ライフサイエンスコーパス: rare earth

1 ely tuned depending on the anisotropy of the rare earth.

2 sumer materials is a promising new source of rare earths.

3 Using rare earth-3d-transition metal ferrimagnetic compounds w

4 Photon upconversion in rare earth activated phosphors involves multiple mechani

5 inescence dynamics of photon upconversion in rare earth activated phosphors.

6 Shibasaki's rare earth alkali metal BINOLate (REMB) catalysts (REMB;

7 Compared to rare earth and silver-based NIR-II emitters, RNase-A@AuN

8 However, limited access to the rare earths and rising costs associated with their extra

9 y populated by B complexes), and finally the rare-earth and actinide species.

10 that charge is also actively compensated by rare-earth and alkaline-earth metal ions of the interfac

11 Here we present a new rare-earth and aluminum-free magnesium-based alloy, with

12 he +III and +IV oxidation states, while most rare earths are purely trivalent and share very similar

13 has been difficult to stably dope individual rare-earth atoms into the w-AlN host lattice.

14 a high temperature superconductor (HTS), a (Rare-Earth)Ba(2)Cu(3)O(7-delta) (REBCO) coated conductor

15 new ways to tune the magnetic properties of rare-earth based magnets with nano-sized building blocks

16 novel ultraviolet (UV) and blue emission in rare-earth based perovskite NdGaO3 (NGO) and the systema

17 window with short exposure time of 20 ms for rare-earth based probes.Fluorescence imaging in the near

18 Overall, rare-earth-based down-conversion nanoparticles demonstra

19 This is particularly true for rare-earth-based magnets because of the large effective

20 ized 4f electrons and itinerant electrons in rare-earth-based materials gives rise to their exotic pr

21 MOF-5, a hybrid microporous highly connected rare-earth-based metal-organic framework (MOF), with dua

22 ived from inorganic materials (e.g., oxides, rare-earth-based, and intermetallic compounds) are key c

23 It discusses in depth the different types of rare-earth carbonate compounds, diverse synthetic approa

24 This review focuses on rare-earth carbonate materials of nano- and micro-size.

25 luminescence properties of lanthanide doped rare-earth carbonates and their potential applications f

26 Orthorhombic RMnO(3) (R = rare-earth cation) compounds are type-II multiferroics i

27 molecular separation system for paramagnetic rare-earth cations.

28 , which are comparable to those reported for rare-earth chiral complexes.

29 that significantly impedes REBa2Cu3Ox (RE = rare earth) coated conductor applications is the low eng

30 ([{(2-(t) BuNO)C(6) H(4) CH(2) }(3) N](3-) ) rare-earth complexes, we efficiently and selectively cry

31 metals, semiconductors, oxides, magnetic, or rare earth compositions.

32 es in the oxidation rates within a series of rare earth compounds containing the redox-active ligand

33 low temperature (<70 K) and predominantly in rare-earth compounds such as RMnO3.

34 a function of composition was studied in low rare earth concentration alloys.

35 with leachates from metal-mine tailings and rare earth deposits, we show that functionalization of t

36 m the reported experimental results on heavy rare-earth diffusion.

37 the Gilbert damping, caused by the inclusion rare-earth dopants such as holmium, acts to suppress Wal

38 r quantum dots, perovskite nanocrystals, and rare earth doped phosphors), it is surprising that the d

39 e central ion in a quantum memory based on a rare-earth doped crystal.

40 Rare-earth doped wurtzite-type aluminum nitride (w-AlN)

41 step for practical application of nanosized rare-earth doped YAG on large scale.

42 udy the effects of exposure to atmosphere of rare earth-doped Bi2(Se, Te)3 thin films using x-ray abs

43 cs and stochastic pinning of domain walls in rare earth-doped Ni80Fe20 nanowires.

44 Rare-earth-doped mode-locked fibre lasers that produce h

45 iaxial strain along the <100> directions and rare-earth doping (Yb, Er, Ho, Dy, Gd, Sm, Nd, and La) o

46 Rare-earth doping is thus identified as a general strate

47 films with and without conversion layers or rare-earth doping.

48 Here, the authors synthesize rare earth down-converting nanocrystals as promising flu

49 tal rift-related settings, have strong light rare earth element (LREE) enrichment; they rarely contai

50 The rare earth element (REE) composition of a fossil bone re

51 Patterns in rare earth element (REE) concentrations are essential in

52 f rivers we have combined for the first time Rare Earth Element (REE) concentrations with Sr-Nd-Pb is

53 ns and validate these metrics using the 2010 rare earth element (REE) crisis as a case study.

54 of exceptional cellular preservation by the rare earth element (REE) phosphates monazite and xenotim

55 Increasing rare earth element (REE) supplies by recycling and expan

56 udy Ce, the most earth abundant and low-cost rare earth element as a single-filling element and demon

57 s highly selective colorimetric detection of rare earth element cerium is being reported for the firs

58 Yttrium is a chemically versatile rare earth element that finds use in a range of applicat

59 m phenomena in the RMn(6)Sn(6) (where R is a rare earth element) family with a variety of magnetic st

60 Layered compounds AMnBi2 (A = Ca, Sr, Ba, or rare earth element) have been established as Dirac mater

61 ets by Ce, the most abundant and lowest cost rare earth element, is important because Dy and Nd are c

62 Lanthanum, a rare earth element, was applied because of its increasin

63 -mining algorithm known as DBSCAN to study a rare-earth element based permanent magnet material, Nd2F

64 e environment, as indicated by seawater-like rare-earth element plus yttrium trace element signatures

65 skite rare-earth nickelates, RNiO(3) (R is a rare-earth element such as Sm or Nd), electrons associat

66 RENiO3 (RE=rare-earth element) and V2O3 are archetypal Mott insulat

67 st them, the REFeAs(O,F) (RE1111, RE being a rare-earth element) is the family with the highest criti

68 Gadolinium is a rare-earth element, which is normally not present in hum

69 Herein, we demonstrate a new approach for rare-earth-element separations by exploiting differences

70 This study examines the trace and rare earth elemental (REE) fingerprint variations of PDO

71 We observed enrichments in Anthropogenic Rare Earth Elements (AREE) for dissolved (Gd) and suspen

72 Heavy rare earth elements (HREE) are dominantly mined from the

73 nese, magnesium, nickel, tin, niobium, light rare earth elements (LREEs; lanthanum, cerium, praseodym

74 Global resources of heavy Rare Earth Elements (REE) are dominantly sourced from Ch

75 Many mining projects targeting rare earth elements (REE) are in development in North Am

76 The rare earth elements (REE) are increasingly important in

77 The manganese content, along with Rare Earth Elements (REE) concentrations, proved to be v

78 al distribution of gadolinium (Gd) and other rare earth elements (REE) in surface waters collected in

79 could contain critical materials such as the rare earth elements (REE) in valuable concentrations.

80 Detection of rare earth elements (REE) is commonly performed with des

81 ncentrates (UOC) prior to the analysis of 14 rare earth elements (REE) via laser ablation inductively

82 ) ] and is the main industrial source of the rare earth elements (REE), cerium and lanthanum.

83 Rare Earth Elements (REE), major and trace elements all

84 edded in all vehicle types and 220-60(+90) t rare earth elements (REE); found mainly in five electric

85 resuspension on particle fluxes in the ECS, rare earth elements (REEs) and organic carbon (OC) were

86 order to estimate the recovery potential of rare earth elements (REEs) and other resources contained

87 Rare earth elements (REEs) are critical and strategic ma

88 o their distinct physicochemical properties, rare earth elements (REEs) are critical to high-tech and

89 Rare earth elements (REEs) are indispensable components

90 In recent years, recovery of rare earth elements (REEs) from coal fly ashes (CFAs) ha

91 extraction (MSX) process for the recovery of rare earth elements (REEs) from scrap permanent magnets

92 The use of biomass for adsorption of rare earth elements (REEs) has been the subject of many

93 Rare earth elements (REEs) have become increasingly impo

94 With the increasing demand for rare earth elements (REEs) in many emerging clean energy

95 The increasing demand for rare earth elements (REEs) in the modern economy motivat

96 ties have resulted in significant release of rare earth elements (REEs) into the environment.

97 The rare earth elements (REEs) such as neodymium, praseodymi

98 Yttrium belongs to the rare earth elements (REEs) together with lanthanides and

99 Sensitive yet rapid methods for detection of rare earth elements (REEs), including lanthanides (Lns),

100 important elements from rocks, including the rare earth elements (REEs), used in electronic industrie

101 terials have been proposed as a resource for rare earth elements (REEs, herein defined as the 14 stab

102 Rare earth elements (REs) consist of a very important gr

103 d samarium), cobalt, silver, tungsten, heavy rare earth elements (yttrium, europium, gadolinium, terb

104 ons and an enhancement over KREEP (Potassium Rare Earth Elements and Phosphorus) surface regions, rev

105 atalyst accessibility by (a) the addition of rare earth elements and phosphorus, (b) constructing hie

106 Furthermore, the distribution pattern of rare earth elements and the concentrations of water-inso

107 nd probabilistic neural networks (PNN) using rare earth elements and trace metals determined using IC

108 by low melting points and high solubility of rare earth elements and volatile molecules.

109 Rare earth elements and yttrium (REY) are raw materials

110 allium, indium, and thallium) and some heavy rare earth elements are representative of modern technol

111 The trace and rare earth elements content of 93 honeys of different bo

112 Rare earth elements have generally not been thought to h

113 Purification of rare earth elements is challenging due to their chemical

114 ape bonded magnets, enables efficient use of rare earth elements thus contributing towards enriching

115 Neodymium is one of the more critical rare earth elements with respect to current availability

116 cterizing 47 elements including lanthanoids (rare earth elements), using inductively coupled plasma-m

117 ethanol obtained from honey fermentation and Rare Earth Elements, were used to develop new recognitio

118 nt magnets which frequently involve critical rare earth elements.

119 nt because Dy and Nd are costly and critical rare earth elements.

120 cobalt, rubidium, strontium, uranium and the rare earth elements.

121 The utility of rare-earth elements (REEs) as natural geochemical tracer

122 ied photochemically induced precipitation of rare-earth elements (REEs) in water from a tributary to

123 Rare-earth elements and minor metals (Y, La, Ce, Pr, Nd,

124 ) for this class of bulk materials with less rare-earth elements and outperforms, for the first time,

125 Recently, rare-earth elements lanthanides (Ln(3+) ) have emerged a

126 The emergence of technologies in which rare-earth elements provide critical functionality has i

127 Rh, and Ir, the alkali, alkaline-earth, and rare-earth elements, and Sb4 polyanions.

128 strong permanent magnets with less expensive rare-earth elements.

129 d complexes of expensive precious metals and rare-earth elements.

130 While urKREEP (primeval KREEP [potassium/rare-earth elements/phosphorus]) has been proposed to be

131 tope ratios of nitrogen and a high number of Rare Earth-Elements (REEs) were able to differentiate th

132 tion and single-shot spin measurement of six rare-earth (Er(3+)) ions, within the subwavelength volum

133 visible emission of sub-15 nm alkaline-earth rare-earth fluoride UCNPs (M(1-x) Ln(x) F(2+x,) MLnF) wi

134 instabilities make it imperative to explore rare earth free magnetic materials.

135 magnetic anisotropy which is a candidate for rare-earth free permanent magnet.

136 oys indicate their great potential as novel, rare-earth free permanent magnetic materials.

137 structure is usually insufficient to produce rare earth-free ferro(i)magnetic blocked nanoparticles a

138 temperature is the highest observed for any rare-earth-free hard magnet.

139 Rare-earth-free magnets are highly demanded by clean and

140 s can be measured in the glass bead, but the rare earth group in particular is a valuable series in n

141 Extension of the superatom concept into the rare earth group not only further shows the power and ad

142 n spectroscopy and ab initio calculations on rare-earth half-Heusler compounds LnPtBi (Ln=Lu, Y), we

143 hree isostructural gigantic transition-metal-rare-earth heterometallic coordination cages are reporte

144 ectron Fermi surface similar to the metallic rare earth hexaborides such as PrB6 and LaB6.

145 T: In the drive to reduce the critical Heavy Rare Earth (HRE) content of magnets for green technologi

146 Our results suggest that rare-earth intermetallics with highly symmetric crystal

147 nstrate single-shot spin readout of a single rare earth ion qubit, Er(3+), which is attractive for it

148 c-field operation are important advances for rare-earth ion magneto-optical devices.

149 RFeO3 orthoferrites, where R is a rare-earth ion of the lanthanide series, are attracting

150 llic catalysts of nickel(0) with a trivalent rare-earth ion or Ga(III), NiML(3) (where L is [(i)Pr(2)

151 We show that rare-earth ion substitution and strain engineering can s

152 cal states in centrosymmetric oxides through rare-earth ion substitution.

153 The combination of rare-earth ion, Er(3+) with the ferroelectricity of PVDF

154 2NiMnO6/La2NiMnO6 superlattices where R is a rare-earth ion--that exhibit an electrical polarization

155 Rare-earth-ion-doped crystals are state-of-the-art mater

156 ilicon photonic data link using a monolithic rare-earth-ion-doped laser, a silicon microdisk modulato

157 p) were doped with different combinations of rare earth ions (RE(3+) = Gd, Eu, Yb, Tm) to achieve a s

158 ycling transition; however, Er(3+) and other rare earth ions generally lack strong cycling transition

159 flexibility of the technique, by implanting rare earth ions into the core of a single mode fibre.

160 Cascade transitions of rare earth ions involved in infrared host fiber provide

161 e incorporation of other co-dopants, such as rare earth ions, has been largely overlooked in GaN.

162 We find that trivalent rare earth ions, Y(III) and Er(III), combine with bis(he

163 pectroscopic properties of solids containing rare earth ions.

164 trong effects of paramagnetic moments of the rare earth ions.

165 uction(11-15), but only recently have single rare-earth ions been isolated(16,17) and coupled to nano

166 The crucial next steps towards using single rare-earth ions for quantum networks are realizing long

167 olid-state platform based on single coherent rare-earth ions for the future quantum internet.

168 The separation of rare-earth ions from one another is challenging due to t

169 hat the intrinsic magnetic properties of the rare-earth ions impact the separations of light/heavy an

170 Rare-earth ions in crystals are known to have highly coh

171 local [Formula: see text] atomic orbitals of rare-earth ions is a realization of electronic nematic o

172 Coherent optical control of cavity-coupled rare-earth ions is performed via photon echoes.

173 Here, we use a dense ensemble of neodymium rare-earth ions strongly coupled to a nanophotonic reson

174 oadening are measured for the cavity-coupled rare-earth ions, thus demonstrating their potential for

175 lanthanum-phosphate glass doped with several rare-earth-ions for use as solid fluorescence standard i

176 nstrate coupling of an ensemble of neodymium rare-earth-ions to photonic nanocavities fabricated in t

177 ted using a single-crystalline ferrimagnetic rare-earth iron garnet film.

178 We show that epitaxial rare-earth iron garnet films with perpendicular magnetic

179 recycling rate of specialty metals, such as rare earths, is negligible compared to their increasing

180 are earths (Tb-Yb) from a mixture with light rare earths (La and Nd) in the presence of an external F

181 Smaller rare earths lead to conventional monoclinic double perov

182 We designed a 2-part, titanium-encased, rare-earth magnet oculomotor prosthesis, powered to damp

183 , for the first time, the corresponding pure rare-earth magnet with 58% enhancement in energy product

184 hat uses a compact and lightweight permanent rare-earth magnet with a built-in readout field gradient

185 ade 3D-printed holder containing an embedded rare-earth magnet.

186 he development of recycling technologies for rare earth magnets from postconsumer products, we presen

187 tudy two classes of ferromagnetic materials, rare-earth magnets with high intrinsic coercivity and an

188 performances compared to corresponding pure rare-earth magnets.

189 ses: (i) wide band gap AB compounds and (ii) rare earth-main group RM intermetallics.

190 For example, multiferroic hexagonal rare earth manganites exhibit a dense network of boundar

191 grees C/900 degrees C by using yttrium-based rare earth manganites.

192 cell tripling, reminiscent of the hexagonal rare earth manganites.

193 Chemical synthesis of platinum-rare earth metal (Pt-RE) nanoalloys, one of the most act

194 nding is also amplified by the fact that the rare earth metal atoms in the crystal structure are tetr

195 e the self-assembly of novel hydrogen-bonded rare earth metal BINOLate complexes that serve as bench-

196 se who are interested in beginning to employ rare earth metal complexes for the synthesis of new mate

197 Rare earth metal doped silica nanoparticles have signifi

198 in the thermolytic production of luminescent rare earth metal doped silica nanoparticles with charact

199 rce precursors for the preparation of sodium-rare earth metal fluorides are reported.

200 osphere was shown to yield phase-pure sodium-rare earth metal fluorides.

201 MOF-1114(RE) and MOF-1115(RE)] with variable rare earth metal ions (RE(3+) = Y(3+), Sm(3+), Eu(3+), G

202 rs who are currently working in the field of rare earth metal mediated polymerization catalysis as we

203 A value analysis considering rare earth metal prices between 2002 and 2013 provides v

204 l study of the first borylimido complex of a rare earth metal, (NacNac(NMe2))Sc{NB(NAr'CH)2} (25, Ar'

205 ew focuses on introducing and explaining the rare earth metal-mediated group transfer polymerization

206 , has been obtained by LnA3 /M reactions (Ln=rare earth metal; A=anionic ligand; M=alkali metal) invo

207 The chemistry of actinide (An) and rare-earth metal (Ln and group 3) complexes featuring mu

208 r over 40 crystallographically characterized rare-earth metal (N horizontal lineN)(2-) complexes of f

209 pproach to synthesize strongly ferromagnetic rare-earth metal (REM) based SmCo and SmFeN nanoparticle

210 ng MOFs when combined with Zr(4+)/Hf(4+) and rare-earth metal cations (RE) with improved gas-sorption

211 the first example of an arsinidene ligand in rare-earth metal chemistry.

212 Four chiral dinuclear rare-earth metal complexes [REL(1)](2) (RE = Y(1), Eu(2)

213 ine synthesis protocols seem less viable for rare-earth metal imide complexes.

214 l breakthroughs in substituting precious and rare-Earth metal ions (e.g. Ru, Ir, Pt, Au, Eu) in these

215 Hence, the use of the rare-earth metal ions can lead to the formation of uniqu

216 igh-pressure metathesis to prepare the first rare-earth metal nitridophosphate, Ce4Li3P18N35, with a

217 synthesis, structure, and reactivity of the rare-earth metal phosphides.

218 hods for targeted separations of mixtures of rare-earth metal salts.

219 first (N horizontal lineN)(2-) complex of a rare-earth metal with an end-on dinitrogen bridge, {K(cr

220 the REFeAsO-type compounds (with RE being a rare-earth metal) exhibit the highest bulk superconducti

221 m comprising [M(TriNOx)thf]/ [M(TriNOx)]2 (M=rare-earth metal).

222 yer complexity in a family of heterometallic rare-earth metal-organic frameworks based on highly conn

223 The synergy between reductants and rare-earth-metal complexes allows the cleavage of unacti

224 The reaction between rare-earth-metal iodides supported by a 1,1'-ferrocenedi

225 Rare-earth-metal separations based on kinetic difference

226 silylium cation produces the first base-free rare-earth metallocenium cation [(Cp(ttt) )2 Dy](+) (2Dy

227 pability has been tested by the inclusion of rare earth metals (Eu, Tb and Gd) to produce a luminesce

228 ribed are two unprecedented cases, where the rare earth metals Tm and Lu partially substitute Al atom

229 in the formation of self-assembled cages of rare earth metals with multianionic salicylhydrazone lig

230 ny of these materials (including lithium and rare earth metals) are at risk of supply disruption.

231 Neodymium, one of the more critically scarce rare earth metals, is often used in sustainable technolo

232 well as thorium, in competition with various rare earth metals.

233 Rare-earth metals are critical components of electronic

234 These rare-earth metals are not only essential for XoxF activi

235 new type of C-H bond activation mediated by rare-earth metals under reducing conditions is reported.

236 s have previously been fabricated from toxic rare-earth metals.

237 ybrid phosphor materials are totally free of rare-earth metals.

238 ng up the great possibility in accomplishing rare earth mimicry.

239 e of core samples collected at a prospective rare earth mine.

240 The rare-earth monopnictide family is attracting an intense

241 Several rare-earth monopnictides were shown to exhibit extreme m

242 e synthesis of a down-conversion luminescent rare-earth nanocrystal with cerium doping (Er/Ce co-dope

243 tible cubic-phase (alpha-phase) erbium-based rare-earth nanoparticles (ErNPs) exhibiting bright downc

244 roelectric-phase Sr(3) Sn(2) O(7) doped with rare earth Nd(3+) ions.

245 t only exposes the near-critical behavior in rare earth nickelates but also underscores the potential

246 ons in strongly correlated materials such as rare-earth nickelates has opened up a new paradigm in re

247 , that in the correlated-electron perovskite rare-earth nickelates, RNiO(3) (R is a rare-earth elemen

248 pects of the complex electronic structure of rare-earth nickelates, taking NdNiO3 thin film as repres

249 with the crystal structure across the MIT in rare-earth nickelates.

250 h disproportionation model of the MIT in the rare-earth nickelates.

251 of intrinsically porous frameworks made from rare-earth nitrates and hexahydroxytriphenylene.

252 Yet, due to their alloying elements, such as rare-earths or aluminum, they are either not economical

253 in perpendicularly-magnetized iron garnets, rare-earth orbital magnetism gives rise to an intrinsic

254 ctricity, as in the much studied families of rare-earth orthoferrites and orthochromites; yet, the me

255 dominant contributions are the mining of the rare earth oxide ceria, the manufacturing of the solar c

256 orption spectroscopy and production of local rare earth patterns in paleontological fossil tissues th

257 on and the intriguing physical properties of rare-earth perovskite nickelates have attracted consider

258 Amongst the rare-earth perovskite nickelates, LaNiO(3) (LNO) is an e

259 Here, we demonstrate that the rare-earth perovskite YbAlO(3) provides a realization of

260 clearly demonstrate that site engineering of rare-earth phosphors is an effective strategy to target

261 In condensed matter, the frustrated rare-earth pyrochlore magnets Ho2Ti2O7 and Dy2Ti2O7, so-

262 ructure of ions and vacancies characterizing rare-earth pyrochlore oxides serves as a model for the s

263 warted by hybridization effects tuned by the rare-earth (R) size.

264 nd biological use of selected main group and rare earth radiometals.

265 The Td point group symmetry of rare earth (RE(3+)) metal clusters RE4(mu3-OH)4(COO)6(2+

266 Solid solutions of the rare earth (RE) cations Pr(3+), Nd(3+), Sm(3+), Gd(3+),

267 Rare earth (RE) metals are critical components of electr

268 Here we use a new rare earth (RE) nonanuclear carboxylate-based cluster as

269 increase in creep life in a prototypical Mg-rare earth (RE)-Zn alloy to multiple mechanisms caused b

270 g control over the assembly of highly porous rare-earth (RE) based metal-organic frameworks (MOFs) re

271 MOFs synthesized with rare-earth (RE) elements, which include scandium, yttriu

272 covery of highly efficient phosphors free of rare-earth (RE) elements.

273 Herein, we report a series of mesoporous rare-earth (RE) MOFs that are constructed from an unusua

274 y to evolve the topology of highly connected rare-earth (RE) MOFs, where a pivot group is placed in t

275 bination of 12-connected hexagonal prismatic rare-earth (RE) nonanuclear [RE(9)(mu(3)-O)(2)(mu(3)-OH)

276 of our recently isolated 12-connected (12-c) rare-earth (RE) nonanuclear [RE9(mu3-OH)12(mu3-O)2(O2C-)

277 A rare-earth (RE)/transition metal (TM) ferromagnetic mult

278 fully employed to deliberately construct new rare-earth (RE, i.e., Eu(3+), Tb(3+), and Y(3+)) fcu met

279 Characteristic "Rare Earth" (RE) texture was formed, originating mainly

280 olvent extraction is a proven technology for rare-earth recovery and separation, its application ofte

281 The rare earths (REs) are a family of 17 elements that exhib

282 ; hexagonal boron nitride; silicon carbide), rare earth, semimetals, transition metal chalcogenides a

283 traction and illustrate its applicability to rare earths separation.

284 Nearly all rare-earth separations rely upon small changes in ionic

285 Rare earth silicate apatites are one-dimensional channel

286 A new family of mixed anion cesium rare earth silicates exhibiting intense scintillation in

287 n (ACC) strategy to achieve the synthesis of rare-earth single erbium (Er) atoms supported on carbon

288 the prospect of coupling to other long-lived rare-earth spin states, this technique opens the possibi

289 we reported Q-switched lasers incorporating rare-earth substituted iron garnet (RIG) film.

290 ficiently and selectively crystallized heavy rare earths (Tb-Yb) from a mixture with light rare earth

291 tric properties of the relatively unexplored rare-earth ternary compounds La3Cu3X4 (X = Bi, Sb, As, a

292 shell growth techniques in hexagonal sodium rare-earth tetrafluoride (beta-NaLnF4) nanocrystals by e

293 AO-HDS) can be observed not only in selected rare earth-transition metal (RE-TM) alloy films but also

294 30 nm thick rare earth:transition-metal films of composition Gd(x)Co

295 dynamic probes to study the newly discovered rare-earth triangular-lattice magnet TmMgGaO(4).

296 rategy that combines spatial patterning with rare-earth upconversion nanocrystals, single-wavelength

297 sses of chalcogenides that include both new (rare earth uranium sulfides and alkali-thorium thiophosp

298 technology metals such as V, Cr, Ga, Nb, and rare earths were comparatively low.

299 Stocks of precious metals and rare earths will increase faster than most base material

300 Information obtained using Rare Earths (Y, La, Ce, Pr, Nd, Sm, Eu, Gd, Tb, Dy, Ho,