1,300 research outputs found

    Leptonetela megaloda Wang & Li 2011, comb. nov.

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    Leptonetela megaloda (Chen et al., 2010) comb. nov. Qianleptoneta megaloda Chen et al. 2010: 2909, figs 23–24, 25I Type material examined. Paratypes: 1 male and 1 female (GIBGAS), Yanzi Cave [28°17´N, 106°09´E], Sangmu Town, Xishui County, Guizhou, China, 30 July 2004, H. Chen leg. Distribution. China (Guizhou).Published as part of Wang, Chunxia & Li, Shuqiang, 2011, 2841, pp. 1-90 in Zootaxa 2841 on pages 9-1

    Leptonetela digitata Lin & Li 2010

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    Leptonetela digitata Lin & Li, 2010 Leptonetela digitata Lin & Li 2010: 24, figs 13–14, 61 Qianleptoneta triangula Chen et al. 2010: 2879, figs 3–4, 25B syn. nov. Type material examined. Leptonetela digitata: holotype: male (IZCAS), Xiniu Cave, Anhe Village, Dushan Town, Anlong County [25°17´N, 105°34´E], Guizhou, China, 8 May 2006, Y. Lin & Y. Tong leg. Paratype: 1 female, same data as holotype. Qianleptoneta triangula: paratypes: 1 male and 1 female (GIBGAS), Xiniu Cave [25°03´N, 105°29´E], Dushan Town, Anlong County, Guizhou, China, 20 May 2006, H. Chen leg. Distribution. China (Guizhou).Published as part of Wang, Chunxia & Li, Shuqiang, 2011, 2841, pp. 1-90 in Zootaxa 2841 on page

    Leptonetela danxia Lin & Li 2010

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    Leptonetela danxia Lin & Li, 2010 Leptonetela danxia Lin & Li 2010: 21, figs 11–12, 61 Qianleptoneta lycotropa Chen et al. 2010: 2889, figs 10–11, 25D syn. nov. Type material examined. Leptonetela danxia: holotype: male (IZCAS), Zimu Cave, Danxia Mt., Zhaoguan Village, Banqiao Town, Panxian County [25°40.505´N, 104°37.607´E], Guizhou, China, 14 April 2007, Y. Lin & J. Liu leg. Paratype: 1 female, same data as holotype. Qianleptoneta lycotropa: paratypes: 1 male and 1 female (GIBGAS), Shenxian Cave [25°37´N, 104°45´E], Zhudong Town, Panxian County, Guizhou, China, 12 January 2008, H. Chen leg. Distribution. China (Guizhou).Published as part of Wang, Chunxia & Li, Shuqiang, 2011, 2841, pp. 1-90 in Zootaxa 2841 on pages 5-

    sj-docx-1-tam-10.1177_17588359221148028 – Supplemental material for The IASLC grading system for invasive pulmonary adenocarcinoma: a potential prognosticator for patients receiving neoadjuvant therapy

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    Supplemental material, sj-docx-1-tam-10.1177_17588359221148028 for The IASLC grading system for invasive pulmonary adenocarcinoma: a potential prognosticator for patients receiving neoadjuvant therapy by Haoran E, Junqi Wu, Yijiu Ren, Lang Xia, Long Xu, Shaoling Li, Yue Zhao, Chongwu Li, Yunlang She, Chunxia Su, Chunyan Wu, Likun Hou, Deping Zhao and Chang Chen in Therapeutic Advances in Medical Oncology</p

    Leptonetela hangzhouensis Wang & Li 2011, comb. nov.

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    Leptonetela hangzhouensis (Chen et al., 1984) comb. nov. Figs 13–15 Leptoneta hangzhouensis Chen et al. 1984: 8, figs 1–6; Song 1987: 98, fig. 62; Chen & Zhang 1991: 58, figs 49.1–6; Song et al. 1999: 50, figs 20K, U–V Type material examined. Paratypes: 2 males (ZMNH), Qianren Cave and Woyun Cave, Hangzhou [30°16´N, 120°09´E], Zhejiang, China, 24 May 1984, Y. Shen & F. Gao leg. Diagnosis. Leptonetela hangzhouensis is similar to L. microdonta (Xu & Song, 1983), but can be distinguished by the presence of nine promarginal cheliceral teeth, the distal two wider spaced, and six small retromarginal teeth (Fig. 15A); five spines on the retrolateral surface of male palpal tibia, with the second one longest (Figs 13D, 14B); the fork-shaped median apophysis, and the presence of four teeth on median apophysis, with the first and fourth teeth stronger than others in the male (Figs 13B, 15B). Description. Male: total length 2.60 (Fig. 13A). Prosoma 1.12 long, 0.90 wide. Opisthosoma 1.25 long, 1.00 wide. Sternum 0.75 long, 0.50 wide (Fig. 15C). Prosoma dark yellow, somewhat quadrate, and with a pair of setae retrolateral of PLE. Median groove needle-shaped, pale brown. Cervical grooves and radial furrow distinct, pale brown. Eyes six, measurements: ALE 0.08, PLE 0.07, PME 0.05; ALE-PME 0.11, PLE-PLE 0.08, PLE-PME 0.05; AER 0.14, PER 0.20. Clypeus 0.12 high, slightly sloped anteriorly. Chelicera (Fig. 15A) dark yellow, with nine promarginal teeth, the distal two wider spaced and five small retromarginal teeth. Endites and labium dark yellow. Sternum and legs yellowish. Leg measurements: I 10.63 (2.87, 0.37, 3.10, 2.42, 1.87); II 7.89 (2.22, 0.37, 2.10, 1.95, 1.25); III 6.56 (1.90, 0.35, 1.72, 1.58, 1.01); IV 8.52 (2.20, 0.37, 2.50, 2.20, 1.25). Leg formula: I-IV-II-III. Femur I–IV with one short spine ventrally and basally. Tibia I with one short spine dorsally (position 0.5), tibia II III with two short spines dorsally (0.3 and 0.6). Male palp (Figs 13C–D, 14A–B): tibia with four trichobothria dorsally, one long seta and five spines retrolaterally, with the second spine longest; tarsus with three strong spines distally. Tip of the bulb (Figs 13B, 15B): median apophysis fork-shaped, with four teeth distally, the first and fourth teeth stronger than others, conductor lamellar, embolus triangular. Variation. Total length: males 2.60–2.45 (n = 2). Distribution. China (Zhejiang). Remarks. Type specimens were originally deposited in the Department of Biology, Hangzhou Normal College, but transferred to ZMNH in 1998.Published as part of Wang, Chunxia & Li, Shuqiang, 2011, 2841, pp. 1-90 in Zootaxa 2841 on pages 7-

    Interface-dependent resistance switching in Nd0.7Sr0.3MnO3 ceramics

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    Interface-dependent electric-pulse-induced resistance switching effect (EPIR) in Nd0.7Sr0.3MnO3 ceramics was studied. The results reveal that the EPIR effect originates from the interface between the electrodes and the bulk, and the EPIR ratio as well as the high and low resistance states can be strongly influenced by applying a large electrical field on the sample for different intervals. Also, the pulse parameters have great effect on the stability of EPIR and the optimal pulse width, pulse amplitude and read bias are obtained. Based on the space charge limited current mechanism together with the theory of interfacial charge-trapped state, the interface-dependent resistance switching effect is discussed

    Interface-dependent resistance switching in Nd0.7Sr0.3MnO3 ceramics

    No full text
    Interface-dependent electric-pulse-induced resistance switching effect (EPIR) in Nd0.7Sr0.3MnO3 ceramics was studied. The results reveal that the EPIR effect originates from the interface between the electrodes and the bulk, and the EPIR ratio as well as the high and low resistance states can be strongly influenced by applying a large electrical field on the sample for different intervals. Also, the pulse parameters have great effect on the stability of EPIR and the optimal pulse width, pulse amplitude and read bias are obtained. Based on the space charge limited current mechanism together with the theory of interfacial charge-trapped state, the interface-dependent resistance switching effect is discussed

    Effect of shape,height,and interparticle spacing of Au nanoparticles on the sensing performance of Au nanoparticle array

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    The effect of shape,height,and interparticle spacing of Au nanoparticles(NPs)on the sensing performance of Au NP array is systematically investigated.Lengthening the major axis of elliptical NPs with the minor axis kept constant will cause the redshift of the local surface plasmon(LSP)resonance mode,enhance the sensitivity,and widen the resonance peaks.Larger height corresponds to smaller LSP resonance wavelength and narrower resonance peak.With each NP size unchanged,larger interparticle spacing corresponds to larger resonance wavelength and smaller full-width at half-maximum(FWHM).Moreover,duty cycle is important for sensitivity,which is largest when the duty cycle is 0.4
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