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Progress In Photovoltaics

Progress In PhotovoltaicsSCIE

国际简称:PROG PHOTOVOLTAICS  参考译名:光伏的进展

  • 中科院分区

    2区

  • CiteScore分区

    Q1

  • JCR分区

    Q1

基本信息:
ISSN:1062-7995
E-ISSN:1099-159X
是否OA:未开放
是否预警:否
TOP期刊:是
出版信息:
出版地区:ENGLAND
出版商:John Wiley and Sons Ltd
出版语言:English
出版周期:Bimonthly
出版年份:1993
研究方向:工程技术-能源与燃料
评价信息:
影响因子:8
H-index:115
CiteScore指数:18.1
SJR指数:1.992
SNIP指数:2.523
发文数据:
Gold OA文章占比:40.13%
研究类文章占比:96.47%
年发文量:85
自引率:0.0746...
开源占比:0.328
出版撤稿占比:0
出版国人文章占比:0.06
OA被引用占比:0.0860...
英文简介 期刊介绍 CiteScore数据 中科院SCI分区 JCR分区 发文数据 常见问题

英文简介Progress In Photovoltaics期刊介绍

Progress in Photovoltaics offers a prestigious forum for reporting advances in this rapidly developing technology, aiming to reach all interested professionals, researchers and energy policy-makers.

The key criterion is that all papers submitted should report substantial “progress” in photovoltaics.

Papers are encouraged that report substantial “progress” such as gains in independently certified solar cell efficiency, eligible for a new entry in the journal's widely referenced Solar Cell Efficiency Tables.

Examples of papers that will not be considered for publication are those that report development in materials without relation to data on cell performance, routine analysis, characterisation or modelling of cells or processing sequences, routine reports of system performance, improvements in electronic hardware design, or country programs, although invited papers may occasionally be solicited in these areas to capture accumulated “progress”.

期刊简介Progress In Photovoltaics期刊介绍

《Progress In Photovoltaics》自1993出版以来,是一本材料科学优秀杂志。致力于发表原创科学研究结果,并为材料科学各个领域的原创研究提供一个展示平台,以促进材料科学领域的的进步。该刊鼓励先进的、清晰的阐述,从广泛的视角提供当前感兴趣的研究主题的新见解,或审查多年来某个重要领域的所有重要发展。该期刊特色在于及时报道材料科学领域的最新进展和新发现新突破等。该刊近一年未被列入预警期刊名单,目前已被权威数据库SCIE收录,得到了广泛的认可。

该期刊投稿重要关注点:

Cite Score数据(2024年最新版)Progress In Photovoltaics Cite Score数据

  • CiteScore:18.1
  • SJR:1.992
  • SNIP:2.523
学科类别 分区 排名 百分位
大类:Physics and Astronomy 小类:Condensed Matter Physics Q1 9 / 434

98%

大类:Physics and Astronomy 小类:Electrical and Electronic Engineering Q1 28 / 797

96%

大类:Physics and Astronomy 小类:Electronic, Optical and Magnetic Materials Q1 17 / 284

94%

大类:Physics and Astronomy 小类:Renewable Energy, Sustainability and the Environment Q1 23 / 270

91%

CiteScore 是由Elsevier(爱思唯尔)推出的另一种评价期刊影响力的文献计量指标。反映出一家期刊近期发表论文的年篇均引用次数。CiteScore以Scopus数据库中收集的引文为基础,针对的是前四年发表的论文的引文。CiteScore的意义在于,它可以为学术界提供一种新的、更全面、更客观地评价期刊影响力的方法,而不仅仅是通过影响因子(IF)这一单一指标来评价。

历年Cite Score趋势图

中科院SCI分区Progress In Photovoltaics 中科院分区

中科院 2023年12月升级版 综述期刊:否 Top期刊:否
大类学科 分区 小类学科 分区
材料科学 2区 MATERIALS SCIENCE, MULTIDISCIPLINARY 材料科学:综合 PHYSICS, APPLIED 物理:应用 ENERGY & FUELS 能源与燃料 2区 2区 3区

中科院分区表 是以客观数据为基础,运用科学计量学方法对国际、国内学术期刊依据影响力进行等级划分的期刊评价标准。它为我国科研、教育机构的管理人员、科研工作者提供了一份评价国际学术期刊影响力的参考数据,得到了全国各地高校、科研机构的广泛认可。

中科院分区表 将所有期刊按照一定指标划分为1区、2区、3区、4区四个层次,类似于“优、良、及格”等。最开始,这个分区只是为了方便图书管理及图书情报领域的研究和期刊评估。之后中科院分区逐步发展成为了一种评价学术期刊质量的重要工具。

历年中科院分区趋势图

JCR分区Progress In Photovoltaics JCR分区

2023-2024 年最新版
按JIF指标学科分区 收录子集 分区 排名 百分位
学科:ENERGY & FUELS SCIE Q1 35 / 170

79.7%

学科:MATERIALS SCIENCE, MULTIDISCIPLINARY SCIE Q1 75 / 438

83%

学科:PHYSICS, APPLIED SCIE Q1 23 / 179

87.4%

按JCI指标学科分区 收录子集 分区 排名 百分位
学科:ENERGY & FUELS SCIE Q1 30 / 173

82.95%

学科:MATERIALS SCIENCE, MULTIDISCIPLINARY SCIE Q1 71 / 438

83.9%

学科:PHYSICS, APPLIED SCIE Q1 24 / 179

86.87%

JCR分区的优势在于它可以帮助读者对学术文献质量进行评估。不同学科的文章引用量可能存在较大的差异,此时单独依靠影响因子(IF)评价期刊的质量可能是存在一定问题的。因此,JCR将期刊按照学科门类和影响因子分为不同的分区,这样读者可以根据自己的研究领域和需求选择合适的期刊。

历年影响因子趋势图

发文数据

2023-2024 年国家/地区发文量统计
  • 国家/地区数量
  • GERMANY (FED REP GER)87
  • USA77
  • Japan54
  • Australia33
  • CHINA MAINLAND31
  • Italy29
  • Spain27
  • Netherlands23
  • France22
  • Switzerland19

本刊中国学者近年发表论文

  • 1、Techno-economic analysis of the use of atomic layer deposited transition metal oxides in silicon heterojunction solar cells

    Author: Chang, Nathan L.; Poduval, Geedhika K.; Sang, Borong; Khoo, Kean; Woodhouse, Michael; Qi, Fred; Dehghanimadvar, Mohammad; Li, Wei Min; Egan, Renate J.; Hoex, Bram

    Journal: PROGRESS IN PHOTOVOLTAICS. 2023; Vol. 31, Issue 4, pp. 414-428. DOI: 10.1002/pip.3553

  • 2、Tube-type plasma-enhanced atomic layer deposition of aluminum oxide: Enabling record lab performance for the industry with demonstrated cell efficiencies > 24%

    Author: Liao, Baochen; Wu, Xinyuan; Wu, Weiliang; Liu, Changming; Ma, Sheng; Wang, Shaozhou; Xie, Tong; Wang, Qiang; Du, Zheren; Shen, Wenzhong; Li, Xiang; Li, Weimin; Hoex, Bram

    Journal: PROGRESS IN PHOTOVOLTAICS. 2023; Vol. 31, Issue 1, pp. 52-61. DOI: 10.1002/pip.3607

  • 3、Mass production of crystalline silicon solar cells with polysilicon-based passivating contacts: An industrial perspective

    Author: Zhang, Xinyu; Dumbrell, Robert; Li, Wenqi; Xu, Menglei; Yan, Di; Jin, Jingsheng; Wang, Zhao; Zheng, Peiting; Liu, Changming; Yang, Jie

    Journal: PROGRESS IN PHOTOVOLTAICS. 2023; Vol. 31, Issue 4, pp. 369-379. DOI: 10.1002/pip.3618

  • 4、Atomic scale controlled tunnel oxide enabled by a novel industrial tube-based PEALD technology with demonstrated commercial TOPCon cell efficiencies > 24%

    Author: Liao, Baochen; Wu, Weiliang; Yeo, Reuben J.; Wu, Xinyuan; Ma, Sheng; Wang, Qiang; Wan, Yimao; Su, Xiaodong; Shen, Wenzhong; Li, Xiang; Li, Weimin; Xing, Guoqiang; Hoex, Bram

    Journal: PROGRESS IN PHOTOVOLTAICS. 2023; Vol. 31, Issue 3, pp. 220-229. DOI: 10.1002/pip.3627

  • 5、Interlaboratory comparison of voltage sweep methods used for the electrical characterization of encapsulated high-efficiency c-Si solar cells

    Author: Zhang, Yating; Monokroussos, Christos; Wilterdink, Harrison; Mullejans, Harald; Pavanello, Diego; Yoshita, Masahiro; Yamagoe, Kengo; Ramspeck, Klaus; Hinken, David; Bothe, Karsten; Fujita, Yuji; Arnoux, Gilles; Pinto, Filipe; Ambigapathy, Rajesh; Gao, Qi; Shi, Qiang; Chen, Yi Feng; Ping, Yan

    Journal: PROGRESS IN PHOTOVOLTAICS. 2023; Vol. 31, Issue 3, pp. 237-250. DOI: 10.1002/pip.3630

  • 6、Achievement of 25.54% power conversion efficiency by optimization of current losses at the front side of silicon heterojunction solar cells

    Author: Tang, Tianwei; Yu, Cao; Peng, Chen-Wei; Dong, Gangqiang; He, Chenran; Ran, Xiaochao; Jiang, Hao; Allen, Vince; Cao, Xinmin; Zhou, Jian

    Journal: PROGRESS IN PHOTOVOLTAICS. 2023; Vol. 31, Issue 5, pp. 449-460. DOI: 10.1002/pip.3641

  • 7、High-performance perovskite/silicon heterojunction solar cells enabled by industrially compatible postannealing

    Author: Wang, Guangyi; Yue, Zongyi; Huang, Zengguang; Liu, Wenzhu; Tong, Rui; Yin, Haipeng; Yang, Lifei; Yu, Fucheng; Zhang, Yuanyuan; Sun, Zongyang; Zhong, Sihua

    Journal: PROGRESS IN PHOTOVOLTAICS. 2023; Vol. , Issue , pp. -. DOI: 10.1002/pip.3696

  • 8、Highly efficient silicon heterojunction solar cells with ZnO:Al transparent electrode and transition metal doped indium oxide interfacial layer

    Author: Dong, Gangqiang; Li, Jia; Zhao, Yu; Ran, Xiaochao; Peng, Chen-Wei; He, Daliang; Jin, Chuanhong; Wang, Qi; Jiang, Hao; Zhang, Yongsheng; Cao, Xinmin; Yu, Cao

    Journal: PROGRESS IN PHOTOVOLTAICS. 2023; Vol. , Issue , pp. -. DOI: 10.1002/pip.3697

投稿常见问题

通讯方式:JOHN WILEY & SONS LTD, THE ATRIUM, SOUTHERN GATE, CHICHESTER, ENGLAND, W SUSSEX, PO19 8SQ。