ライフサイエンスコーパス: bronze

1 of glass and an upper region of the heavier bronze.

2 s for thousands of years since the advent of bronze.

3 O(t)Bu to the Bronsted acidic protons of the bronze.

4 lized electrons to afford mixed-metal hybrid bronzes.

5 ed to date, including the well characterized Bronze 1 (Bz1) gene of maize.

6 was noted with the catastrophic (26.4%) and bronze (22.7%) plans, while gold plans had the lowest sh

7 Here we study molybdenum blue bronze A(0.3)MoO(3) (A = K, Rb), a canonical quasi-one-d

8 CE), Chalcolithic ( 3000-2200 BCE) and Early Bronze Age ( 2200-1500 BCE).

9 round 4000 BCE and expanded during the Early Bronze Age (3300 BCE).

10 archaeological contexts dated from the Early Bronze Age (3500-2500 BC) to the 1(st) Century BC.

11 5.8 ka), with cattle appearing at the early Bronze Age (4.2 ka) and goats arriving later (3.5 ka).

12 the Helladic (Mycenaean) cultures define the Bronze Age (BA) of Greece.

13 The emerging Bronze Age (BA) of southeastern Iberia saw marked social

14 spanning at least 3500 years, from the Early Bronze Age (c.

15 tein analysis, that cauldrons from the Final Bronze Age (ca. 2700 BP) were primarily used to collect

16 preserved in human dental calculus from the Bronze Age (ca. 3000 BCE) to the present day.

17 Eurasian Steppes during the Early or Middle Bronze Age (ca. 3000-1500 BCE), the actual economic basi

18 first population, Cis-Baikal Late Neolithic-Bronze Age (Cisbaikal_LNBA), is associated with Yeniseia

19 power vacuum created by the collapse of Late Bronze Age (LB, ca. 1300 BCE) civilizations and the disi

20 n whether the glass produced during the Late Bronze Age (LBA) originated in Egypt or Mesopotamia.

21 ng and archaeobotanical analysis to two Late Bronze Age (LBA) sites, Esperstedt and Kuckenburg, in ce

22 asian Steppe belonging to the Late Neolithic Bronze Age (LNBA) lineage, until now exclusively identif

23 s genomes spanning the Late Neolithic to the Bronze Age (LNBA; 4,800 to 3,700 calibrated years before

24 wo cereals were cultivated during the Middle Bronze Age (MBA), around 2000-1800 BC, especially Setari

25 hic (EN) hunter-gatherers and 19 Middle-Late Bronze Age (MLBA) pastoralists, from the site of Koken i

26 stry from the second, Yakutia Late Neolithic-Bronze Age (Yakutia_LNBA), is associated with migrations

27 e between the Early Neolithic (~5450 BC) and Bronze Age (~2200 BC) in Central Europe.

28 Radiocarbon (carbon-14) data from the Aegean Bronze Age 1700-1400 B.C. show that the Santorini (Thera

29 e results support the notion that during the Bronze Age a dispersal of individuals carrying the R-S11

30 oss the transition from the Neolithic to the Bronze Age add to the archaeological evidence of continu

31 rasian ancestry back to the Eneolithic/Early Bronze Age Afanasievo and Early Bronze Age Khemtseg (Che

32 Early Bronze Age and flourished in the Late Bronze Age alongside the emergence of diverse mortuary p

33 of Eastern Mediterranean cuisines during the Bronze Age and Early Iron Age, we analyzed microremains

34 nites inhabited the Levant region during the Bronze Age and established a culture that became influen

35 of descent from Mesolithic Britain into the Bronze Age and even to the present day.

36 astoralism reached Mongolia during the Early Bronze Age and flourished in the Late Bronze Age alongsi

37 sistence of such a river during the Harappan Bronze Age and the Iron Age Vedic period is strongly deb

38 and third centering on the beginning of the Bronze Age and the late Iron Age, respectively.

39 stry that occurred in the region between the Bronze Age and today.

40 f male lineages, and focused interest on the Bronze Age as a period of cultural and demographic chang

41 nsity of Indo-Mediterranean trade during the Bronze Age as well as the degree of globalization in ear

42 an analysis of 14 warriors from the Tollense Bronze Age battlefield in northern Germany (~3,200 befor

43 and Unetice contexts in Germany, as well as Bronze Age Bulgaria.

44 e-wide data of 46 individuals from the Early Bronze Age burial ground of Leubingen in today's Germany

45 c analysis of equids uncovered in rich Early Bronze Age burials at Umm el-Marra, Syria, placed them b

46 We find that a Bronze Age Canaanite-related ancestry was widespread in

47 ns related to the Chalcolithic Zagros or the Bronze Age Caucasus.

48 east, at least one-tenth of the ancestry of Bronze Age central Anatolians, who spoke Hittite(4,5).

49 The first advanced Bronze Age civilization of Europe was established by the

50 fered in mobility pattern from the following Bronze Age communities from more northern areas.

51 In the Middle Bronze Age community that we studied, we find multiple c

52 val of millet is often seen as part of wider Bronze Age connectivity, yet understanding of the subsis

53 two canids excavated from Late Neolithic and Bronze Age contexts in the Stora Forvar cave on the isla

54 hed a chronology for the initial Aegean Late Bronze Age cultural phases (Late Minoan IA, IB, and II).

55 e Caucasus influence on this important Early Bronze age culture.

56 ly, we refine the genetic origin of the Late Bronze Age Deer Stone-Khirgisuur Complex populations, tr

57 metacarpals shows that Botai horses resemble Bronze Age domestic horses rather than Paleolithic wild

58 n South Asia has the same profile as that in Bronze Age Eastern Europe, tracking a movement of people

59 l daggers are widespread in Chalcolithic and Bronze Age Europe, yet their social and practical roles

60 focuses interest on the social structure of Bronze Age Europe.

61 o South Asia and Europe before the suggested Bronze Age expansion of Indo-European languages from the

62 emographic reconstructions show no signal of Bronze Age expansion, but evidence of Paleolithic expans

63 Canarian natives show signatures related to Bronze Age expansions in Eurasia and trans-Saharan migra

64 hern Europe and remained isolated from later Bronze Age expansions on the mainland.

65 er-gatherers (10,800 to 4250 cal BCE) and 26 Bronze Age farmers from the Corded Ware complex Fatyanov

66 y well preserved circa 3.400-year old Danish Bronze Age female find, known as the Egtved Girl.

67 Neolithic Bell Beaker Complex and the Early Bronze Age from the Lech River valley in southern Bavari

68 led as an admixture between a northern China Bronze Age genetic source and a source of Jomon-related

69 uggest that Southeastern Europe in the Early Bronze Age had a significantly different family and soci

70 ne samples from seven Peruvian mummies and a Bronze Age hair sample from Denmark.

71 Irish Bronze Age haplotypic similarity is strongest within mod

72 The collapse of the Bronze Age Harappan, one of the earliest urban civilizat

73 of early farmers from the Near East and then Bronze Age herders from the Pontic Steppe.

74 in 20 early Neolithic and 16 late Neolithic/Bronze Age human remains.

75 on libraries created from four Iron Age and Bronze Age human teeth from Bulgaria, as well as bone sa

76 d on a new dataset of Chalcolithic and Early Bronze Age human teeth.

77 The transition from Stone to Bronze Age in Central and Western Europe was a period of

78 esolithic period, Neolithic period and Early Bronze Age in Denmark and integrated these with proxies

79 ons, highlighting strong selection since the Bronze Age in Europe (<4,500 years) and potential geneti

80 The Early Bronze Age in Europe is characterized by social and gene

81 teries from the Late Neolithic to the Middle Bronze Age in southern Germany.

82 lactose tolerance, can be traced back to the Bronze Age in the Eastern Baltic.

83 h the major transition from the Neolithic to Bronze Age in the Yellow River valley and supports hypot

84 A Late Bronze Age individual dated to 980-825 cal BCE has a gen

85 An Early Bronze Age individual has an ancestry profile related to

86 rovide the first genomic characterization of Bronze Age individuals (n = 8; 0.001-1.2x coverage) from

87 elong to a sublineage previously observed in Bronze Age individuals from Central Europe that had lost

88 Genome studies of several Bronze Age individuals from each of these regions have n

89 ts of archaeogenetic investigations of Early Bronze Age individuals from Lower Austria, specifically

90 by analysing 91 newly generated genomes from Bronze Age individuals from present Poland and Ukraine,

91 Three Bronze Age individuals from Rathlin Island (2026-1534 ca

92 orial expansions during the Early and Middle Bronze Age is characterized by long-term genetic stabili

93 ra-forming eruption of Santorini in the Late Bronze Age is known to have been tsunamigenic, and calde

94 lithic/Early Bronze Age Afanasievo and Early Bronze Age Khemtseg (Chemurchek) populations.

95 Pb concentrations in Magdalenian and Bronze age levels at El Pirulejo site can be similarly i

96 The Late Bronze Age marks another period of gene flow from multip

97 dence for pastoral-related multi-cropping in Bronze Age Mesopotamia provides an antecedent to first m

98 e analysis and experiments shed new light on Bronze Age metal daggers, showing that they were fully f

99 significant archaeological remains found at Bronze Age metallurgical workshops in China.

100 s, perhaps whole families, whereas the later Bronze Age migration and cultural shift were instead dri

101 Europe from Anatolia and the late Neolithic/Bronze Age migration from the Pontic-Caspian Steppe, can

102 with the late Neolithic period and following Bronze Age migrations.

103 The origins of the Bronze Age Minoan and Mycenaean cultures have puzzled ar

104 ng contributed to the demographic success of Bronze Age Mongolian populations and that the origins of

105 etically distinct individual within the Late Bronze Age Northern Levant.

106 The Bronze Age of Central Europe was a period of major socia

107 The Bronze Age of Eurasia (around 3000-1000 BC) was a period

108 nt of pastoralism at high altitudes from the Bronze Age onwards and the extension of agriculture star

109 ere major centres of maritime trade from the Bronze Age onwards.

110 sian ancestry in the Lebanese not present in Bronze Age or earlier Levantines.

111 ungary from the Middle Neolithic to the Late Bronze Age periods.

112 e heightened mobility of the Middle and Late Bronze Age periods.

113 d genetic evidence supports widespread Early Bronze Age population movements out of the Pontic-Caspia

114 expansion coincided with the collapse of pre-Bronze Age population structure.

115 orm Early Bronze Age were followed by Middle Bronze Age populations displaying unique characteristics

116 oland and Ukraine, we discovered that Middle Bronze Age populations were formed by an additional admi

117 pean hunter-gatherers, Steppe Eneolithic and Bronze Age populations, and European Late Neolithic/Bron

118 Age populations, and European Late Neolithic/Bronze Age populations, while their X chromosomes are in

119 mon/broomcorn millet (Panicum miliaceum), in Bronze Age pottery vessels from the Korean Peninsula and

120 s performed on ten copper-alloy daggers from Bronze Age Pragatto, Italy, c.1550-1250 BCE.

121 fowling, and sea fishing station, and in the Bronze Age probably also for grazing.

122 e anchorage phases can be distinguished: (i) Bronze Age proto-harbours that correspond to natural anc

123 Slightly elevated delta(15)N values for Bronze Age samples imply higher reliance on protein than

124 shows that the frequency of CCR5-Delta32 in Bronze Age samples is similar to that seen today, pushin

125 ete) shows that a tsunami resulting from the Bronze Age Santorini eruption reached the outskirts of t

126 sults open the field for new research on the Bronze Age Santorini tsunami regarding both impact and c

127 The Bronze Age saw new social organization emerge amid a 40%

128 A later region-wide Bronze Age shift indicates rapid and widespread introgre

129 ta with genotypes of 18 individuals from the Bronze Age site Mokrin in Serbia (~4,100 to ~3,700 BP) a

130 Pontic-Caspian Steppe region, predating both Bronze Age sites (~5,980 to ~3,980 BP).

131 cial structure than Late Neolithic and Early Bronze Age societies of Central Europe.

132 isotope data to gain new insights into Early Bronze Age societies.

133 s related to the Chalcolithic Zagros and the Bronze Age Southern Levant.

134 of the NPR Scythians was found with the late Bronze Age Srubnaya population of the Northern Black Sea

135 y 3,800-y-old burial mound attributed to the Bronze Age Srubnaya-Alakul cultural tradition at the sit

136 'steppe-forest' cline descends from the Late Bronze Age steppe ancestries, while the 'southern steppe

137 espread introduction of Neolithic farmer and Bronze Age Steppe ancestries.

138 odern and ancient datasets: 15 from the Late Bronze Age stone-cist graves (1200-400 BC) (EstBA) and 6

139 at the Neolithic peoples of Europe and their Bronze Age successors are not closely related to the mod

140 y of Southern Europe and West Asia since the Bronze Age that can be complemented by genetics.

141 The first occurred during the initial Bronze Age that, we suggest, reflected restricted elite

142 bris are in situ victims related to the Late Bronze Age Thera eruption event.

143 The Late Bronze Age Thera eruption was one of the largest natural

144 om episodic grazing during the Neolithic and Bronze Age to agropastoralism in the Middle Ages.

145 rn Kihnu sheep and 83 ancient sheep from the Bronze Age to Modern Period (850 BCE-1950 CE).

146 e burden common to past populations from the Bronze Age to the early 20(th) century.

147 s majority genomic continuity from the Early Bronze Age to the Iron Age, this is markedly reduced in

148 w human migrations from the Neolithic to the Bronze Age transformed the social and genetic structure

149 haeological continuity across the Eneolithic-Bronze Age transition and a likely epicentre of Yamna fo

150 oss Europe, the genetics of the Chalcolithic/Bronze Age transition is increasingly characterized in t

151 widespread admixture during the Chalcolithic/Bronze Age transition.

152 hic patterns in France for the Neolithic and Bronze Age transitions consistent with neighboring regio

153 The Neolithic and Bronze Age transitions were profound cultural shifts cat

154 well-defined calendar placement of a Middle Bronze Age tree-ring chronology.

155 We show that the Bronze Age was a highly dynamic period involving large-s

156 sociated with steppe pastoralists form Early Bronze Age were followed by Middle Bronze Age population

157 the Neolithic period and the following Early Bronze Age were marked by 'eastern' gene flow, which was

158 Using analysis of a well-preserved Early Bronze Age wooden container from Switzerland, we propose

159 ch metal resources, became a crucible of the Bronze Age(1) and the birthplace of the earliest steppe

160 n farmers (EEF) than did people of the Early Bronze Age(1).

161 me dataset from the Mesolithic period to the Bronze Age(2), along with new Medieval and post-Medieval

162 ermed the 'LNBA lineage' (Late Neolithic and Bronze Age), has been suggested to have spread into Euro

163 since the Paleolithic) and Africa (since the Bronze Age).

164 ividuals spanning the Late Neolithic to Late Bronze Age, a period characterized by intense interregio

165 allele frequency estimates from Eneolithic, Bronze Age, and modern Eastern European samples and forw

166 teppe, persisted within Europe until the mid-Bronze Age, and moved back toward Central Eurasia in par

167 1-M267 expanded during the Chalcolithic, the Bronze Age, and the Iron Age.

168 was already present at high frequency in the Bronze Age, but not lactose tolerance, indicating a more

169 ary exploitation of horses prior to the late Bronze Age, ca. 1200 BCE - at which point horses come to

170 of Mid-Holocene (Late Mesolithic to Initial Bronze Age, ca. 7000-3000 BCE) Europe are characterized

171 has a broader demographic impact during the Bronze Age, despite continuity of local Chalcolithic gen

172 Starting with the Bronze Age, however, regional populations diverged from

173 the Pontic Steppe during the late Neolithic/Bronze Age, however, we estimate a dramatic male bias, w

174 into Mongolia ca. 3000 BCE, and by the Late Bronze Age, Mongolian populations were biogeographically

175 uring the Late Chalcolithic and/or the Early Bronze Age, more than half of the Northern Levantine gen

176 ndicates they were abandoned before the Late Bronze Age, pointing to a potentially earlier origin.

177 During the Early Bronze Age, populations of the western Eurasian steppe e

178 d of the Iberian Late Chalcolithic and Early Bronze Age, suggesting that the population history of th

179 ancestry in the Greek mainland by the Middle Bronze Age, we additionally show that such genetic signa

180 A lineages evidently arrived afresh with the Bronze Age, we also find evidence for continuity in the

181 asin by Afanasievo migrants during the Early Bronze Age, we find that the earliest Tarim Basin cultur

182 we contextualize its Chalcolithic period and Bronze Age, when extensive gene flow entangled it with t

183 o indicates horse domestication by the Early Bronze Age, which provides support for its role in stepp

184 large-scale population replacement after the Bronze Age.

185 of Indo-European languages during the Early Bronze Age.

186 within the globalized societies of the Late Bronze Age.

187 apse at the end of the northwestern European Bronze Age.

188 ovement of Yamnaya steppe peoples during the Bronze Age.

189 ux of Western steppe-related ancestry in the Bronze Age.

190 by extensive cultural interaction since the Bronze Age.

191 been present in the Ukraine region since the Bronze Age.

192 h a dramatic decrease in frequency after the Bronze Age.

193 r transition in dairying at the start of the Bronze Age.

194 for its early cultivation during the Middle Bronze Age.

195 ossil collecting in Greece began in the Late Bronze Age.

196 s across the Central Asian steppe during the Bronze Age.

197 of Eurasian steppe pastoralists by the Early Bronze Age.

198 s back their regional domestication into the Bronze Age.

199 es, in Southern Italy during the Middle/Late Bronze Age.

200 and the eastern Mediterranean after the Late Bronze Age.

201 ng after extensive exploitation in the Early Bronze Age.

202 pinned Eurasian tin exchange during the Late Bronze Age.

203 d economic transformations took place in the Bronze Age.

204 in Europe that signaled the beginning of the Bronze Age.

205 , inheritance rules, and mobility during the Bronze Age.

206 ovement across the mountain range during the Bronze Age.

207 thic and increased between the Neolithic and Bronze Age.

208 continuity in the Levant since at least the Bronze Age.

209 at the transition from the Neolithic to the Bronze Age.

210 ns from the Bell Beaker Complex to the Early Bronze Age.

211 y from the Pontic steppe at the onset of the Bronze Age.

212 istry-transport model, we show here that the Bronze-Age 'Minoan' eruption of Santorini Volcano releas

213 Urbanism in the Bronze-age Indus Civilisation ( 4.6-3.9 thousand years b

214 data, highlighting the critical role of post-Bronze-Age migrations into the region over the past 3,00

215 related ancestries, compatible with maritime Bronze-Age migrations.

216 The Neolithic and Bronze Ages were highly transformative periods for the g

217 composition of three ternary Cu-Sn-Pb model bronze alloys (lead bronzes: CuSn10Pb10, CuSn7Pb15, and

218 ntaneously sweep across the surface, leaving bronze alloys in their tracks.

219 hemical inhomogeneities in all three ternary bronze alloys with profound local deviations from their

220 tion of vertically vibrated mixtures of fine bronze and glass spheres of similar diameters.

221 However, when analyzed by year, Bronze and Hybrid articles received comparable citation

222 yields, from 13 Hungarian Neolithic, Copper, Bronze and Iron Age burials including two to high (~22 x

223 ee small, spouted vessels that were found in Bronze and Iron Age graves of infants in Bavaria.

224 from an ancestry pool like that found in the Bronze and Iron Age Levant.

225 losely related to modern Selkups and to some Bronze and Iron Age populations of the Altai region, wit

226 European Bronze and Iron Age vitrified hillforts have been known

227 y rose to appreciable frequencies during the Bronze and Iron Ages [2, 3], long after humans started c

228 ased mobility correspond geographically with Bronze and Iron Ages settlement patterns across the Tibe

229 ls from five archaeological sites across the Bronze and Iron Ages Southern Levant.

230 mic shifts with the advent of the Neolithic, Bronze and Iron Ages, with interleaved periods of genome

231 e detected during the transition between the Bronze and Iron Ages.

232 rk or intermediate skin colors well into the Bronze and Iron ages.

233 urope, and become more common throughout the Bronze and Iron Ages.

234 he first farmers followed by the adoption of bronze and then iron metallurgy leading on to the rise o

235 ucting the genetic history of the Neolithic, Bronze, and Iron Age populations of coastal northern Eas

236 es, organophosphorous pesticide and phosphor bronze, and the produced N2 might be collected and used

237 Bronze articles are selected at the publisher's discreti

238 Bronze articles received significantly more citations th

239 um (pea) mutants degenerate leaves (dgl) and bronze (brz) accumulate large amounts of iron in leaves.

240 The bronze bug, Thaumastocoris peregrinus, an Australian nat

241 debates on the electronic properties of blue bronzes but also provide a rare platform to study intere

242 The bronze (bz) gene is a recombinational hotspot in the mai

243 The bronze (bz) locus exhibits the highest rate of recombina

244 studying spontaneous mutations at the maize bronze (bz) locus, we made the unexpected discovery that

245 gous genetic intervals on either side of the bronze (bz) locus.

246 arried out extensive genetic analysis of the bronze (Bz) region in Zea mays using a W22 inbred line c

247 e harboring Ac in the 5' untranslated region bronze (bz).

248 host or transposon sequences produce stable bronze (bz-s) mutants.

249 Intricate ceramic bronze-casting moulds are among the most significant arc

250 icle size of the burial soil, in addition to bronze composition.

251 "Bronze" CPR, in which chest compression-only BLS is taug

252 n of existing and new data into 'gold-silver-bronze' criteria, allowing users to filter and query dep

253 d its specialist brood parasite, the shining bronze-cuckoo Chalcites lucidus in New Caledonia (Figure

254 The shining bronze-cuckoo is a specialist parasite of a few hosts in

255 e ternary Cu-Sn-Pb model bronze alloys (lead bronzes: CuSn10Pb10, CuSn7Pb15, and CuSn5Pb20), which we

256 ical reduction-yielding mixed-valence hybrid bronzes-diminishes the effect.

257 ts had pretibial venous stasis ulcers, 4 had bronze edema, 23 had both, and 17 had recurrent cellulit

258 se including pretibial venous stasis ulcers, bronze edema, and cellulitis.

259 sease, pretibial ulceration, cellulitis, and bronze edema.

260 on scanning tunneling microscopy reveal that bronze forms on the surface by a complicated, unanticipa

261 the original survives, including 30 corroded bronze gearwheels.

262 The in situ formed hydrogen tungsten bronze (H(x)WO(y)) phase via continuous hydrogen inserti

263 there was evidence that the lead phase in a bronze had melted.

264 The helmets, originally made in bronze, have maintained their original shape because of

265 ses involved in the total oxidation of roman bronze helmet metal.

266 he epidermis and dermis, and gave the skin a bronze hue.

267 nonetheless causes necrotic patches called "bronzing" in contact areas.

268 -ring chronology from the East Mediterranean Bronze-Iron Age.

269 ior tools to encourage entry into the copper-bronze-iron continuum of tool manufacture in other parts

270 eractions across the Adriatic Sea during the Bronze/Iron Age and a high level of individual mobility

271 Here it is shown that such bronzing is accompanied by cell death, which was quantif

272 red series of layered monophosphate tungsten bronzes (L-MPTB) [Ba(PO(4))(2)]W(m)O(3m-3) consist of m-

273 whereas the lower elites only had access to bronzes made by secondary alloying practice and copper w

274 een gold and silver medal in 40%, silver and bronze medal in 64%, and bronze or no medal in 61% of th

275 itions and compare the future performance of bronze medalists to those finishing just shy of the podi

276 rom dilute blue electrolytes to concentrated bronze metallic solutions.

277 By considering the chemical analysis of bronze objects within archaeological contexts, this pape

278 lief that all medals have been cast from the bronze of guns captured from the Russians at Sebastopol.

279 Nanowire hydrogen bronzes of WO(3) nanowires decorated with Pd (Pd/H(y)WO(

280 Brass and bronze on doorknobs can discourage microbial spread in h

281 in 40%, silver and bronze medal in 64%, and bronze or no medal in 61% of the finals.

282 n open access (OA) publishing system: Green, Bronze, or Hybrid.

283 sources at various degrees of consensus (532 bronze pairs, 527 silver pairs and 370 gold pairs).

284 city and rate performance of low-temperature bronze-phase TT- and T-polymorphs of Nb2O5 are inherent

285 itaxial growth of a strain-free, monoclinic, bronze-phase VO2(B) thin film on a perovskite SrTiO3 (ST

286 Median total spending was lower among bronze plan enrollees ($593; IQR, $28-$2100) vs platinum

287 idy cost of premiums for the least-expensive bronze plan for every county in the United States was ca

288 Compared with enrollees in bronze plans (17.2%), enrollees were more likely to be c

289 s much as or more than older individuals for bronze plans.

290 with artefact typology and uncorrelated with bronze preservation.

291 high elites such as Fuhao, particularly the bronze ritual vessels, were made by carefully controlled

292 For this purpose, bronze samples were directly ablated within an ablation

293 At higher frequencies, the bronze separates as a mid-height layer between upper and

294 etic data, and has the best performance on a bronze standard applied to real data.

295 CsNbW(2) O(9) , with the hexagonal tungsten bronze structure, is reported.

296 ly debated as a key factor for the spread of bronze technology and profound changes in burial practic

297 emarkably preserved as liquids inside sealed bronze vessels of the Shang and Western Zhou Dynasties.

298 tection of chromium traces on the surface of bronze weapons buried with the Chinese Terracotta Army,

299 e formation kinetics of the copper-tin alloy bronze when tin is deposited on the (111) surface of cop

300 octahedra, reminiscent of hexagonal tungsten bronzes, with planar Si6 rings enclosed within its hexag