{"currentpage":1,"firstResult":0,"maxresult":10,"pagecode":5,"pageindex":{"endPagecode":5,"startPagecode":1},"records":[{"abstractinfo":"本文采用KOH:H2O=3:20～1:25(质量比)的KOH溶液,对Si基外延GaN进行湿法腐蚀.腐蚀后用扫描电子显微镜(SEM)观察,GaN面出现了六角腐蚀坑,它是外延层中的位错露头,密度约108/cm2.腐蚀坑的密度随腐蚀时间延长而增加,说明GaN外延生长过程中位错密度是逐渐降低的,部分位错因相互作用而终止于GaN体内.观察缺陷腐蚀形貌还发现,接近裂纹处腐蚀坑的密度要高于远离裂纹处腐蚀坑的密度,围绕裂纹有许多由裂纹引起的位错.腐蚀坑的密度可以很好地反映GaN晶体的质量.晶体质量较差的GaN片,腐蚀后其六角腐蚀坑的密度高.","authors":[{"authorName":"赵丽伟","id":"dbd36344-bb02-4170-9a09-22ce53879e32","originalAuthorName":"赵丽伟"},{"authorName":"刘彩池","id":"d566ab68-3842-490b-a007-b60efd79e21f","originalAuthorName":"刘彩池"},{"authorName":"滕晓云","id":"adacd881-bd16-4c94-b689-74b7c2a03b7c","originalAuthorName":"滕晓云"},{"authorName":"朱军山","id":"4526e2ee-a0d5-4540-8721-383c0ca432ec","originalAuthorName":"朱军山"},{"authorName":"郝秋艳","id":"4fa5dd2e-f8fe-4574-abb4-61823355f724","originalAuthorName":"郝秋艳"},{"authorName":"孙世龙","id":"6296dfe3-c9d3-4ec6-9439-c7ec26c1c7cb","originalAuthorName":"孙世龙"},{"authorName":"王海云","id":"6003e10c-8da0-4bde-bef5-6481e2a16f19","originalAuthorName":"王海云"},{"authorName":"徐岳生","id":"944e7a6b-59a9-43ab-b1c7-18314d06c968","originalAuthorName":"徐岳生"},{"authorName":"<span style=\"color:red\">胡</span><span style=\"color:red\">家</span><span style=\"color:red\">辉</span>","id":"3fee9090-9bfe-471c-88bc-c5180fdb414e","originalAuthorName":"胡家辉"},{"authorName":"冯玉春","id":"7efefe94-57a5-4751-a2a2-316c9c874cfc","originalAuthorName":"冯玉春"},{"authorName":"郭宝平","id":"0a5d36e3-bbff-4afa-a5dc-84df9ad3f43e","originalAuthorName":"郭宝平"}],"doi":"10.3969/j.issn.1000-985X.2005.06.019","fpage":"1079","id":"4ba359d3-b11a-41ef-b0d0-caee670fe09e","issue":"6","journal":{"abbrevTitle":"RGJTXB","coverImgSrc":"journal/img/cover/RGJTXB.jpg","id":"57","issnPpub":"1000-985X","publisherId":"RGJTXB","title":"人工晶体学报"},"keywords":[{"id":"c1601069-8f39-4055-86d1-e3abc2e12d13","keyword":"GaN","originalKeyword":"GaN"},{"id":"04cda761-de1f-4c68-8bfb-1d08ebb2969d","keyword":"湿法腐蚀","originalKeyword":"湿法腐蚀"},{"id":"52c8a8ab-a2cb-47e7-9156-af2df04ee8ac","keyword":"六角腐蚀坑","originalKeyword":"六角腐蚀坑"},{"id":"5fdebcc9-5556-4e3d-a316-638c50b60d29","keyword":"SEM","originalKeyword":"SEM"}],"language":"zh","publisherId":"rgjtxb98200506019","title":"Si基外延GaN中缺陷的腐蚀研究","volume":"34","year":"2005"},{"abstractinfo":"<span style=\"color:red\">胡</span><span style=\"color:red\">家</span>峪铜矿床大地构造位置处于华北克拉通中部造山带南缘的中条山地区，矿床主要赋存于古元古界中条群篦子沟组含碳片岩、不纯大理岩和硅质钠长岩等岩石中，次为余家山组白云石大理岩中。对矿区内的含矿岩系进行了全岩地球化学测试分析，主量元素特征表明矿区内的含矿岩系均表现出富镁、富铝的特征；微量元素特征显示，所有样品均呈现出Nb、Ta、Ti负异常的现象，显示出与俯冲带岩浆地球化学类似的特征；稀土元素特征显示出一定程度的轻重稀土分馏，轻稀土富集，所有样品都表现出不同程度的铕负异常，表明这些含矿岩系形成于还原沉积环境中。研究认为，<span style=\"color:red\">胡</span><span style=\"color:red\">家</span>峪铜矿床的成矿构造背景为俯冲后形成的弧后盆地；容矿岩石与国内典型热水喷流矿床相比，在地球化学特征方面有一定相似之处。因此，<span style=\"color:red\">胡</span><span style=\"color:red\">家</span>峪铜矿床应为热水喷流沉积矿床。","authors":[{"authorName":"王子维","id":"ad0e6313-d4d6-4dc0-abbc-371068f119b9","originalAuthorName":"王子维"},{"authorName":"杨言辰","id":"fa6e5af9-31d8-4d28-b1af-18d546d8ab54","originalAuthorName":"杨言辰"},{"authorName":"韩世炯","id":"b700d724-a8a3-4d42-b26b-454049959c36","originalAuthorName":"韩世炯"},{"authorName":"张国宾","id":"517404e2-1f0d-4776-82dd-6ba27096d546","originalAuthorName":"张国宾"}],"doi":"10.11792/hj20140306","fpage":"26","id":"96823248-4ad8-4d6d-ab8a-555c99566f98","issue":"3","journal":{"abbrevTitle":"HJ","coverImgSrc":"journal/img/cover/HJ.jpg","id":"44","issnPpub":"1001-1277","publisherId":"HJ","title":"黄金"},"keywords":[{"id":"603922d4-cc44-4fda-bb47-6823130fa04c","keyword":"中条山","originalKeyword":"中条山"},{"id":"bf949b0b-54a2-4d58-9ff5-6002214136b9","keyword":"<span style=\"color:red\">胡</span><span style=\"color:red\">家</span>峪铜矿床","originalKeyword":"胡家峪铜矿床"},{"id":"8c83c06b-9063-4f0b-9086-cf4fe1f30f43","keyword":"地球化学","originalKeyword":"地球化学"},{"id":"df2e6d76-c8a2-4b84-8264-265ce7b71582","keyword":"热水喷流沉积矿床","originalKeyword":"热水喷流沉积矿床"}],"language":"zh","publisherId":"huangj201403006","title":"中条山<span style=\"color:red\">胡</span><span style=\"color:red\">家</span>峪铜矿区含矿岩系的地球化学特征及其地质意义","volume":"","year":"2014"},{"abstractinfo":"通过对采油五厂<span style=\"color:red\">胡</span>五块生产系统腐蚀因素调查,摸清了<span style=\"color:red\">胡</span>五块腐蚀原因是产出液中Cl-,HCO3等强腐蚀性离子含量高,同时含有一定量的CO2(最高达4.68％),并含硫酸盐还原菌(SRB),从而形成弱酸性腐蚀水体.经向套管中注入KY-2高效缓性剂(加药浓度100 mg·L-1)后,腐蚀速率由0.0970mm·a-1降为0.0215 mm·a-1,总铁值由38.1 mg·L-1降为16.5 mg·L-1,治理后减少腐蚀作业5井次,取得较好的防腐蚀效果.","authors":[{"authorName":"丁其杰","id":"a726fd07-29b8-44e9-ad8c-d794e8cb40ae","originalAuthorName":"丁其杰"},{"authorName":"韩长喜","id":"2c7adb72-966b-4311-a324-a94a65656839","originalAuthorName":"韩长喜"},{"authorName":"刘生福","id":"026bb2ca-5601-4bfc-aa8a-2903be33cf2d","originalAuthorName":"刘生福"},{"authorName":"王红","id":"05eabf3b-9623-41fa-9353-e57398dcce5e","originalAuthorName":"王红"},{"authorName":"陈慧丽","id":"aaacc03d-0bd4-4484-a79e-40b2463bcaed","originalAuthorName":"陈慧丽"}],"doi":"","fpage":"430","id":"fa6b50c5-fc8d-4a34-a988-1e2286e3384c","issue":"5","journal":{"abbrevTitle":"FSYFH","coverImgSrc":"journal/img/cover/FSYFH.jpg","id":"25","issnPpub":"1005-748X","publisherId":"FSYFH","title":"腐蚀与防护"},"keywords":[{"id":"250af674-c501-4552-8164-351206ec28e3","keyword":"腐蚀因素","originalKeyword":"腐蚀因素"},{"id":"81d7048b-390a-4926-89a3-c9872eea4a80","keyword":"缓蚀剂","originalKeyword":"缓蚀剂"},{"id":"77f74e64-8796-4b22-967c-efb512d794a0","keyword":"综合治理","originalKeyword":"综合治理"},{"id":"967ef120-eb87-4f34-9e38-4738fdf733cd","keyword":"现场试验","originalKeyword":"现场试验"},{"id":"29e68cf8-1da8-4fdc-9ec1-3214dedc76c1","keyword":"采油五厂","originalKeyword":"采油五厂"}],"language":"zh","publisherId":"fsyfh201305016","title":"KY-2缓蚀剂在采油五厂<span style=\"color:red\">胡</span>七南块的应用","volume":"34","year":"2013"},{"abstractinfo":"随着纳米碳管(CNTs)的广泛应用,其不可避免地进入环境中,天然有机质与CNTs的相互作用增大了CNTs的分散性,可能带来更大的环境风险.本研究系统考察了溶解<span style=\"color:red\">胡</span>敏酸(HA)对CNTs的悬浮效果,发现随着悬浮次数的增加,HA的累积吸附量不断增大,而CNTs的悬浮量先增加后减少,表明CNTs确实存在分级悬浮的现象.通过透射电子显微镜和热重分析对高悬浮量和低悬浮量的CNTs进行表征发现,高悬浮量的CNTs相比低悬浮量的CNTs短且碎,说明具有较多缺陷的CNTs可能是易悬浮的部分;尽管高悬浮量的CNTs对HA的累积吸附量较低,但其较早的出现了明显的失重平台,具有较差的热稳定性.两方面的证据可以证实CNTs自身性质的差异是其分级悬浮的控制性因素.","authors":[{"authorName":"魏超贤","id":"763376ea-2448-4547-bac0-80ec19040b45","originalAuthorName":"魏超贤"},{"authorName":"张凰","id":"ef50f9b4-3744-4d99-aff6-7857b144cd2f","originalAuthorName":"张凰"},{"authorName":"张迪","id":"f0acfb07-9e5a-49d8-972c-708411258223","originalAuthorName":"张迪"},{"authorName":"杨晓磊","id":"26d8c99a-9cf5-4743-b0c8-db29854a74c7","originalAuthorName":"杨晓磊"}],"doi":"","fpage":"252","id":"2fdfda36-fcce-4a68-8dc3-514fcd180646","issue":"3","journal":{"abbrevTitle":"XXTCL","coverImgSrc":"journal/img/cover/XXTCL.jpg","id":"70","issnPpub":"1007-8827","publisherId":"XXTCL","title":"新型炭材料"},"keywords":[{"id":"f89293b1-e366-47f8-a046-b5e210588eae","keyword":"纳米碳管","originalKeyword":"纳米碳管"},{"id":"78e1c012-4a87-4723-8c61-4e467c003f4f","keyword":"分级悬浮","originalKeyword":"分级悬浮"},{"id":"dc55b4c3-889e-4ad6-92cd-f67e6d1c6dd1","keyword":"透射电镜","originalKeyword":"透射电镜"},{"id":"45aafcc6-3606-4cac-a8ad-f1ba1624c673","keyword":"热重分析","originalKeyword":"热重分析"}],"language":"zh","publisherId":"xxtcl201703009","title":"纳米碳管在<span style=\"color:red\">胡</span>敏酸中的分级悬浮","volume":"32","year":"2017"},{"abstractinfo":"多环芳烃(Polycyclic aromatic hydrocarbons,PAHs)对人类健康和生态环境的危害近年来备受关注,有关PAHs在DOM上吸附特征的研究已有大量报道.但DOM构成成分的复杂性给PAHs与DOM相互作用的研究工作带来了困难.将DOM分离为不同化学结构和元素组成的组分,并分析其不同组分对与PAHs相互作用的具体贡献十分必要.本研究利用离子交换树脂将<span style=\"color:red\">胡</span>敏酸(Humic acid,HA)按照疏水性和酸碱性分离为不同组分,使用透析平衡法确定不同结构的HA与菲(PHE)的结合平衡常数,并对结合后样品进行傅里叶变换红外光谱(FTIR)分析.结果显示,HA组分中的极性和脂肪族含量对PHE在HA上的结合有重要影响和不同的贡献机制.疏水性HA组分对PHE的结合亲和力高于亲水性HA组分,疏水性中性组分(HoN)与PHE之间的结合系数最高,亲水性酸性组分(HiA)对PHE在HA上的结合贡献最少,HoN对PHE的环境风险有重要影响.研究中首次通过对结合前后不同有机质组分的FTIR光谱图的对比分析,进一步证明脂肪族是HA中与PHE发生相互作用的主要组分.","authors":[{"authorName":"王琳","id":"3b5d9548-8ed4-4ed5-b54f-af24076c50a3","originalAuthorName":"王琳"},{"authorName":"田路萍","id":"86da6f16-d4ee-4f52-ae3b-ed9d04e3474b","originalAuthorName":"田路萍"},{"authorName":"李芳芳","id":"9301c727-eac8-41eb-9725-93815d4544f4","originalAuthorName":"李芳芳"},{"authorName":"吴敏","id":"0e8d96c3-ac49-464c-99d0-fab5e90c650f","originalAuthorName":"吴敏"}],"doi":"10.7524/j.issn.0254-6108.2017.04.2016081902","fpage":"745","id":"36c3ac72-435d-418a-9603-812a691f5498","issue":"4","journal":{"abbrevTitle":"HJHX","coverImgSrc":"journal/img/cover/HJHX.jpg","id":"43","issnPpub":"0254-6108","publisherId":"HJHX","title":"环境化学   "},"keywords":[{"id":"6eda2fbc-7c54-4623-a99f-09a8ba85cf46","keyword":"<span style=\"color:red\">胡</span>敏酸","originalKeyword":"胡敏酸"},{"id":"d67dac65-54a9-48da-83d6-48f58000ab11","keyword":"离子交换树脂","originalKeyword":"离子交换树脂"},{"id":"729c4a44-5d7a-469e-aab0-9c4186a9a22d","keyword":"多环芳烃","originalKeyword":"多环芳烃"},{"id":"4cc7df56-04ee-465a-8b48-4d85935568d3","keyword":"吸附","originalKeyword":"吸附"},{"id":"9dcb7c53-fecd-4935-884d-6e1a9e28d7e4","keyword":"疏水性中性组分(HoN)","originalKeyword":"疏水性中性组分(HoN)"}],"language":"zh","publisherId":"hjhx201704008","title":"脂肪族在不同组分<span style=\"color:red\">胡</span>敏酸与菲结合中的作用","volume":"36","year":"2017"},{"abstractinfo":"现代<span style=\"color:red\">家</span>纺设计在我国起步较晚水平较低,如何使我国家纺设计尽快适应迅速发展的我国家纺行业,是我们面临的重大课题.该文从消费需求趋势、品牌演变趋势、渠道模式趋势、终端创新趋势等方面进行探讨,以期对家纺企业有所帮助.","authors":[{"authorName":"严瑛","id":"a9d7358a-9ca5-4b86-bc16-55eee34cfd71","originalAuthorName":"严瑛"}],"doi":"","fpage":"134","id":"b5d1dd3b-d1fa-4b8b-a79e-23f321c26026","issue":"5","journal":{"abbrevTitle":"HCCLLHYYY","coverImgSrc":"journal/img/cover/HCCLLHYYY.jpg","id":"42","issnPpub":"1671-5381","publisherId":"HCCLLHYYY","title":"合成材料老化与应用"},"keywords":[{"id":"c5f297be-da42-458d-be40-65ee3b69957e","keyword":"<span style=\"color:red\">家</span>纺","originalKeyword":"家纺"},{"id":"67b6f43e-ac8c-4281-b59f-880b333936a1","keyword":"发展","originalKeyword":"发展"},{"id":"41d05b0a-e37b-4f2a-a1c9-f7e856c6dfff","keyword":"趋势","originalKeyword":"趋势"}],"language":"zh","publisherId":"hccllhyyy201505030","title":"<span style=\"color:red\">家</span>纺发展趋势探讨","volume":"44","year":"2015"},{"abstractinfo":"研究了63～292K热力学过冷度范围内,Cu-Ni单相合金的凝固组织演化规律,分析了负温度梯度熔体凝固过程中的形核与再<span style=\"color:red\">辉</span>行为.结果表明:①负温度梯度熔体凝固的冷却曲线上有较明显的形核特征;②在负温度梯度熔体凝固冷却曲线的快速再<span style=\"color:red\">辉</span>阶段,出现了明显的\"二次再<span style=\"color:red\">辉</span>\"特征,此\"二次再<span style=\"color:red\">辉</span>\"的本质有别于慢速凝固阶段的二次再<span style=\"color:red\">辉</span>,因此称之为\"伪再<span style=\"color:red\">辉</span>\".","authors":[{"authorName":"谢发勤","id":"3672eb10-df5a-4adf-a355-5a9a22970f8c","originalAuthorName":"谢发勤"},{"authorName":"吴向清","id":"4af11c6e-f6a4-4ee3-9e70-67a3797729b9","originalAuthorName":"吴向清"},{"authorName":"李金山","id":"b3b47a9e-a454-464a-856d-b1c0e61a3b2a","originalAuthorName":"李金山"},{"authorName":"傅恒志","id":"9e66bae0-ad73-4072-bf10-051df6cff6ea","originalAuthorName":"傅恒志"}],"doi":"","fpage":"56","id":"31311933-6aba-4817-b91e-079f4fc6961e","issue":"8","journal":{"abbrevTitle":"CLDB","coverImgSrc":"journal/img/cover/CLDB.jpg","id":"8","issnPpub":"1005-023X","publisherId":"CLDB","title":"材料导报"},"keywords":[{"id":"54e3abde-157f-4893-859d-5ac0b92aad38","keyword":"负温度梯度","originalKeyword":"负温度梯度"},{"id":"1e2e4f6b-c3f1-4b06-9b42-37fbf90e8a39","keyword":"过冷度","originalKeyword":"过冷度"},{"id":"9e7cdbba-c927-4e48-bbf3-795ffadb9a68","keyword":"过冷凝固","originalKeyword":"过冷凝固"},{"id":"8c8a6cfa-b529-4d04-abce-0911c39385bf","keyword":"再<span style=\"color:red\">辉</span>","originalKeyword":"再辉"}],"language":"zh","publisherId":"cldb200408017","title":"负温度梯度熔体凝固过程中的形核与再<span style=\"color:red\">辉</span>行为","volume":"18","year":"2004"},{"abstractinfo":"用双<span style=\"color:red\">辉</span>等离子表面冶金技术在Q235钢表面制备Ta改性层。用XRD，SEM，EDS，电化学腐蚀和中性盐雾试验分析Ta改性层的组织特征、成分和耐蚀性能。结果表明，Ta改性层与基体结合良好，厚度为32μm左右。改性层中Ta元素含量呈梯度分布，主要物相为α-Ta。双<span style=\"color:red\">辉</span>等离子表面渗Ta处理后试样的耐蚀性明显优于基材。","authors":[{"authorName":"毕强","id":"6ff8f36d-bc5a-402c-8585-0d75ecb4d544","originalAuthorName":"毕强"},{"authorName":"张平则","id":"d9e5115f-a621-41e5-bca9-a139697985bb","originalAuthorName":"张平则"},{"authorName":"黄俊","id":"9b8a5858-161d-481b-a7db-2d828193beb7","originalAuthorName":"黄俊"},{"authorName":"魏东博","id":"6fa56b9e-c8a8-4902-9189-407e85908135","originalAuthorName":"魏东博"},{"authorName":"李伟","id":"7d15e3d5-801c-4d17-8662-5ebc03e5235c","originalAuthorName":"李伟"}],"doi":"","fpage":"364","id":"04788188-da9c-4551-9ce5-307cce18d599","issue":"5","journal":{"abbrevTitle":"ZGFSYFHXB","coverImgSrc":"journal/img/cover/中国腐蚀封面19-3期-01.jpg","id":"81","issnPpub":"1005-4537","publisherId":"ZGFSYFHXB","title":"中国腐蚀与防护学报"},"keywords":[{"id":"bcdcdc5b-61fe-4e91-a577-6578116364b9","keyword":"双<span style=\"color:red\">辉</span>等离子表面冶金","originalKeyword":"双辉等离子表面冶金"},{"id":"4cecf85c-db80-4d52-9ff4-ebbb734a3b6b","keyword":"Ta改性层","originalKeyword":"Ta改性层"},{"id":"bd813d52-e9c4-47d2-be5c-0a58c68941af","keyword":"极化曲线","originalKeyword":"极化曲线"},{"id":"34c2818d-db06-494c-92e2-faa8f2e4a186","keyword":"电化学阻抗","originalKeyword":"电化学阻抗"},{"id":"329923ef-2fa5-43cf-a5ab-97c303b14a5c","keyword":"中性盐雾试验","originalKeyword":"中性盐雾试验"},{"id":"701db2ad-9c56-44d5-ab06-232402e61e2a","keyword":"抗腐蚀性","originalKeyword":"抗腐蚀性"}],"language":"zh","publisherId":"zgfsyfhxb201205002","title":"双<span style=\"color:red\">辉</span>等离子渗Ta改性层的组织及耐蚀性","volume":"32","year":"2012"},{"abstractinfo":"用双<span style=\"color:red\">辉</span>等离子表面冶金技术在Q235钢表面制备Ta改性层。用XRD，SEM，EDS，电化学腐蚀和中性盐雾试验分析Ta改性层的组织特征、成分和耐蚀性能。结果表明，Ta改性层与基体结合良好，厚度为32μm左右。改性层中Ta元素含量呈梯度分布，主要物相为α-Ta。双<span style=\"color:red\">辉</span>等离子表面渗Ta处理后试样的耐蚀性明显优于基材。","authors":[{"authorName":"毕强","id":"9cd16206-821d-442e-942f-0ecb0c01e166","originalAuthorName":"毕强"},{"authorName":"张平则","id":"1e1cb97a-32e5-4dfb-825d-ce3708e895d5","originalAuthorName":"张平则"},{"authorName":"黄俊","id":"9c454803-c8b2-47b7-bd32-557abc6da0e7","originalAuthorName":"黄俊"},{"authorName":"魏东博","id":"4ce093c9-3b45-4e41-9d2b-90371a44df00","originalAuthorName":"魏东博"},{"authorName":"李伟","id":"ede451be-6288-4af7-bbd5-34b39441e6f1","originalAuthorName":"李伟"}],"doi":"","fpage":"364","id":"79872c24-24c8-4cad-bd0c-d18238fc5ad4","issue":"5","journal":{"abbrevTitle":"ZGFSYFHXB","coverImgSrc":"journal/img/cover/中国腐蚀封面19-3期-01.jpg","id":"81","issnPpub":"1005-4537","publisherId":"ZGFSYFHXB","title":"中国腐蚀与防护学报"},"keywords":[{"id":"3e43295e-63e5-42c9-94ca-1dff2e0e60a3","keyword":"双<span style=\"color:red\">辉</span>等离子表面冶金","originalKeyword":"双辉等离子表面冶金"},{"id":"feb07ee5-e864-40c4-8b6d-407482a1dbc3","keyword":"Ta改性层","originalKeyword":"Ta改性层"},{"id":"1a4f0e47-0ae1-45d8-8d25-394918cf19fe","keyword":"极化曲线","originalKeyword":"极化曲线"},{"id":"9742a349-5143-4a9e-a56c-de7dc4b7b945","keyword":"电化学阻抗","originalKeyword":"电化学阻抗"},{"id":"576efea6-346b-41ef-9f2a-7a828ae90779","keyword":"中性盐雾试验","originalKeyword":"中性盐雾试验"},{"id":"8fa24d50-9bd3-4294-acd9-406af82eafc8","keyword":"抗腐蚀性","originalKeyword":"抗腐蚀性"}],"language":"zh","publisherId":"zgfsyfhxb201205002","title":"双<span style=\"color:red\">辉</span>等离子渗Ta改性层的组织及耐蚀性","volume":"32","year":"2012"},{"abstractinfo":"马虎沟测区位于灵北断裂带下盘,区内主干断裂为前孙<span style=\"color:red\">家</span>—洼孙<span style=\"color:red\">家</span>断裂,发育似斑状郭家岭型花岗闪长岩和玲珑型片麻状黑云母花岗岩. 本次地表构造地球化学测量范围约15 km2 ,采集构造地球化学样品共858件,测试元素包括Au、Ni、Pb、Co、Mo、Sn、Zn、Ti、Cr、As、Sb、Hg、Ag、Cu、Ba、Bi、B、Mn、V等19种. Au元素异常沿前孙<span style=\"color:red\">家</span>—洼孙<span style=\"color:red\">家</span>断裂带及次级断裂分布特征明显. 分形分维统计表明,Au具有多阶段成矿的特征. 结合多元统计分析,厘定本测区构造地球化学异常找矿标志为Au-Pb-Bi元素组合异常及因子得分Y(i,2)和Y(i,3)异常. 结合地质分析,圈定找矿靶区5处.","authors":[{"authorName":"祝涛","id":"d87cfdbb-d220-4cb9-8426-f320167f9456","originalAuthorName":"祝涛"},{"authorName":"杨斌","id":"1d417931-fdd7-42e2-9013-b63c775244b0","originalAuthorName":"杨斌"}],"doi":"10.11792/hj20160103","fpage":"9","id":"a5cda7a4-a416-4d7a-a1fe-6ba6019f42a3","issue":"1","journal":{"abbrevTitle":"HJ","coverImgSrc":"journal/img/cover/HJ.jpg","id":"44","issnPpub":"1001-1277","publisherId":"HJ","title":"黄金"},"keywords":[{"id":"d52aaa44-4bef-429b-abb6-5fb51c9e7876","keyword":"找矿预测","originalKeyword":"找矿预测"},{"id":"ba34116e-33b4-4e40-b1a4-18c7f3563a5e","keyword":"构造地球化学","originalKeyword":"构造地球化学"},{"id":"bc66191e-c1c4-431b-beee-3c43a947083a","keyword":"多元统计分析","originalKeyword":"多元统计分析"},{"id":"bd626c5c-05ff-4c78-a90c-4eb7ed36e1c4","keyword":"前孙<span style=\"color:red\">家</span>—洼孙<span style=\"color:red\">家</span>断裂带","originalKeyword":"前孙家—洼孙家断裂带"}],"language":"zh","publisherId":"huangj201601003","title":"胶西北前孙<span style=\"color:red\">家</span>—洼孙<span style=\"color:red\">家</span>断裂带构造地球化学找矿预测","volume":"37","year":"2016"}],"totalpage":42,"totalrecord":412}