Formation of hexagonal-molybdenum trioxide (h-MoO3) nanostructures and their pseudocapacitive behavior
文献情報
出版日
2015-06-24
DOI
10.1039/C5NR01505G
インパクトファクター
7.79
著者
Vipin Kumar, Xu Wang, Pooi See Lee
原文を見る
要旨
The crystallographic structure and morphology of redox active transition metal oxides have a pronounced effect on their electrochemical properties. In this work, h-MoO3 nanostructures with three distinct morphologies, i.e., pyramidal nanorod, prismatic nanorod and hexagonal nanoplate, were synthesized by a facile solvothermal method. The morphologies of h-MoO3 nanostructures were tailored by a controlled amount of hexamethylenetetramine. An enhanced specific capacitance about 230 F g−1 at an applied current density of 0.25 A g−1 was achieved in h-MoO3 pyramidal nanorods. Electrochemical studies confirmed that the h-MoO3 pyramidal nanorods exhibit superior charge-storage ability. This improved performance can be ascribed to the coexistence of its well exposed crystallographic planes with abundant active sites, i.e., hexagonal window (HW), trigonal cavity (TC) and four-coordinated square window (SW). The mechanism of charge-storage is likely facilitated by the vehicle mechanism of proton transportation due to the availability of the vehicles, i.e., NH4+ and H2O. The promising, distinct and unexploited features of h-MoO3 nanostructures reveal a strong candidate for pseudocapacitive electrode materials.
関連文献
Wet-chemical approach for the halogenation of hydrogenated boron-doped diamond electrodes
Manash R. Das, Vera G. Praig, Francois LeNormand, Musen Li, Rabah Boukherroub
2008-10-22
Communication
DOI: 10.1039/B810975C
Reversible colorimetric ion sensors based on surface initiated polymerization of photochromic polymers
Kristen Fries, Satyabrata Samanta, Sara Orski, Jason Locklin
2008-11-04
Communication
DOI: 10.1039/B818042C
Selective dimerization of 1,6-diynes catalyzed by ionic liquid-supported nickel complexes in an ionic liquid/toluene biphasic system
Avijit Goswami, Taichi Ito, Naoko Saino, Kouki Kase, Chikashi Matsuno, Sentaro Okamoto
2008-11-18
Communication
DOI: 10.1039/B816850D
Preparation of a self-standing mesoporous carbon membrane with perpendicularly-ordered pore structures
Ken’ichi Kimijima, Akari Hayashi, Ichizo Yagi
2008-10-01
Communication
DOI: 10.1039/B812982G
Facile photoinduced charge separation through a cyanoacetylide bridge in a heterobimetallic Fe(ii)–Re(i) complex
Mark E. Smith, Emma L. Flynn, Mark A. Fox, Alexandre Trottier, Eckart Wrede, Dmitri S. Yufit, Judith A. K. Howard, Kate L. Ronayne, Michael Towrie, Anthony W. Parker, František Hartl, Paul J. Low
2008-10-07
Communication
DOI: 10.1039/B811357B
Supported ATRP of fluorinated methacrylates in supercritical carbon dioxide: preparation of scCO2 soluble polymers with low catalytic residues
Bruno Grignard, Cédric Calberg, Christine Jérôme, Wenxin Wang, Steven Howdle, Christophe Detrembleur
2008-10-01
Communication
DOI: 10.1039/B812297K
A palladium-mediated cascade cyclisation approach to the CDE cores of rubriflordilactone A and lancifodilactone G‡
Marie-Caroline A. Cordonnier, S. B. Jennifer Kan
2008-10-02
Communication
DOI: 10.1039/B814360A
Phase transition and conductive acceleration of phosphonium-cation-based room-temperature ionic liquid
Shiro Seki, Yasuhiro Umebayashi, Seiji Tsuzuki, Kikuko Hayamizu, Yo Kobayashi, Yasutaka Ohno, Takeshi Kobayashi, Yuichi Mita, Hajime Miyashiro, Nobuyuki Terada, Shin-ichi Ishiguro
2008-09-23
Communication
DOI: 10.1039/B809309A
Selectivity control in enantioselective four-component reactions of aryl diazoacetates with alcohols, aldehydes and amines: an efficient approach to synthesizing chiral β-amino-α-hydroxyesters
Xinfang Xu, Jing Zhou, Liping Yang, Wenhao Hu
2008-11-11
Communication
DOI: 10.1039/B816104F
Palladium-catalysed direct synthesis of benzo[b]thiophenes from thioenols
Kiyofumi Inamoto, Yukari Arai, Kou Hiroya, Takayuki Doi
2008-09-24
Communication
DOI: 10.1039/B811362A
こちらもおすすめ
化合物よくある質問
1-{3-[5-(エチルカルボンイル)-2,4-ジメチル-1H-ピロロール-3-基]プロパニル}ピペリジン-4-カルボン酸について、適用される法規ガイドラインは何ですか?
この化合物はCAS番号1142209-81-1であり、GHS分類では corrosive (腐食性物質) と classified (分類物質) として指定され...
1142209-81-11-{3-[5-(Ethoxycarbo...
化合物よくある質問
2,2-二氟-1,3-ベンゾジオキサン-5-カルボキシlic酸とは何ですか?
2,2-二氟-1,3-ベンゾジオキサン-5-カルボキシlic酸は、CAS番号656-46-2の化合物で、化学式はC8H4F2O4です。この化合物は白色の結晶性粉...
656-46-22,2-Difluoro-1,3-ben...
化合物よくある質問
8-氯-4-色原酮の代替品はありますか?
8-氯-4-色原酮(CAS番号: 49701-11-3)の代替品には、他の色原酮類似物や、構造が似ている化合物があります。例えば、8-メチル-4-色原酮や、他の...
49701-11-38-Chloro-2,3-dihydro...
化合物よくある質問
エチル6,6-ジメチル-4,5,6,7-テトラヒドロ-1H-インドアゼー-3-カルボキシレートとは何ですか?
エチル6,6-ジメチル-4,5,6,7-テトラヒドロ-1H-インドアゼー-3-カルボキシレートは、CAS番号1233243-56-5を有する化合物です。これは有...
1233243-56-5Ethyl 6,6-dimethyl-4...
化合物よくある質問
4-叔丁基-6-氯-嘧啶に適用される法規ガイドラインは何ですか?
4-叔丁基-6-氯-嘧啶はCAS番号3435-24-3で、GHS分類では毒性物質とみなし、GHSの危険性分類が適用されます。REACH規則では登録が必要で、Eu...
3435-24-34-Tert-butyl-6-chlor...
化合物よくある質問
維库溴铵杂质Bはどのように合成されますか?
維库溴铵杂质Bは、アンドロステンデンから始まり、一連の合成反応、包括的な選択性と高い収率で合成されます。具体的には、ブロミド化、酸化、ジマーゼ反応、アミド化など...
50587-95-6(2beta,3alpha,5alpha...
化合物よくある質問
2-(4-氟苄基)-吡咯烷の物理化学的性質は何ですか?
CAS番号350017-04-8の2-(4-氟苄基)-吡咯烷は、結晶性の白色粉末です。分子量は199.17 g/molで、水に溶けにくいです。化学反応では比較的...
350017-04-82-(4-Fluorobenzyl)py...
化合物よくある質問
3-喹啉甲醛(2-チロール-8-エチル)は安全ですか?
3-喹啉甲醛(2-チロール-8-エチル)は一定の毒性を持つため、取扱には注意が必要です。使用する際は適切な防護具を着用し、密閉容器で保管・搬送し、直接的な接触を...
335196-05-92-Chloro-8-ethyl-3-q...
化合物よくある質問
エチル3-(ヒドロキシメチル)-1H-ピロール-2-カルボキシレートはどのように保存すればよいですか?
エチル3-(ヒドロキシメチル)-1H-ピロール-2-カルボキシレートは、室温(25℃)以下で保存し、直射日光を避け、乾燥した環境で保管することが推奨されます。ま...
75448-69-0Ethyl 3-(hydroxymeth...
119410-05-88-Chloro-11-(4-piper...
掲載誌
Nanoscale
CiteScore:
12.1
自己引用率:
5.2%
年間論文数:
1681
Nanoscale is a high-impact international journal, publishing high-quality research across nanoscience and nanotechnology. Nanoscale publishes a full mix of research articles on experimental and theoretical work, including reviews, communications, and full papers. Highly interdisciplinary, Nanoscale appeals to scientists, researchers and professionals interested in nanoscience and nanotechnology, quantum materials and quantum technology, including the areas of physics, chemistry, biology, medicine, materials, energy/environment, information technology, detection science, healthcare and drug discovery, and electronics. For publication in Nanoscale, papers must report high-quality reproducible new work that will be of significant general interest to the journal's wide international readership. Nanoscale is a collaborative venture between the Royal Society of Chemistry Publishing and a leading nanoscience research centre, the National Center for Nanoscience and Technology (NCNST) in Beijing, China. image block The journal publishes weekly issues, complementing and building on the nano content already published across the Royal Society of Chemistry Publishing journal portfolio. Since its launch in late 2009, Nanoscale has established itself as a platform for high-quality, cross-community research that bridges the various disciplines involved with nanoscience and nanotechnology, publishing important research from leading international research groups.
おすすめ化合物
おすすめサプライヤー
免責事項
このページに表示される学術雑誌情報は、参考および研究目的のみを目的としています。当社は雑誌出版社とは提携しておらず、投稿の取り扱いも行っておりません。出版に関するお問い合わせは、各雑誌出版社に直接ご連絡ください。
表示されている情報に誤りがある場合は、support@chemtradehub.com までご連絡ください。迅速に確認し、対応いたします。