Dataset related to the article: Stability of the D019 Chi (χ) and C14 laves phases in the γ-phase of chemically complex CoNi-base superalloys

This data set contains the following information related to the research article mentioned in the title: Fig.01: Origin file: DSC data for all ten alloys Fig.02: Origin file of Thermocalc data Fig.03: BSE images for the alloy γCo*-5Ni annealed at 800°C between 100 and 1500h Fig.04: Origin file: surface area fractions of all ten alloys after aging between 100 and 1500h Fig.05: BSE images of alloy series 2 aged for 1000h at 800°C and 900°C Fig.06: BSE images of alloy series 1 aged for 1000h between 800 and 1100 °C Fig.07-09_&_Fig.S10-S17: TEM data of two-phase alloys are sorted here by alloy series, aging temperature, and alloy name. All folders contain .jpg/.png/.dm3/.dm4 files. For each condition, we provide a microstructure overview. Additionally, diffraction patterns are labeled after the identified phases: FCC, Chi, G and C14 and the corresponding zone axes (ZA) Fig.10: Origin file showing the effect of composition on phase stability (pentagons) Supplementary: Fig.S1: Microstructure and phase analysis of γCo-5W from series 1 in the as-swaged state. FSD micrograph, indexed and unindexed Kikuchi patterns of the HCP and FCC phases appearing green and red in the EBSD phase map, respectively. Fig.S2: The corresponding BSE image can be found in Fig. 06 Fig.S3: XRD data for all ten alloys annealed at 800°C for 1000h Fig.S4: EDX elemental maps of the alloys with a reduced Ni content from both series. Here the Cr, Co, Ni and W maps correspond to the as-cast state Fig.S5: Five folders named after the alloys of series 2. EDX elemental maps for the elements Cr, Co, Ni and W in the as-cast state Fig.S6: Origin file comparing thermodynamic calculations performed with the TCNI10 database and another one developed for CrCoNiW. Here we show the molar fractions of phases as a function of temperature in alloy series 2 Fig.S7: Five folders named after the alloys of series 1. Each folder contains three BSE images of the alloy it is named after, annealed at 800°C for times of 100, 500 and 1000h Fig.S8: Five folders named after the alloys of series 2. Each folder contain 3 to 4 BSE images of samples annealed at 800°C between 100 and 1500h Fig.S9: Five folders named after the alloys of series 1. Each folder contains three BSE images of the alloy it is named after, annealed at 900°C for times of 100, 500 and 1000h.

本数据集包含与标题提及的研究论文相关的如下资料： 图01：原始数据文件——全部10种合金的差示扫描量热（Differential Scanning Calorimetry, DSC）数据 图02：Thermocalc原始数据文件 图03：γCo*-5Ni合金于800℃退火100~1500h后的背散射电子（Back Scattered Electron, BSE）成像图 图04：原始数据文件——全部10种合金经100~1500h时效处理后的表面积占比数据 图05：系列2合金分别于800℃、900℃时效1000h后的背散射电子成像图 图06：系列1合金于800~1100℃时效1000h后的背散射电子成像图 图07~09及补充图S10~S17：双相合金的透射电子显微镜（Transmission Electron Microscopy, TEM）数据，按合金系列、时效温度及合金名称分类整理。所有文件夹均包含.jpg、.png、.dm3及.dm4格式文件。针对每种实验条件，均提供显微组织全景图；此外，衍射花样已根据所鉴定的相完成标注：面心立方（Face-Centered Cubic, FCC）、χ相（Chi）、G相（G）及C14相，并标注了对应的晶带轴（Zone Axis, ZA） 图10：展示成分对相稳定性影响的原始数据文件（数据点以五边形表示） 补充材料： 补充图S1：系列1中γCo-5W合金锻造态的显微组织与相分析资料，包含前向散射探测器（Forward Scatter Detector, FSD）显微图像，以及电子背散射衍射（Electron Backscatter Diffraction, EBSD）相图中分别以绿色、红色标注的密排六方（Hexagonal Close-Packed, HCP）相与面心立方（FCC）相的标定与未标定菊池花样 补充图S2：对应的背散射电子成像图详见图06 补充图S3：全部10种合金于800℃退火1000h后的X射线衍射（X-ray Diffraction, XRD）数据 补充图S4：两个系列中镍含量降低的合金的能量色散X射线光谱（Energy Dispersive X-ray Spectroscopy, EDX）元素分布图，其中Cr、Co、Ni及W元素分布图对应铸态样品 补充图S5：以系列2合金命名的5个文件夹，内含铸态下Cr、Co、Ni及W元素的EDX元素分布图 补充图S6：对比使用TCNI10数据库与另一款专为CrCoNiW开发的数据库所开展的热力学计算的原始数据文件，本图展示了系列2合金中各相的摩尔分数随温度的变化关系 补充图S7：以系列1合金命名的5个文件夹，每个文件夹均包含对应合金于800℃退火100h、500h及1000h的3张背散射电子成像图 补充图S8：以系列2合金命名的5个文件夹，每个文件夹均包含对应样品于800℃退火100~1500h的3~4张背散射电子成像图 补充图S9：以系列1合金命名的5个文件夹，每个文件夹均包含对应合金于900℃退火100h、500h及1000h的3张背散射电子成像图