerin gelişiminin yanı sıra oldukça önemli başka bir konudur. Bu çalışmada, kimya laboratuvarımızda sentezlenen bazı hekzaborürler (LaB6 ve CeB6) X–ışını kırınımı (XRD) ile analiz edilmiş, Debye Scherrer eşitliği ile ortalama kristal boyutları hesap edilmiş, nano boyutta oldukları görülmüş ve bu numunelerin gama ışını zırhlama özellikleri incelenmiştir. Gama ışını koruma parametreleri olarak; kütle zayıflatma katsayıları, yarı değer katmanı, onda bir değer katmanı, ortalama serbest yol, etkin atom numarası, etkin elektron yoğunluğu, toplam atomik kesit ve toplam elektronik kesit değerleri, Monte Carlo yöntemi ile belirlendi. Bu yöntemde kullanılan foton enerji aralığı, 1.0 keV - 105 MeV olup, elde edilen veriler XCom programı tarafından hesaplanan sonuçlarla karşılaştırıldı. MC ve XCom arasında hesaplanan sonuçlar, radyasyon koruyucu malzemeler olarak kurşun, vermikülit, borosilikat, beton ve granit ile karşılaştırıldığında başarılı bir tutarlılık göstermiştir. Üretilen hekzaboridlerin, literatürde daha önce araştırılan malzemelere kıyasla daha umut verici gama koruma özelliklerine sahip olduğu sonucuna varılmıştır.

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A high temperature W2B–W composite for fusion reactor shielding

Cited by 15 publications

References 70 publications

Tungsten boride shields in a spherical tokamak fusion power plant

Tungsten boride shields in a spherical tokamak fusion power plant

Materials challenges for successful roll-out of commercial fusion reactors

Magnezyotermik indirgeme ile sentezlenen Lantanyum hekzaborür (LaB6) ve Seryum hekzaborür (CeB6) malzemelerinin gama zırhlama özelliklerinin Monte Carlo simülasyonu

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