來一趟說走就走的旅行論文書籍站
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box office mo的問題,我們搜遍了碩博士論文和台灣出版的書籍,推薦Treasure, Troy寫的 Icing on the Plains: The Rough Ride of Kansas City’s Nhl Scouts 和Treasure, Troy的 Icing on the Plains: The Rough Ride of Kansas City’s NHL Scouts都 可以從中找到所需的評價。
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這兩本書分別來自 和所出版 。
長庚大學 電子工程學系 賴朝松所指導 Mamina Sahoo的 基於石墨烯及生物碳基材料的可撓式電晶體應用與能量攫取 (2021),提出box office mo關鍵因素是什麼,來自於石墨烯、氟化石墨烯、太阳能电池、摩擦纳米发电机、生物碳、能量收集器。
而第二篇論文國立臺灣大學 環境與職業健康科學研究所 吳章甫所指導 吳宗鋼的 綠色通勤族之交通空氣污染暴露評估 (2021),提出因為有 細懸浮微粒、苯-甲-二甲苯混合物、自行車、電動機車、路徑網路、土地利用迴歸模式、隨機森林的重點而找出了 box office mo的解答。
最後網站The Top Grossing Movies in the Last 30 Years - Visual Capitalist則補充:With this in mind, here's a look at the top grossing movies worldwide since the early 1990s, using data from Box Office Mojo.
Icing on the Plains: The Rough Ride of Kansas City’s Nhl Scouts
為了解決box office mo 的問題,作者Treasure, Troy 這樣論述:
This is the story of Kansas City's attempt to integrate major-league hockey into its sports marketplace, only to see it fall through thin ice. Troy Treasure, an award-winning sports reporter, tells the riveting story of the Kansas City Scouts, who began playing in the National Hockey League in 1974.
Perhaps the franchise's owners should have guessed it would be a struggle from the beginning: After finally getting an arena, its original name-the Mo-Hawks-was rejected because the Chicago Blackhawks thought it too closely resembled their moniker. But while the franchise underperformed on the ice
and at the box office, there was also triumphs and plenty of laughs mixed in with the tears. During their two years on the ice, the Scouts featured the biggest on-ice badass in the NHL, a combustible coach, and one of hockey's all-time funny men. Filled with player interviews and painstakingly resea
rched, this book pays tribute to the history of professional hockey in Kansas City, the city's other pro sports teams, and athletics at large. Troy Treasure is a longtime newspaper sports writer and radio broadcaster. Treasure has received awards from media and press associations in Mississippi, M
issouri, and Pennsylvania. He is a graduate of the University of Missouri.
box office mo進入發燒排行的影片
Phê Phim News: BLACK PANTHER LÊN TIẾNG HẬU CHỈ TRÍCH MARVEL | SONIC TRỞ LẠI VỚI TẠO HÌNH MỚI
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Nội dung: Ngân, Dương
Giọng đọc: Linh, Ngân
Dẫn: Linh
Editor: Nhân
Tin 1: Truyện tranh của tác giả Việt được chuyển thể thành phim live-action Nhật
https://www.facebook.com/100005081670577/posts/1309046082608102?sfns=mo
https://www.manga-audition.com/manga-movie-angel-sign-release-date-and-poster-art-revealed/?fbclid=IwAR1tUCTszLAdmhjmYhq9dOcNwaYZzUV_353UqxCkVCofEb-PJaZ5bI3RFbA
Tin 2: Tổng hợp trailer mới tuần qua
The Invisible Man: https://youtu.be/GgQ96Qurn94
Sonic the Hedgehog: https://youtu.be/szby7ZHLnkA
Scoob!: https://youtu.be/-BgWppq25xI
Tin 3: Doctor Sleep đứng trước nguy cơ thua lỗ
https://deadline.com/2019/11/doctor-sleep-bombs-at-box-office-reasons-why-1202782503/?fbclid=IwAR1jY2g5A6GWJafmZSbLKFJR-ciU3k3V6CaHnJM4jZvE6KpyYwGdTmaGTKk
Tin 4: Black Panther góp chuyện vào drama của Martin Scorsese
https://www.independent.co.uk/arts-entertainment/films/news/chadwick-boseman-black-panther-martin-scorsese-marvel-mcu-21-bridges-irishman-a9198016.html?fbclid=IwAR3_3JcAAOStqIvIgy0LzaXgRCgHF0yVL3CPLPkxZi21Pl9r32tEl60f61s
Điểm tin:
1. Phim Áo không được tranh cử Phim Quốc tế xuất sắc nhất tại Oscar
https://variety.com/2019/film/news/joy-austria-oscar-disqualified-too-much-english-sudabeh-mortezai-1203400543/
2. Phim Việt trên sóng HBO bị hoãn chiếu
https://news.zing.vn/phim-am-thuc-viet-se-len-song-hbo-sau-khi-luoc-bot-canh-nong-post1012042.html
3. Joker là phim chuyển thể từ truyện tranh lợi nhuận nhất
https://www.indiewire.com/2019/11/joker-most-profitable-comic-book-film-ever-box-office-1202188266/?fbclid=IwAR1FUIxg_6lJx4_FpwIWVM52IjPw6i_NWkLQpVNJZ3avIGsm2FhuWeYV1G4
BXH:
Bắc Mỹ: https://www.boxofficemojo.com/weekend/2019W45/?ref_=bo_hm_rw
Việt Nam: https://boxofficevietnam.com/#1543824640456-16ae0ab0-64e8
#PhêPhimNews #số111 #DoctorSleep
基於石墨烯及生物碳基材料的可撓式電晶體應用與能量攫取
為了解決box office mo 的問題,作者Mamina Sahoo 這樣論述:
Table of ContentsAbstract.......................................................................................................iFigure Captions........................................................................................xiTable Captions...................................................
....................................xxiChapter 1: Introduction1.1 Flexible electronics................................................................................11.2 Graphene the magical material ………………………….……….......21.2.1 Synthesis of graphene…………………………….….…...21.2.1.1 Mechanical exfoliati
on of graphene………………...……21.2.1.2 Epitaxial growth on Sic substrate………………….…..31.2.1.3 Chemical vapor deposition (CVD) method………….…..41.2.2 Graphene transfer…………………………………………....41.3 Application of graphene based Electronics……………………….......51.3.1 Graphene based flexible transparent electrode
……………….61.3.2 Top gated Graphene field effect transistor…………………….71.4 Challenges of flexible graphene based field effect transistors.……….91.5 Energy harvesting devices for flexible electronics………….........….91.6 Solar cell…………………………………………………………...101.6.1 Device architecture…………………………………………101.
6.2 Issues and Challenges of Perovskite solar cells………...121.7 Triboelectric nanogenerator (TENG)………………………………121.7.1 Working mode of TENG………………………………….141.8 Applications of TENG………………………………………………151.8.1 Applications of graphene based TENG…………………....151.8.2 Applications of bio-waste material ba
sed TENG………….171.9 Key challenges of triboelectric nanogenerator…………………....…191.10 Objective and scope of this study………………………………....19Chapter 2: Flexible graphene field effect transistor with fluorinated graphene as gate dielectric2.1 Introduction………………………………………………………....212.2 Material preparation a
nd Device fabrication………………. 232.2.1CVD Growth of Graphene on Copper Foil………………….232.2.2 Transfer of graphene over PET substrate……………...........252.2.3 Fabrication of fluorinated graphene ……………...........252.2.4 F-GFETs with FG as gate dielectric device fabrication……262.2.5 Material and electrical C
haracterization …………………272.3 Results and discussion…………………………………………….282.3.1 Material characterization of PG and FG……………...…...….282.3.2 Electrical characterization of F-GFET with FG as dielectrics..332.3.3 Mechanical stability test of F-GFET with FG as dielectrics ….362.4 Summary…………………………………………………
………....40Chapter 3: Robust sandwiched fluorinated graphene for highly reliable flexible electronics3.1 Introduction………………………………………………………….423.2 Material preparation and Device fabrication ………………….........443.2.1 CVD Growth of Graphene on Copper Foil…………………...443.2.2 Graphene fluorination …...…….…………
…………..............443.2.3 F-GFETs with sandwiched FG device fabrication....................443.2.4 Material and electrical Characterization…..............................453.3 Results and discussion ……………………………………...............453.3.1 Material characterization of sandwiched…………………….453.3.2 Electric
al characterization of F-GFET with sandwiched FG....473.3.3 Mechanical stability test of F-GFET with sandwiched FG…503.3.4 Strain transfer mechanism of sandwiched FG………………513.4 Summary…………………………………………………………....53Chapter 4: Functionalized fluorinated graphene as a novel hole transporting layer for ef
ficient inverted perovskite solar cells4.1 Introduction………………………………………………………….544.2 Material preparation and Device fabrication......................................564.2.1 Materials ………………………...…………………………564.2.2 CVD-Graphene growth ……………………………...…...564.2.3 Graphene fluorination …………………………………….564.
2.4 Transfer of fluorinated graphene…………………………...574.2.5 Device fabrication …………………………………….….574.2.6 Material and electrical Characterization …….....................584.3 Results and discussion …………………………………………….594.3.1 Surface electronic and optical properties of FGr……….….594.3.2 Characterization o
f FGr and perovskite surface ……….…644.3.3 Electrical performance of PSC………………….…….…...694.3.4 Electrical performance of Flexible PSC……………………724.4 Summary…………………………………………………………...78Chapter 5: Flexible layered-graphene charge modulation for highly stable triboelectric nanogenerator5.1 Introduction…………
…………………………………………....795.2 Experimental Section……………………………………………….825.2.1 Large-area graphene growth ……………………………….825.2.2 Fabrication of Al2O3 as the CTL …………………………...825.2.3 Fabrication of a Gr-TENG with Al2O3 as the CTL………825.2.4 Material characterization and electrical measurements…….835.3 Results
and discussion.…………………………………...…………845.3.1 Material Characterization of Graphene Layers/Al2O3……845.3.2 Working Mechanism of Gr-TENG with Al2O3 as CTL…915.3.3 Electrical Characterization of Gr-TENG with Al2O3 CTL…945.3.4 Applications of the Gr-TENG with Al2O3 as CTL……….1015.4 Summary…………………………………………
……………….103Chapter 6: Eco-friendly Spent coffee ground bio-TENG for high performance flexible energy harvester6.1 Introduction…………………………………………………….......1046.2 Experimental Section…………………………………………….1086.2.1 Material Preparation …………………………………….1086.2.2 Fabrication of SCG powder based TENG………………...1086
.2.3 Fabrication of SCG thin-film based TENG ………………1096.2.4 Material characterization and electrical measurements….1106.3 Results and discussion.…………………………………...………1116.3.1 Material Characterization of SCG powder and thin film….1116.3.2 Working Mechanism of SCG-TENG……………………...1186.3.3 Electrical Cha
racterization of SCG-TENG……………….1226.3.4 Applications of the SCG thin-film based TENG………….1326.4 Summary………………………………………………………….134Chapter 7: Conclusions and future perspectives7.1 Conclusion………………………………………………………....1357.2 Future work …………………………….………………………….1377.2.1 Overview of flexible fluorinated g
raphene TENG..............1377.2.1.1 Initial results………………………………….…1387.2.2.1.1 Fabrication of FG-TENG………………1387.2.2.1.2 Working principle of FG-TENG……….1397.2.2.1.3 Electrical output of FG-TENG.………...140References…………………………………………………………….142Appendix A: List of publications………………….……………..........177A
ppendix B: Fabrication process of GFETs with fluorinated graphene (FG) as gate dielectric……........……………………………………….179Appendix C: Fabrication process of GFETs with sandwiched FG…....180Appendix D: Fabrication process of inverted perovskite solar cell with FGr as HTL…………………………………………………………….181Appendi
x E: Fabrication of a Gr-TENG with Al2O3 as the CTL…….182Appendix F: Fabrication of SCG based triboelectric nanogenerator….183Figure captionsFigure 1-1 Exfoliated graphene on SiO2/Si wafer……………………….3Figure 1-2 Epitaxial graphene growth on SiC substrate………………....3Figure 1-3 Growth mechanism of graphe
ne on Cu foil by CVD ……......4Figure 1-4 Wet transfer process of CVD grown graphene…………...….5Figure 1-5 RGO/PET based electrodes as a flexible touch screen.……....6Figure 1-6 Graphene based (a) touch panel (b) touch-screen phone…….7Figure 1-7 Flexible graphene transistors (a) (Top) Optical photograph
of an array of flexible, self-aligned GFETs on PET. (Bottom) The corresponding schematic shows a device layout. (b) Schematic cross-sectional and top views of top-gated graphene flake–based gigahertz transistors. (Left) AFM image of a graphene flake. (Right) Photograph of flexible graphene devices
fabricated on a PI substrate. (c) Cross-sectional schematic of flexible GFETs fabricated using a self-aligned process……8Figure 1-8 The magnitude of power needed for meet certain operation depending critically on the scale and applications………………………10Figure 1-9 Schematic diagrams of PSC in the (a) n-i
-p mesoscopic, (b) n-i-p planar, (c) p-i-n planar, and (d) p-i-n mesoscopic structures………...12Figure 1-10 Schematic illustration of the first TENG...………………...13Figure 1-11 Working modes of the TENG. (a) The vertical contact-separation mode. (b) The lateral sliding mode. (c) The single-electrode mode
. (d) The free-standing mode ………………………………...……14Figure 1-12 Schematic illustration of (a) device fabrication of graphene-based TENGs (b) graphene/EVA/PET-based triboelectric nanogenerators (c) device fabrication of stretchable CG based TENG with electrical output performance……………………………………………………...17
Figure 1-13 Schematic illustration and output performance of bio-waste material based TENG (a) Rice-husk (b) Tea leaves (c) Sun flower powder (SFP) (d) Wheat stalk based TENG………….…………………………18Figure 2-1 Graphene synthesis by LPCVD method……….…………...24Figure 2-2 Schematic diagram of (a) preparation pro
cess of 1L-FG/copper foil (b) Layer by layer assembly method was used for fabricating three-layer graphene over copper foil and then CF4 plasma treatment from top side to form 3L-FG/copper foil…………………….26Figure 2-3 Schematic illustration of fabrication process of F-GFET with FG as gate dielectric ……
……………………………………………….27Figure 2-4 (a) Raman spectra of PG, 1L-FG and 3L-FG after 30 min of CF4 plasma treatment over copper foil. (b) Peak intensities ratio ID/IG and optical transmittance of PG, 1L-FG and 3L-FG. Inset: image of PG and 1L-FG film over PET substrate. (c) Typical Raman spectra of PG, 1L
-FG and 3L-FG on PET substrate. (d) Optical transmittance of PG, 1L-FG and 3L-FG film over PET substrate. The inset shows the optical image of GFETs with FG as gate dielectrics on PET ……….…………30Figure 2-5 XPS analysis result of (a) PG (b) 1L-FG (c) 3L-FG where the C1s core level and several carbon f
luorine components are labeled. The inset shows the fluorine peak (F 1s) at 688.5 eV……………………….32Figure 2-6 (a) Water contact angle of PG, 1L-FG and 3L-FG over PET substrate. (b) The relationship between water contact angle of PG, 1L-FG and 3L-FG and surface-roughness………………………………………33Figure 2-7 (a) I
d vs. Vd of w/o-FG, w/1L-FG and w/3L-FG samples after 30 min of CF4 plasma (b) Id vs. Vg of w/o-FG, w/1L-FG and w/3L-FG samples at a fixed value of drain to source voltage, Vds of 0.5 V (c) Gate capacitance of w/o-FG, w/1L-FG and w/3L-FG samples (d) Gate leakage current of w/o-FG (naturally formed A
l2OX as gate dielectric), w/1L-FG and w/3L-FG samples ……………………………...…………...……...34Figure 2-8 (a) Schematic illustration of bending measurement setup at different bending radius. (i) Device measurement at (i) flat condition (ii) bending radius of 10 mm (iii) 8 mm (iv) 6 mm. Inset shows the photograph
of measurement setup. Change in (b) carrier mobility (c) ION of w/o-FG, w/1L-FG and w/3L-FG samples as a function of bending radius. The symbol ∞ represents the flat condition. Change in (d) carrier mobility (e) ION of w/o-FG, w/1L-FG and w/3L-FG samples as a function of bending cycles (Strain = 1.
56%)…………………………………….38Figure 3-1 Schematic illustration of the flexible top gate graphene field effect transistor with sandwich fluorinated graphene (FG as gate dielectric and substrate passivation layer) ……………………………...…………44Figure 3-2 Raman spectra of (a) PG/PET and PG/FG/PET substrate (b) sandwiche
d FG (FG/PG/FG/PET). Inset showing the optical transmittance of sandwiched FG. (c) HRTEM image for 1L-FG.……………….….…46Figure 3-3 (a) Id vs. Vd of FG/PG/FG device at variable vg (−2 to 2 V). (b) Id vs. Vg of FG/PG/FG. (c) Gate capacitance of FG/PG/FG ….…….48Figure 3-4 Raman spectra of devices under be
nding (a) PG/PET (Inset shows the 2D peak) (b) PG/FG/PET (inset shows the 2D peak) …….…49Figure 3-5 (a) Change in Mobility (b) change in ION of PG/PET and PG/FG/PET as a function of bending radius between bending radii of ∞ to 1.6 mm in tensile mode (c) Change in Mobility (d) Change in ION of PG/PET
and PG/FG/PET as a function of bending cycles. Inset of (c) shows the photograph of F-GFETs with sandwich FG on the PET substrate (e) change in resistance of w/1L-FG, 1L-FG/PG/1L-FG samples as a function of bending radius ………………………...……………….50Figure 3-6 Schematic evolution of proposed strain transf
er mechanism through PG/PET and PG/FG/PET. The inset of PG/PET sample shows the generation of sliding charge due to interfacial sliding between PG and PET ………………………………………………………………….….52Figure 4-1 FGr fabrication and transfer process …………….………....57Figure 4-2 (a) Raman analysis of pristine graphene a
nd the FGr samples after 5, 10, 20, and 30 min of CF4 plasma treatment over Cu foil (b) Raman intensity ratios (I2D/IG and ID/IG) of fluorinated graphene, with respect to the exposure time ……………………………………………60Figure 4-3 SEM images of (a) ITO, (b) ITO/1L-FGr, (c) ITO/2L-FGr, and (d) ITO/3L-FGr …………………
………………………………….61Figure 4-4 XPS analysis of FGr with (a) 5 min (b) 10 min and (c) 20 min of CF4 plasma treatment on the Cu foil (d) The fluorine peak (F1s) of FGr (f) The correlation of the carbon-to-fluorine fraction (C/F) with exposure time and the corresponding carrier concentrations …………….………62Fi
gure 4-5 Tauc plots and UV–Vis absorption spectra of FGr films with CF4 plasma treatment for (a) 5, (b) 10, and (c) 20 min ….………......….63Figure 4-6 WCAs on PEDOT: PSS and 1L, 2L, and 3L FGr samples ...64Figure 4-7 (a) Mechanism of large grain growth of perovskite on a non-wetting surface (b) Top-vi
ew and cross-sectional surface morphologies of perovskites on various HTLs ………………………………...…………65Figure 4-8 XRD of perovskite films on various HTL substrates ….…...66Figure 4-9 UPS spectra of various numbers of FGr layers on ITO: (a) cut-off and (b) valance band spectra …………………………………….….67Figure 4-10
Energy band diagrams of PSCs with (a) PEDOT: PSS, (b) 1L-FGr, (c) 2L-FGr, and (d) 3L-FGr as HTL …………………….…….68Figure 4-11 (a) Steady state PL spectra of PEDOT: PSS/perovskite and FGr/perovskite films. (b) TRPL spectral decay of PEDOT: PSS/perovskite and FGr/perovskite films………………………….……69Figure 4-1
2 (a) Schematic representation of a PSC having an inverted device configuration. (b) Cross-sectional HRTEM image of the ITO/ FGr–perovskite interface………………………………………...………70Figure 4-13 Photovoltaic parameters of PSCs incorporating various HTL substrates: (a) PCE (%), (b) Voc (V), (c) Jsc (mA/cm2), an
d (d) FF (%)....71Figure 4-14 Normalized PCEs of target and control PSCs incorporating various HTL substrates, measured in a N2-filled glove box. (a) Thermal stability at 60 °C (b) Light soaking effect under 1 Sun (c) Stability after several days …………………………………………………………….72Figure 4-15 (a) Schematic r
epresentation of the structure of a flexible PSC on a PET substrate (b) J–V curves of control and target flexible PSCs, measured under both forward and reverse biases. (c) Average PCE of flexible PSCs incorporating PEDOT: PSS and FGr HTLs……….…73Figure 4-16 (a) Normalized averaged PCEs of the flexibl
e PSCs after bending for 10 cycles at various bending radii. (b) Normalized averaged PCEs of the flexible PSCs plotted with respect to the number of bending cycles at a radius of 6 mm ………………………………………………75Figure 4-17 Photovoltaics parameters of flexible PSCs with various HTL substrates: (a) JSC (mA/c
m2), (b) Voc (V), and (c) FF (%) ……………....75Figure 4-18 XRD patterns of perovskite films on PET/ITO/FGr, recorded before and after bending 500 times …………………………………….76Figure 4-19 SEM images of (a) perovskite films/FGr/ITO/PET before bending (b) after bending 500 times (c) perovskite films/PEDOT: PSS/
ITO/PET before bending (d) after bending 500 times ……………….…77Figure 4-20 PL spectra of perovskite films on PET/ITO/FGr, recorded before and after various bending cycles …………………………….…78Figure 5-1 Schematic illustration showing the fabrication process of a flexible Gr-TENG with Al2O3 as the CTL ……………
………………...83Figure 5-2 The Raman spectra of (a) graphene/Al-foil/PET and (b) graphene/Al2O3/Al-foil/PET. The I2D/IG of graphene layers (1L, 3L and 5L) over (c) Al-foil/PET substrate (d) Al2O3/Al-foil/PET substrate …...85Figure 5-3 XRD patterns of (a) graphene/Al-foil/PET and (b) graphene/Al2O3/Al-foi
l/PET ……………………………………………86Figure 5-4 FESEM image of the graphene surface on (a) Al-foil/PET and (b) Al2O3/Al-foil/PET. EDS analysis of (c) graphene/Al-foil/PET and (d) graphene/Al2O3/Al-foil/PET (e) EDS elemental mapping of the graphene/Al2O3/Al-foil/PET presenting C K series, O K series and Al K ser
ies …………………………………………………………….………87Figure 5-5 3D AFM images of (a) 1L-Gr (b) 3L-Gr (c) 5L-Gr on Al foil (d) 1L-Gr (e) 3L-Gr (f) 5L-Gr on Al2O3/Al foil………………….….….89Figure 5-6 Work function of graphene layers on the (a) Al-foil (b) Al2O3/Al-foil substrate by KPFM. Inset showing the surface potential of
graphene layers (1L, 3L and 5L) over Al-foil and Al2O3 substrate (c) energy band diagrams for 1L-Gr, 3L-Gr and 5L-Gr over Al2O3 ……....90Figure 5-7 Schematic illustration of Electronic energy levels of graphene samples and AFM tip without and with electrical contact for three cases: (i) tip and the
1L-Gr (ii) tip and the 3L-Gr and (iii) tip and the 5L-Gr over Al2O3/Al foil/PET……………………………………….…...…………91Figure 5-8 Working mechanism of Gr-TENG with Al2O3 ….….…...…93Figure 5-9 a) ISC and (b) VOC of 1L-, 3L- and 5L-Gr-TENGs without Al2O3 CTL (c) Sheet resistance of graphene as a function of number
of layers ………………………………...…...…………………………….95Figure 5-10 Electrical output of the Gr-TENG with Al2O3 CTL: (a) ISC and (b) VOC of 1L-, 3L- and 5L-Gr. Magnification of the (c) ISC and (d) VOC of the 3L-Gr-TENG with Al2O3 as the CTL. Average mean (e) ISC and (f) VOC generated by pristine Gr-TENGs (1L, 3L
and 5L) and Gr-TENGs (1L, 3L and 5L) with Al2O3 CTL. Error bars indicate standard deviations for 4 sets of data points ……………...…………….….…......96Figure 5-11 (a) CV of Al/Al2O3/3L-Gr/Al at 100 kHz and 1 MHz (b) CV hysteresis of 3L-Gr-TENG with Al2O3 as CTL with different sweeping voltages (c) Surface
charge density of graphene (1L, 3L and 5L)-based TENG with and without Al2O3 as CTL ………………………………...98Figure 5-12 Circuit diagram of output (a) VOC and (b) ISC measurement of 3L-Gr TENG with Al2O3 CTL as a function of different resistors as external loads. Variation in VOC and ISC w.r.t different re
sistors as external loads of (c) 3L-Gr TENG with Al2O3 CTL (d) 3L-Gr TENG without Al2O3 CTL. Relationship between electrical output power and external loading resistance (e) 3L-Gr TENG with Al2O3 CTL (f) 3L-Gr TENG without Al2O3 CTL…………………………………….………………...99Figure 5-13 (a)Electrical stability and du
rability of the 3L-Gr TENG with Al2O3 (b) Schematic illustrations showing the charge-trapping mechanism of 3L-Gr-TENG without and with Al2O3 charge trapping layer ………101Figure 5-14 (a) Photograph showing 20 LEDs being powered (b) Circuit diagram of bridge rectifier (c) Charging curves of capacitors
with various capacitances (d) Photograph of powering a timer …….………………102Figure 6-1 The schematic diagram of the fabrication process for SCG powder based TENG ……………………………………………….….108Figure 6-2 The schematic diagram of the fabrication process for SCG thin-film based TENG via thermal evaporation meth
od ………………109Figure 6-3 FESEM image of (a) SCG powder (inset image illustrates the high magnification of SCG powder) (b) SCG thin-film/Al foil/PET (inset image illustrates the high magnification of SCG thin-film). EDS of the (c) SCG powder (d) SCG thin-film/Al foil/PET…………………………. 112Figure 6-4 Raman
spectra analysis (a) pristine SCG powder (b) SCG thin-film/Al foil/PET. XRD patterns of (c) SCG powder (d) SCG thin film with different thickness ……………………………………… ……….115Figure 6-5 FTIR analysis of the (a) pristine SCG powder sample (b) SCG thin film………………………………………………………………...116Figure 6-6 3D AFM ima
ge of SCG thin-film with various thickness (a) 50 nm (b)100 nm and (c) 200 nm……………………………………...117Figure 6-7 Schematic illustration of working principle of SCG thin-film based TENG …………………………………………………………...119Figure 6-8 Finite element simulation of the generated voltage difference for SCG thin-film b
ased TENG based on the contact and separation between SCG thin film and PTFE …………….……………………….120Figure 6-9 (a) The setup for electrical property testing, which including a Keithley 6514 system electrometer and linear motor. Electrical output (b) ISC (c) VOC of TENGs based on different friction pairs
for checking the triboelectric polarity of SCG…………………………………………...123Figure 6-10 Electrical measurement of (a) ISC and (b) VOC of the SCG thin-film based TENG. Mean value of (d) ISC (e) VOC and (f) Output power density of the pristine SCG powder and thermal deposited SCG thin-film based TENG. ...………
………………………………………125Figure 6-11 (a) Schematic illustration of KPFM for measuring the work function. (b) Surface potential images of SCG thin film with various thickness (50 nm, 100 nm and 200 nm). (c) Surface potential and (d) Work function vs SCG thin film with various thickness (50 nm, 100 nm and 20
0 nm).………….……………………………………………….128Figure 6-12 (a) Isc and (b) Voc of SCG thin film based TENG under different contact frequencies (c) Isc and (d) Voc of SCG thin film based TENG under different separation distance…………………………….129Figure 6-13 Electrical response (a) ISC (b) VOC of pristine SCG powder an
d (c) ISC (d) VOC of SCG thin-film based TENG with respect to different relative humidity (35-85% RH) …………………………….131Figure 6-14 Electrical stability and durability test of the output performance of (a) pristine SCG powder based TENG (b) SCG thin-film based TENG……………………………………………………………132Figure 6-15
Applications of the SCG thin film based TENG as a power supply: (a) Circuit diagram of the bridge-rectifier for charging a capacitor (b) Charging curves of capacitors with various capacitances (0.1, 2.2 and 3.3 µF) (c) Photograph of powering a timer…………………...………133Figure 7-1 Schematic illustration o
f FG based TENG…….….……….139Figure 7-2 Working mechanism of FG based TENG…………………140Figure 7-3 Electrical output of FG-TENG: (a) Isc and (b) Voc …….….141Table captionsTable 2-1 Comparison of flexible G-FETs on/off ratio of our work with other’s work…………………………………………………...………...40Table 3-1 Summary of th
e electrical and mechanical performance of flexible w/o-FG, w/ 1L-FG, w/3L-FG and sandwich FG (FG/PG/FG) samples......................................................................................................52Table 3.2: Comparison of the electrical and mechanical performance of sandwich FG ba
sed F-GFET with previous F-GFET with different gate dielectrics……………………………………………………….………53Table 4-1 Best photovoltaic performance from control and target devices prepared on rigid and flexible substrates……………………………......74Table 5-1 EDS elemental analysis of graphene over Al-foil/PET and Al2O3/Al-foi
l/PET ………………………………………………………88Table 5-2 Comparison of electrical output performance of Gr-TENGs with and without Al2O3 CTL samples used in this study………………103Table 6-1 EDS elemental analysis of SCG-Powder and SCG thin film /Al foil/PET………………………………………………………………...113Table 6-2 Comparison of electrical o
utput performance of SCG-TENGs samples used in this study……………………………………………...126
Icing on the Plains: The Rough Ride of Kansas City’s NHL Scouts
為了解決box office mo 的問題,作者Treasure, Troy 這樣論述:
This is the story of Kansas City's attempt to integrate major-league hockey into its sports marketplace, only to see it fall through thin ice. Troy Treasure, an award-winning sports reporter, tells the riveting story of the Kansas City Scouts, who began playing in the National Hockey League in 1974.
Perhaps the franchise's owners should have guessed it would be a struggle from the beginning: After finally getting an arena, its original name-the Mo-Hawks-was rejected because the Chicago Blackhawks thought it too closely resembled their moniker. But while the franchise underperformed on the ice
and at the box office, there was also triumphs and plenty of laughs mixed in with the tears. During their two years on the ice, the Scouts featured the biggest on-ice badass in the NHL, a combustible coach, and one of hockey's all-time funny men. Filled with player interviews and painstakingly resea
rched, this book pays tribute to the history of professional hockey in Kansas City, the city's other pro sports teams, and athletics at large. Troy Treasure is a longtime newspaper sports writer and radio broadcaster. Treasure has received awards from media and press associations in Mississippi, M
issouri, and Pennsylvania. He is a graduate of the University of Missouri.
綠色通勤族之交通空氣污染暴露評估
為了解決box office mo 的問題,作者吳宗鋼 這樣論述:
苯(benzene)、甲苯(toluene)、二甲苯(ethylbenzene)與鄰間對二甲苯(xylenes)這類合稱為BTEX的揮發性有機污染物和細懸浮微粒(PM2.5)為常見的交通空氣污染物(traffic-related air pollutant, TRAP),為了降低車輛排放,許多人們開始選擇成為綠色通勤族—透過騎乘腳踏車或電動機車來通勤。儘管如此,這些通勤族也因為接近路上的車輛排放源,而較其他通勤族(如轎車駕駛、捷運通勤族)有較高的空氣污染物(TRAP)濃度暴露量。為進行綠色通勤族的暴露評估,政府的空品測站或是低階微型感測器的監測方式不失為一種方法。但因為空品測站的密度與位置或
是低階感測器的量測精準度與架設位置的不確定性,使得兩者的量測值代表性受到限制。因此,在本研究中,使用直接量測的方式評估綠色通勤族的暴露。此外,亦以現場的量測結果為基礎進行暴露濃度模式的建立,模擬與評估最低暴露濃度路徑與最短通勤路徑的暴露濃度差異。本研究分成三階段的實驗。在第一階段,於自行車道架設固定式監測儀器設備以監測污染物暴露濃度,並藉由監測值結合模式分析以鑑別影響暴露濃度的環境因子與各類車輛種類的貢獻程度。在監測儀器方面,PM2.5以連續監測儀器,而BTEX則以近連續監測儀器進行暴露濃度評估。在第二階段,則是在規定的騎乘路線上,藉由綠色通勤族所攜帶監測設備,以移動監測的方式評估個人暴露,且
評估與鑑別影響暴露濃度的環境因子與各類車輛種類的貢獻程度。此階段亦使用連續監測儀器進行PM2.5的暴露濃度評估,BTEX因儀器技術的限制,只能使用時間累積式的方法來評估。資料分析方面,第一與第二階段皆以廣義線性回歸模式(generalized linear model),包含混合模式(mixed-effect model)評估影響暴露濃度的環境因子與各類車輛種類的貢獻程度。而在第二階段,亦使用健康衝擊模式(Health Impact Modelling, HIM)的方式評估自行車與電動機車通勤族的全因死亡率(All-cause mortality, ACM)風險差異。在第三階段,於亞洲三城市(
台北、大阪與首爾)藉由自行車騎士配戴PM2.5低階採樣器,以移動監測的方式評估個人暴露濃度。以個人暴露濃度為基礎,結合路徑上之土地利用特性以及機械學習演算法中的隨機森林演算法(Random Forest),建立城市PM2.5濃度分布推估模式。並以空間交叉驗證(Spatial cross-validation)方法驗證模式表現,避免模式評估過程因為空間自相關性(Sptail Autocorrelation, SAC)的狀況而有過度優化模式表現的假象。最後,以QGIS(Quantum geographic information system)之的最短路徑工具(shortest path)模擬最低
暴露濃度路徑與最短通勤路徑,並評估兩種路徑的暴露濃度差異。實驗結果顯示,主要影響綠色通勤族的交通污染物濃度暴露的因子與來源多數與交通有關,如路徑的種類、通勤的時間點、通勤工具、與交通有關的土地利用特徵、車輛數(如機車)。另外,BTEX與PM2.5的暴露濃度相比,有較高的空間變異特性。因此,BTEX可以成為評估都市土地利用規劃差異的空氣品質指標物。而第二階段的模式分析結果也顯示,透過替代通勤路徑可以有效降低空氣污染物的暴露濃度。在第二階段,HIM的結果顯示,自行車通勤族可因通勤的時間點、通勤的時間在替代通勤路徑,降低全因死亡率(ACM)的風險。在第三階段,在完成建立暴露濃度地圖後,透過模擬路徑的
比較,所有的低暴露濃度路徑的累積暴露濃度都比最短路徑的暴露濃度低。儘管有些路徑比較的結果顯示暴露濃度差異百分比不大,但每天通勤的暴露差異量,透過每日的積累,長遠來看是有其效益之存在。總結來說,避開交通量大或是有許多交通相關的土地利用特徵的路徑或時間,是可以有效降低通勤所累積的暴露濃度。而騎乘腳踏車所帶來的效益,除了降低暴露濃度外,透過騎車這項運動所產生的健康效益,有機會可以克服暴露於空氣污染物所帶來的風險。對於政策推行者,可以考慮建立以空氣污染物暴露濃度為基礎的路徑規劃的平台,供綠色通勤族使用。