Transactions of Tianjin University
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SCImago
Q1
WOS
Q1
Impact factor
6.7
SJR
1.502
CiteScore
12.5
Categories
Multidisciplinary
Areas
Multidisciplinary
Years of issue
2004-2025
journal names
Transactions of Tianjin University
T TIANJIN U
Top-3 citing journals

Transactions of Tianjin University
(334 citations)

International Journal of Hydrogen Energy
(220 citations)

Energies
(97 citations)
Top-3 organizations

Tianjin University
(745 publications)

Dalian University of Technology
(33 publications)

Tianjin University
(77 publications)

University of Chinese Academy of Sciences
(9 publications)
Most cited in 5 years
Found
Publications found: 119

Insights into Microsporidia Evolution from Early Diverging Microsporidia
Corsaro D.
Microsporidia have drastically modified genomes and cytology resulting from their high level of adaptation to intracytoplasmic parasitism. Their origins, which had long remained enigmatic, were placed within the line of Rozella, a primitive endoparasitic chytrid. These origins became more and more refined with the discovery of various parasites morphologically similar to the primitive lines of microsporidia (Metchnikovellids and Chytridiopsids) but which possess fungal-like genomes and functional mitochondria. These various parasites turn out to be distinct missing links between a large assemblage of chytrid-like rozellids and the true microsporidians, which are actually a very evolved branch of the rozellids themselves. The question of how to consider the historically known Microsporidia and the various microsporidia-like organisms within paraphyletic rozellids is discussed.

Factors That Determine Microsporidia Infection and Host Specificity
Willis A.R., Reinke A.W.
Microsporidia are a large phylum of obligate intracellular parasites that infect an extremely diverse range of animals and protists. In this chapter, we review what is currently known about microsporidia host specificity and what factors influence microsporidia infection. Extensive sampling in nature from related hosts has provided insight into the host range of many microsporidia species. These field studies have been supported by experiments conducted in controlled laboratory environments which have helped to demonstrate host specificity. Together, these approaches have revealed that, while examples of generalist species exist, microsporidia specificity is often narrow, and species typically infect one or several closely related hosts. For microsporidia to successfully infect and complete their life cycle within a compatible host, several steps must occur, including spore germination, host cell invasion, and proliferation of the parasite within the host tissue. Many factors influence infection, including temperature, seasonality, nutrient availability, and the presence or absence of microbes, as well as the developmental stage, sex, and genetics of the host. Several studies have identified host genomic regions that influence resistance to microsporidia, and future work is likely to uncover molecular mechanisms of microsporidia host specificity in more detail.

Comparative Genomics of Microsporidia
Williams B.A., Williams T.A., Trew J.
The microsporidia are a phylum of intracellular parasites that represent the eukaryotic cell in a state of extreme reduction, with genomes and metabolic capabilities embodying eukaryotic cells in arguably their most streamlined state. Over the past 20 years, microsporidian genomics has become a rapidly expanding field starting with sequencing of the genome of Encephalitozoon cuniculi, one of the first ever sequenced eukaryotes, to the current situation where we have access to the data from over 30 genomes across 20+ genera. Reaching back further in evolutionary history, to the point where microsporidia diverged from other eukaryotic lineages, we now also have genomic data for some of the closest known relatives of the microsporidia such as Rozella allomycis, Metchnikovella spp. and Amphiamblys sp. Data for these organisms allow us to better understand the genomic processes that shaped the emergence of the microsporidia as a group. These intensive genomic efforts have revealed some of the processes that have shaped microsporidian cells and genomes including patterns of genome expansions and contractions through gene gain and loss, whole genome duplication, differential patterns of invasion and purging of transposable elements. All these processes have been shown to occur across short and longer time scales to give rise to a phylum of parasites with dynamic genomes with a diversity of sizes and organisations.

Microsporidia
Experientia supplementum (2012)
,
2022
,
citations by CoLab: 10


Impact of Genome Reduction in Microsporidia
Jespersen N., Monrroy L., Barandun J.
AbstractMicrosporidia represent an evolutionary outlier in the tree of life and occupy the extreme edge of the eukaryotic domain with some of their biological features. Many of these unicellular fungi-like organisms have reduced their genomic content to potentially the lowest limit. With some of the most compacted eukaryotic genomes, microsporidia are excellent model organisms to study reductive evolution and its functional consequences. While the growing number of sequenced microsporidian genomes have elucidated genome composition and organization, a recent increase in complementary post-genomic studies has started to shed light on the impacts of genome reduction in these unique pathogens. This chapter will discuss the biological framework enabling genome minimization and will use one of the most ancient and essential macromolecular complexes, the ribosome, to illustrate the effects of extreme genome reduction on a structural, molecular, and cellular level. We outline how reductive evolution in microsporidia has shaped DNA organization, the composition and function of the ribosome, and the complexity of the ribosome biogenesis process. Studying compacted mechanisms, processes, or macromolecular machines in microsporidia illuminates their unique lifestyle and provides valuable insights for comparative eukaryotic structural biology.

Microsporidian Pathogens of Aquatic Animals
Bojko J., Stentiford G.D.
Around 57.1% of microsporidia occupy aquatic environments, excluding a further 25.7% that utilise both terrestrial and aquatic systems. The aquatic microsporidia therefore compose the most diverse elements of the Microsporidia phylum, boasting unique structural features, variable transmission pathways, and significant ecological influence. From deep oceans to tropical rivers, these parasites are present in most aquatic environments and have been shown to infect hosts from across the Protozoa and Animalia. The consequences of infection range from mortality to intricate behavioural change, and their presence in aquatic communities often alters the overall functioning of the ecosystem. In this chapter, we explore aquatic microsporidian diversity from the perspective of aquatic animal health. Examples of microsporidian parasitism of importance to an aquacultural (‘One Health’) context and ecosystem context are focussed upon. These include infection of commercially important penaeid shrimp by Enterocytozoon hepatopenaei and interesting hyperparasitic microsporidians of wild host groups. Out of ~1500 suggested microsporidian species, 202 have been adequately taxonomically described using a combination of ultrastructural and genetic techniques from aquatic and semi-aquatic hosts. These species are our primary focus, and we suggest that the remaining diversity have additional genetic or morphological data collected to formalise their underlying systematics.

Insights from C. elegans into Microsporidia Biology and Host-Pathogen Relationships
Tecle E., Troemel E.R.
Microsporidia are poorly understood, ubiquitous eukaryotic parasites that are completely dependent on their hosts for replication. With the discovery of microsporidia species naturally infecting the genetically tractable transparent nematode C. elegans, this host has been used to explore multiple areas of microsporidia biology. Here we review results about microsporidia infections in C. elegans, which began with the discovery of the intestinal-infecting species Nematocida parisii. Recent findings include new species identification in the Nematocida genus, with more intestinal-infecting species, and also a species with broader tissue tropism, the epidermal and muscle-infecting species Nematocida displodere. This species has a longer polar tube infection apparatus, which may enable its wider tissue range. After invasion, multiple Nematocida species appear to fuse host cells, which likely promotes their dissemination within host organs. Localized proteomics identified Nematocida proteins that have direct contact with the C. elegans intestinal cytosol and nucleus, and many of these host-exposed proteins belong to expanded, species-specific gene families. On the host side, forward genetic screens have identified regulators of the Intracellular Pathogen Response (IPR), which is a transcriptional response induced by both microsporidia and the Orsay virus, which is also a natural, obligate intracellular pathogen of the C. elegans intestine. The IPR constitutes a novel immune/stress response that promotes resistance against microsporidia, virus, and heat shock. Overall, the Nematocida/C. elegans system has provided insights about strategies for microsporidia pathogenesis, as well as innate defense pathways against these parasites.

The Function and Structure of the Microsporidia Polar Tube
Han B., Takvorian P.M., Weiss L.M.
Microsporidia are obligate intracellular pathogens that were initially identified about 160 years ago. Current phylogenetic analysis suggests that they are grouped with Cryptomycota as a basal branch or sister group to the fungi. Microsporidia are found worldwide and can infect a wide range of animals from invertebrates to vertebrates, including humans. They are responsible for a variety of diseases once thought to be restricted to immunocompromised patients but also occur in immunocompetent individuals. The small oval spore containing a coiled polar filament, which is part of the extrusion and invasion apparatus that transfers the infective sporoplasm to a new host, is a defining characteristic of all microsporidia. When the spore becomes activated, the polar filament uncoils and undergoes a rapid transition into a hollow tube that will transport the sporoplasm into a new cell. The polar tube has the ability to increase its diameter from approximately 100 nm to over 600 nm to accommodate the passage of an intact sporoplasm and penetrate the plasmalemma of the new host cell. During this process, various polar tube proteins appear to be involved in polar tube attachment to host cell and can interact with host proteins. These various interactions act to promote host cell infection.

Chronic Infections in Mammals Due to Microsporidia
Sak B., Kváč M.
Microsporidia are pathogenic organism related to fungi. They cause infections in a wide variety of mammals as well as in avian, amphibian, and reptilian hosts. Many microsporidia species play an important role in the development of serious diseases that have significant implications in human and veterinary medicine. While microsporidia were originally considered to be opportunistic pathogens in humans, it is now understood that infections also occur in immune competent humans. Encephalitozoon cuniculi, Encephalitozoon intestinalis, and Enterocytozoon bieneusi are primarily mammalian pathogens. However, many other species of microsporidia that have some other primary host that is not a mammal have been reported to cause sporadic mammalian infections. Experimental models and observations in natural infections have demonstrated that microsporidia can cause a latent infection in mammalian hosts. This chapter reviews the published studies on mammalian microsporidiosis and the data on chronic infections due to these enigmatic pathogens.

Immune Response to Microsporidia
Moretto M.M., Khan I.A.
Microsporidia are a group of pathogens, which can pose severe risks to the immunocompromised population, such as HIV-infected individuals or organ transplant recipients. Adaptive immunity has been reported to be critical for protection, and mice depleted of T cells are unable to control these infections. In a mouse model of infection, CD8 T cells have been found to be the primary effector cells and are responsible for protecting the infected host. Also, as infection is acquired via a peroral route, CD8 T cells in the gut compartment act as a first line of defense against these pathogens. Thus, generation of a robust CD8 T-cell response exhibiting polyfunctional ability is critical for host survival. In this chapter, we describe the effector CD8 T cells generated during microsporidia infection and the factors that may be essential for generating protective immunity against these understudied but significant pathogens. Overall, this chapter will highlight the necessity for a better understanding of the development of CD8 T-cell responses in gut-associated lymphoid tissue (GALT) and provide some insights into therapies that may be used to restore defective CD8 T-cell functionality in an immunocompromised situation.

Mechanics of Microsporidian Polar Tube Firing
Jaroenlak P., Usmani M., Ekiert D.C., Bhabha G.
As obligate intracellular parasites with reduced genomes, microsporidia must infect host cells in order to replicate and cause disease. They can initiate infection by utilizing a harpoon-like invasion organelle called the polar tube (PT). The PT is both visually and functionally a striking organelle and is a characteristic feature of the microsporidian phylum. Outside the host, microsporidia exist as transmissible, single-celled spores. Inside each spore, the PT is arranged as a tight coil. Upon germination, the PT undergoes a large conformational change into a long, linear tube and acts as a tunnel for the delivery of infectious cargo from the spore to a host cell. The firing process is extremely rapid, occurring on a millisecond timescale, and the emergent tube may be as long as 20 times the size of the spore body. In this chapter, we discuss what is known about the structure of the PT, the mechanics of the PT firing process, and how it enables movement of material from the spore body.

Recent Advances with Fish Microsporidia
Schuster C.J., Sanders J.L., Couch C., Kent M.L.
There have been several significant new findings regarding Microsporidia of fishes over the last decade. Here we provide an update on new taxa, new hosts and new diseases in captive and wild fishes since 2013. The importance of microsporidiosis continues to increase with the rapid growth of finfish aquaculture and the dramatic increase in the use of zebrafish as a model in biomedical research. In addition to reviewing new taxa and microsporidian diseases, we include discussions on advances with diagnostic methods, impacts of microsporidia on fish beyond morbidity and mortality, novel findings with transmission and invertebrate hosts, and a summary of the phylogenetics of fish microsporidia.

A Perspective on the Molecular Identification, Classification, and Epidemiology of Enterocytozoon bieneusi of Animals
Koehler A.V., Zhang Y., Gasser R.B.
The microsporidian Enterocytozoon bieneusi is an obligate intracellular pathogen that causes enteric disease (microsporidiosis) in humans and has been recorded in a wide range of animal species worldwide. The transmission of E. bieneusi is direct and likely occurs from person to person and from animal to person via the ingestion of spores in water, food, or the environment. The identification of E. bieneusi is usually accomplished by molecular means, typically using the sequence of the internal transcribed spacer (ITS) region of nuclear ribosomal DNA. Currently, ~820 distinct genotypes of E. bieneusi have been recorded in at least 210 species of vertebrates (mammals, birds, reptiles, and amphibians) or invertebrates (insects and mussels) in more than 50 countries. In this chapter, we provide a perspective on (1) clinical aspects of human microsporidiosis; (2) the genome and DNA markers for E. bieneusi as well as molecular methods for the specific and genotypic identification of E. bieneusi; (3) epidemiological aspects of E. bieneusi of animals and humans, with an emphasis on the genotypes proposed to be zoonotic, human-specific, and animal-specific; and (4) future research directions to underpin expanded molecular studies to better understand E. bieneusi and microsporidiosis.

Advances in the Genetic Manipulation of Nosema bombycis
Li T., Wei J., Pan G.
The microsporidium Nosema bombycis can infect and transmit both vertically and horizontally in multiple lepidopteran insects including silkworms and crop pests. While there have been several studies on the N. bombycis spore, there have been only limited studies on the N. bombycis sporoplasm. This chapter reviews what is known about this life cycle stage as well as published studies on purification of the N. bombycis sporoplasm and its survival in an in vitro cell culture system. Genetic transformation techniques have revolutionized the study of many pathogenic organisms. While progress has been made on the development of such systems for microsporidia, this critical problem has not been solved for these pathogens. This chapter provides a summary of the latest research progress on genetic manipulation of N. bombycis.

Nosema apis and N. ceranae Infection in Honey bees: A Model for Host-Pathogen Interactions in Insects
Snow J.W.
There has been increased focus on the role of microbial attack as a potential cause of recent declines in the health of the western honey bee, Apis mellifera. The Nosema species, N. apis and N. ceranae, are microsporidian parasites that are pathogenic to honey bees, and infection by these species has been implicated as a key factor in honey bee losses. Honey bees infected with both Nosema spp. display significant changes in their biology at the cellular, tissue, and organismal levels impacting host metabolism, immune function, physiology, and behavior. Infected individuals lead to colony dysfunction and can contribute to colony disease in some circumstances. The means through which parasite growth and tissue pathology in the midgut lead to the dramatic physiological and behavioral changes at the organismal level are only partially understood. In addition, we possess only a limited appreciation of the elements of the host environment that impact pathogen growth and development. Critical for answering these questions is a mechanistic understanding of the host and pathogen machinery responsible for host-pathogen interactions. A number of approaches are already being used to elucidate these mechanisms, and promising new tools may allow for gain- and loss-of-function experiments to accelerate future progress.
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2 citations, 0.03%
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|
Water Environment Federation
2 citations, 0.03%
|
|
Acta Physica Sinica, Chinese Physical Society and Institute of Physics, Chinese Academy of Sciences
2 citations, 0.03%
|
|
Argentinean Association of Computational Mechanics
2 citations, 0.03%
|
|
Optical Society of India
2 citations, 0.03%
|
|
Beilstein-Institut
2 citations, 0.03%
|
|
Asian Journal of Chemistry
2 citations, 0.03%
|
|
Alexandria University
2 citations, 0.03%
|
|
Science Alert
2 citations, 0.03%
|
|
The Russian Academy of Sciences
2 citations, 0.03%
|
|
SciELO
2 citations, 0.03%
|
|
Institute of Research and Community Services Diponegoro University (LPPM UNDIP)
2 citations, 0.03%
|
|
Show all (70 more) | |
500
1000
1500
2000
2500
|
Publishing organizations
100
200
300
400
500
600
700
800
|
|
Tianjin University
745 publications, 67.06%
|
|
Collaborative Innovation Center of Chemical Science and Engineering Tianjin
75 publications, 6.75%
|
|
Dalian University of Technology
33 publications, 2.97%
|
|
Harbin Institute of Technology
27 publications, 2.43%
|
|
Nankai University
24 publications, 2.16%
|
|
University of Chinese Academy of Sciences
18 publications, 1.62%
|
|
Nanyang Technological University
17 publications, 1.53%
|
|
Beijing University of Chemical Technology
13 publications, 1.17%
|
|
Hebei University of Technology
13 publications, 1.17%
|
|
Beijing Institute of Technology
12 publications, 1.08%
|
|
Shandong University
12 publications, 1.08%
|
|
Tsinghua University
11 publications, 0.99%
|
|
Tiangong University
10 publications, 0.9%
|
|
Huazhong University of Science and Technology
9 publications, 0.81%
|
|
Tongji University
9 publications, 0.81%
|
|
East China University of Science and Technology
9 publications, 0.81%
|
|
Zhejiang University
8 publications, 0.72%
|
|
Nanjing University of Aeronautics and Astronautics
8 publications, 0.72%
|
|
Xidian University
8 publications, 0.72%
|
|
Tianjin University of Science and Technology
8 publications, 0.72%
|
|
Dalian Institute of Chemical Physics, Chinese Academy of Sciences
8 publications, 0.72%
|
|
Shanghai Jiao Tong University
7 publications, 0.63%
|
|
Fuzhou University
7 publications, 0.63%
|
|
Beijing Jiaotong University
7 publications, 0.63%
|
|
Tianjin Chengjian University
7 publications, 0.63%
|
|
Beihang University
6 publications, 0.54%
|
|
Tianjin University of Technology
6 publications, 0.54%
|
|
Shenyang Jianzhu University
6 publications, 0.54%
|
|
South China University of Technology
5 publications, 0.45%
|
|
China University of Mining and Technology
5 publications, 0.45%
|
|
Wuhan University
5 publications, 0.45%
|
|
Tianjin University of Commerce
5 publications, 0.45%
|
|
Civil Aviation University of China
5 publications, 0.45%
|
|
Hohai University
5 publications, 0.45%
|
|
University of California, Merced
5 publications, 0.45%
|
|
Tibet University
5 publications, 0.45%
|
|
PLA Army Engineering University
5 publications, 0.45%
|
|
University of Alberta
5 publications, 0.45%
|
|
Xi'an Jiaotong University
4 publications, 0.36%
|
|
Southeast University
4 publications, 0.36%
|
|
Beijing University of Technology
4 publications, 0.36%
|
|
Hebei University of Science and Technology
4 publications, 0.36%
|
|
Tianjin Medical University
4 publications, 0.36%
|
|
China Three Gorges University
4 publications, 0.36%
|
|
University of Western Australia
4 publications, 0.36%
|
|
University of Adelaide
4 publications, 0.36%
|
|
Arizona State University
4 publications, 0.36%
|
|
Sichuan University
3 publications, 0.27%
|
|
Jilin University
3 publications, 0.27%
|
|
Beijing University of Posts and Telecommunications
3 publications, 0.27%
|
|
China University of Petroleum (East China)
3 publications, 0.27%
|
|
Northeastern University
3 publications, 0.27%
|
|
China Agricultural University
3 publications, 0.27%
|
|
University of Science and Technology Beijing
3 publications, 0.27%
|
|
Nanchang University
3 publications, 0.27%
|
|
Shihezi University
3 publications, 0.27%
|
|
Shenzhen University
3 publications, 0.27%
|
|
Norwegian University of Science and Technology
3 publications, 0.27%
|
|
Tianjin University of Technology and Education
3 publications, 0.27%
|
|
Tianjin Agricultural University
3 publications, 0.27%
|
|
Shanghai Normal University
3 publications, 0.27%
|
|
Soochow University (Suzhou)
3 publications, 0.27%
|
|
Southern University of Science and Technology
3 publications, 0.27%
|
|
University of Manchester
3 publications, 0.27%
|
|
Northeast Forestry University
3 publications, 0.27%
|
|
Heilongjiang University
3 publications, 0.27%
|
|
Shandong University of Technology
3 publications, 0.27%
|
|
University of Hong Kong
3 publications, 0.27%
|
|
Tohoku University
3 publications, 0.27%
|
|
University of Science and Technology of China
3 publications, 0.27%
|
|
Agency for Science, Technology and Research
3 publications, 0.27%
|
|
Xinjiang University
3 publications, 0.27%
|
|
Boreskov Institute of Catalysis of the Siberian Branch of the Russian Academy of Sciences
2 publications, 0.18%
|
|
Ioffe Physical-Technical Institute of the Russian Academy of Sciences
2 publications, 0.18%
|
|
Saint Petersburg State University
2 publications, 0.18%
|
|
Northwestern Polytechnical University
2 publications, 0.18%
|
|
Central South University
2 publications, 0.18%
|
|
Fujian Normal University
2 publications, 0.18%
|
|
Nanjing University of Science and Technology
2 publications, 0.18%
|
|
Nanjing Tech University
2 publications, 0.18%
|
|
Beijing University of Civil Engineering and Architecture
2 publications, 0.18%
|
|
Shandong University of Science and Technology
2 publications, 0.18%
|
|
Chongqing University
2 publications, 0.18%
|
|
Hebei Normal University
2 publications, 0.18%
|
|
North China Electric Power University
2 publications, 0.18%
|
|
Ocean University of China
2 publications, 0.18%
|
|
Taiyuan University of Technology
2 publications, 0.18%
|
|
Shandong Normal University
2 publications, 0.18%
|
|
Inner Mongolia University of Technology
2 publications, 0.18%
|
|
ShanghaiTech University
2 publications, 0.18%
|
|
Shanghai University
2 publications, 0.18%
|
|
Florida State University
2 publications, 0.18%
|
|
National University of Singapore
2 publications, 0.18%
|
|
Southwest Petroleum University
2 publications, 0.18%
|
|
Dalian Jiaotong University
2 publications, 0.18%
|
|
Shenyang Pharmaceutical University
2 publications, 0.18%
|
|
Liaoning Technical University
2 publications, 0.18%
|
|
Guizhou University
2 publications, 0.18%
|
|
Northwest University
2 publications, 0.18%
|
|
Ludong University
2 publications, 0.18%
|
|
Show all (70 more) | |
100
200
300
400
500
600
700
800
|
Publishing organizations in 5 years
10
20
30
40
50
60
70
80
|
|
Tianjin University
77 publications, 40.1%
|
|
Collaborative Innovation Center of Chemical Science and Engineering Tianjin
25 publications, 13.02%
|
|
University of Chinese Academy of Sciences
9 publications, 4.69%
|
|
Nanyang Technological University
8 publications, 4.17%
|
|
Dalian Institute of Chemical Physics, Chinese Academy of Sciences
8 publications, 4.17%
|
|
Beijing University of Chemical Technology
6 publications, 3.13%
|
|
Nankai University
6 publications, 3.13%
|
|
Beijing Institute of Technology
3 publications, 1.56%
|
|
Huazhong University of Science and Technology
3 publications, 1.56%
|
|
East China University of Science and Technology
3 publications, 1.56%
|
|
Shanghai Normal University
3 publications, 1.56%
|
|
Soochow University (Suzhou)
3 publications, 1.56%
|
|
Southern University of Science and Technology
3 publications, 1.56%
|
|
Agency for Science, Technology and Research
3 publications, 1.56%
|
|
Boreskov Institute of Catalysis of the Siberian Branch of the Russian Academy of Sciences
2 publications, 1.04%
|
|
Ioffe Physical-Technical Institute of the Russian Academy of Sciences
2 publications, 1.04%
|
|
Tsinghua University
2 publications, 1.04%
|
|
Shanghai Jiao Tong University
2 publications, 1.04%
|
|
Harbin Institute of Technology
2 publications, 1.04%
|
|
South China University of Technology
2 publications, 1.04%
|
|
Beihang University
2 publications, 1.04%
|
|
Xi'an Jiaotong University
2 publications, 1.04%
|
|
Fujian Normal University
2 publications, 1.04%
|
|
Nanjing University of Science and Technology
2 publications, 1.04%
|
|
Nanjing Tech University
2 publications, 1.04%
|
|
Beijing University of Technology
2 publications, 1.04%
|
|
China University of Petroleum (East China)
2 publications, 1.04%
|
|
Hebei University of Science and Technology
2 publications, 1.04%
|
|
Taiyuan University of Technology
2 publications, 1.04%
|
|
China Three Gorges University
2 publications, 1.04%
|
|
National University of Singapore
2 publications, 1.04%
|
|
Ningbo University
2 publications, 1.04%
|
|
City University of Hong Kong
2 publications, 1.04%
|
|
Tohoku University
2 publications, 1.04%
|
|
Institute of Chemistry, Chinese Academy of Sciences
2 publications, 1.04%
|
|
University of Science and Technology of China
2 publications, 1.04%
|
|
Southern Illinois University Carbondale
2 publications, 1.04%
|
|
Ningxia University
2 publications, 1.04%
|
|
Nikolaev Institute of Inorganic Chemistry of the Siberian Branch of the Russian Academy of Sciences
1 publication, 0.52%
|
|
Novosibirsk State University
1 publication, 0.52%
|
|
Tomsk State University
1 publication, 0.52%
|
|
National Research Centre "Kurchatov Institute"
1 publication, 0.52%
|
|
Moscow Power Engineering Institute
1 publication, 0.52%
|
|
Al Farabi Kazakh National University
1 publication, 0.52%
|
|
Kazakh-British Technical University
1 publication, 0.52%
|
|
Almaty University of Power Engineering and Telecommunications
1 publication, 0.52%
|
|
Combustion Problems Institute
1 publication, 0.52%
|
|
New Uzbekistan University
1 publication, 0.52%
|
|
Tashkent State Pedagogical University named after Nizami
1 publication, 0.52%
|
|
King Abdullah University of Science and Technology
1 publication, 0.52%
|
|
King Fahd University of Petroleum and Minerals
1 publication, 0.52%
|
|
Prince Mohammad Bin Fahd University
1 publication, 0.52%
|
|
Jadavpur University
1 publication, 0.52%
|
|
Zhejiang University of Science and Technology
1 publication, 0.52%
|
|
Jain University
1 publication, 0.52%
|
|
Tongji University
1 publication, 0.52%
|
|
Jilin University
1 publication, 0.52%
|
|
Dalian University of Technology
1 publication, 0.52%
|
|
China University of Mining and Technology
1 publication, 0.52%
|
|
KTH Royal Institute of Technology
1 publication, 0.52%
|
|
Fuzhou University
1 publication, 0.52%
|
|
Nanjing Agricultural University
1 publication, 0.52%
|
|
China University of Geosciences (Wuhan)
1 publication, 0.52%
|
|
Beijing Forestry University
1 publication, 0.52%
|
|
Wuhan University of Technology
1 publication, 0.52%
|
|
Wuhan Institute of Technology
1 publication, 0.52%
|
|
Hubei University
1 publication, 0.52%
|
|
Technische Universität Dresden
1 publication, 0.52%
|
|
Northeastern University
1 publication, 0.52%
|
|
South China Agricultural University
1 publication, 0.52%
|
|
University of Science and Technology Beijing
1 publication, 0.52%
|
|
Al-Hussein Bin Talal University
1 publication, 0.52%
|
|
Shaanxi Normal University
1 publication, 0.52%
|
|
Nanchang University
1 publication, 0.52%
|
|
Northeast Normal University
1 publication, 0.52%
|
|
Shihezi University
1 publication, 0.52%
|
|
Shenzhen University
1 publication, 0.52%
|
|
University College London
1 publication, 0.52%
|
|
National Institute for Materials Science
1 publication, 0.52%
|
|
Norwegian University of Science and Technology
1 publication, 0.52%
|
|
Tianjin University of Technology and Education
1 publication, 0.52%
|
|
Tianjin University of Technology
1 publication, 0.52%
|
|
Tiangong University
1 publication, 0.52%
|
|
Inner Mongolia University of Technology
1 publication, 0.52%
|
|
ShanghaiTech University
1 publication, 0.52%
|
|
Shanghai University
1 publication, 0.52%
|
|
Second Military Medical University
1 publication, 0.52%
|
|
Jiangsu University
1 publication, 0.52%
|
|
Yangzhou University
1 publication, 0.52%
|
|
Guangzhou University
1 publication, 0.52%
|
|
Southwest Petroleum University
1 publication, 0.52%
|
|
Dalian Jiaotong University
1 publication, 0.52%
|
|
University of South China
1 publication, 0.52%
|
|
Anhui Normal University
1 publication, 0.52%
|
|
Hefei Normal University
1 publication, 0.52%
|
|
Huangshan University
1 publication, 0.52%
|
|
Northeast Forestry University
1 publication, 0.52%
|
|
Heilongjiang University
1 publication, 0.52%
|
|
North Minzu University
1 publication, 0.52%
|
|
Qingdao University of Science and Technology
1 publication, 0.52%
|
|
Show all (70 more) | |
10
20
30
40
50
60
70
80
|
Publishing countries
200
400
600
800
1000
1200
|
|
China
|
China, 1060, 95.41%
China
1060 publications, 95.41%
|
USA
|
USA, 30, 2.7%
USA
30 publications, 2.7%
|
Singapore
|
Singapore, 21, 1.89%
Singapore
21 publications, 1.89%
|
Australia
|
Australia, 15, 1.35%
Australia
15 publications, 1.35%
|
United Kingdom
|
United Kingdom, 10, 0.9%
United Kingdom
10 publications, 0.9%
|
Canada
|
Canada, 10, 0.9%
Canada
10 publications, 0.9%
|
Japan
|
Japan, 9, 0.81%
Japan
9 publications, 0.81%
|
Russia
|
Russia, 6, 0.54%
Russia
6 publications, 0.54%
|
Germany
|
Germany, 4, 0.36%
Germany
4 publications, 0.36%
|
Republic of Korea
|
Republic of Korea, 4, 0.36%
Republic of Korea
4 publications, 0.36%
|
France
|
France, 3, 0.27%
France
3 publications, 0.27%
|
India
|
India, 3, 0.27%
India
3 publications, 0.27%
|
Norway
|
Norway, 3, 0.27%
Norway
3 publications, 0.27%
|
New Zealand
|
New Zealand, 2, 0.18%
New Zealand
2 publications, 0.18%
|
Saudi Arabia
|
Saudi Arabia, 2, 0.18%
Saudi Arabia
2 publications, 0.18%
|
Kazakhstan
|
Kazakhstan, 1, 0.09%
Kazakhstan
1 publication, 0.09%
|
Austria
|
Austria, 1, 0.09%
Austria
1 publication, 0.09%
|
Denmark
|
Denmark, 1, 0.09%
Denmark
1 publication, 0.09%
|
Egypt
|
Egypt, 1, 0.09%
Egypt
1 publication, 0.09%
|
Indonesia
|
Indonesia, 1, 0.09%
Indonesia
1 publication, 0.09%
|
Jordan
|
Jordan, 1, 0.09%
Jordan
1 publication, 0.09%
|
North Korea
|
North Korea, 1, 0.09%
North Korea
1 publication, 0.09%
|
Morocco
|
Morocco, 1, 0.09%
Morocco
1 publication, 0.09%
|
Nigeria
|
Nigeria, 1, 0.09%
Nigeria
1 publication, 0.09%
|
Netherlands
|
Netherlands, 1, 0.09%
Netherlands
1 publication, 0.09%
|
Pakistan
|
Pakistan, 1, 0.09%
Pakistan
1 publication, 0.09%
|
Uzbekistan
|
Uzbekistan, 1, 0.09%
Uzbekistan
1 publication, 0.09%
|
Sweden
|
Sweden, 1, 0.09%
Sweden
1 publication, 0.09%
|
South Africa
|
South Africa, 1, 0.09%
South Africa
1 publication, 0.09%
|
200
400
600
800
1000
1200
|
Publishing countries in 5 years
20
40
60
80
100
120
140
160
180
|
|
China
|
China, 161, 83.85%
China
161 publications, 83.85%
|
Singapore
|
Singapore, 9, 4.69%
Singapore
9 publications, 4.69%
|
Japan
|
Japan, 4, 2.08%
Japan
4 publications, 2.08%
|
Russia
|
Russia, 3, 1.56%
Russia
3 publications, 1.56%
|
USA
|
USA, 3, 1.56%
USA
3 publications, 1.56%
|
United Kingdom
|
United Kingdom, 2, 1.04%
United Kingdom
2 publications, 1.04%
|
India
|
India, 2, 1.04%
India
2 publications, 1.04%
|
Republic of Korea
|
Republic of Korea, 2, 1.04%
Republic of Korea
2 publications, 1.04%
|
Saudi Arabia
|
Saudi Arabia, 2, 1.04%
Saudi Arabia
2 publications, 1.04%
|
Germany
|
Germany, 1, 0.52%
Germany
1 publication, 0.52%
|
Kazakhstan
|
Kazakhstan, 1, 0.52%
Kazakhstan
1 publication, 0.52%
|
Australia
|
Australia, 1, 0.52%
Australia
1 publication, 0.52%
|
Egypt
|
Egypt, 1, 0.52%
Egypt
1 publication, 0.52%
|
Indonesia
|
Indonesia, 1, 0.52%
Indonesia
1 publication, 0.52%
|
Jordan
|
Jordan, 1, 0.52%
Jordan
1 publication, 0.52%
|
Canada
|
Canada, 1, 0.52%
Canada
1 publication, 0.52%
|
Morocco
|
Morocco, 1, 0.52%
Morocco
1 publication, 0.52%
|
Nigeria
|
Nigeria, 1, 0.52%
Nigeria
1 publication, 0.52%
|
New Zealand
|
New Zealand, 1, 0.52%
New Zealand
1 publication, 0.52%
|
Norway
|
Norway, 1, 0.52%
Norway
1 publication, 0.52%
|
Pakistan
|
Pakistan, 1, 0.52%
Pakistan
1 publication, 0.52%
|
Uzbekistan
|
Uzbekistan, 1, 0.52%
Uzbekistan
1 publication, 0.52%
|
Sweden
|
Sweden, 1, 0.52%
Sweden
1 publication, 0.52%
|
South Africa
|
South Africa, 1, 0.52%
South Africa
1 publication, 0.52%
|
20
40
60
80
100
120
140
160
180
|
1 profile journal article
Trigub Alexander
PhD in Physics and Mathematics

National Research Centre "Kurchatov Institute"
175 publications,
1 946 citations
h-index: 26
Research interests
X-ray absorption spectroscopy
1 profile journal article
Kurenkova Anna

Boreskov Institute of Catalysis of the Siberian Branch of the Russian Academy of Sciences
40 publications,
492 citations
h-index: 12