每天都要穿得美美的論文書籍站
Knot的問題,透過圖書和論文來找解法和答案更準確安心。 我們找到下列評價、門市、特惠價和推薦等優惠
Knot的問題,我們搜遍了碩博士論文和台灣出版的書籍,推薦Brown, Jonathan A. C.寫的 Islam and Blackness 和James, Victoria的 A Christmas House Wedding都 可以從中找到所需的評價。
另外網站Dreye權威釋義|knot也說明:▸(of the stomach) tighten as a result of tension. Phrase. at a rate of knots. Brit. informal very fast. get knotted
這兩本書分別來自 和所出版 。
國立清華大學 先進光源科技學位學程 李志浩、黃清鄉所指導 羅皓文的 同步加速器光源中插件磁鐵的進階特性之研究 (2021),提出Knot關鍵因素是什麼,來自於同步加速器光源、聚頻磁鐵、亮度、橫向同調、維格納分布函數。
而第二篇論文國立清華大學 材料科學工程學系 楊長謀所指導 魯 宣的 抑制自縛增進高分子光電量子效率以及介面電場與量子點激發電荷之交互作用 (2021),提出因為有 共軛高分子、自縛效應、量子效率、量子點、異質介面電場的重點而找出了 Knot的解答。
最後網站Wrap Knot White | SkLO | Glass Sculpture | Handblown - Jardan則補充:SkLO Wrap Knot objects are handblown from a wound and knotted tube of glass handblown in the Czech Republic. Each object is a unique handmade piece, ...
Islam and Blackness
為了解決Knot 的問題,作者Brown, Jonathan A. C. 這樣論述:
The most comprehensive examination to date of the claim that Islam, as a system of scripture, law and spirituality, is antiblackIt is commonly claimed that Islam is antiblack, even inherently bent on enslaving Black Africans. Western and African critics alike have contended that antiblack racism
is in the faith’s very scriptural foundations and its traditions of law, spirituality, and theology. But what is the basis for this accusation? Bestselling scholar Jonathan A.C. Brown examines Islamic scripture, law, Sufism, and history to comprehensively interrogate this claim and determine how and
why it emerged. Locating its origins in conservative politics, modern Afrocentrism, and the old trope of Barbary enslavement, he explains how antiblackness arose in the Islamic world and became entangled with normative tradition. From the imagery of ’blackened faces’ in the Quran to Shariah assessm
ents of Black women as ’undesirable’ and the assertion that Islam and Muslims are foreign to Africa, this work provides an in-depth study of the controversial knot that is Islam and Blackness, and identifies authoritative voices in Islam’s past that are crucial for combatting antiblack racism today.
Knot進入發燒排行的影片
UHA味覚糖「なが〜い さけるグミ 巨峰」をまるまる一本使って、レアチーズケーキをつくりました。
ゼリーに閉じ込めた3つの飾りは水引梅結びにした、さけるグミです。梅結びは、縁起が良いとされ、水引きなどでよく見かける結び方です。梅結びを大量に使って、夏に作っていた娘の工芸作品が かわいかったのに影響され、ケーキにしてみました。
さけるグミのお陰で、思いっきり巨峰味のレアチーズケーキができました。
この手の面白くておいしいお菓子、ほんとにすばらしいな。
*レシピ*(直径 14.5 cmの丸型 1個分)
1.なが〜い さけるグミを4つに割き、梅結びを作る。
ボトムを作ります
2.ビスケット 70gを細かく砕く。
3.溶かした無塩バター 30g(若干崩れやすかったので、35gにしてみてください)を入れ混ぜる。
4.型に敷き込み冷蔵庫で冷やしておく。
レアチーズケーキを作ります
5.水 35gに粉ゼラチン 10gを振り入れておく。
6.室温に戻したクリームチーズ 100gをなめらかになるまで混ぜる。
7.砂糖 60gを入れ混ぜる。
8.無糖ヨーグルト 200gを入れ混ぜる。
9.(5)を600wの電子レンジで20秒ほど加熱し、ゼラチンを溶かす。
10.(8)を混ぜながら(9)を入れる。
11.半量(200g程度)を取り分ける。
12.(1)の梅結びを3つ残し、残りのさけるグミ(22g)を耐熱容器に入れ、水を10g加える。
13.600wの電子レンジで20秒ほど加熱し、さけるグミを溶かす。
14.(11)の半量の片方に(13)を入れ混ぜる。薄紫になるように着色しました。
15.(4)に流し入れ、1時間弱冷蔵庫で冷やし、表面を固める。
16.(15)に(11)の残りの半量を流し入れ、冷蔵庫で冷やし、表面がうっすら固まりかけたら(1)の梅結びを3つのせ、表面を固める。
上部のゼリーを作ります
17.80℃程度のお湯 150gに粉ゼラチン 6gを入れ溶かす。
18.砂糖 30gを入れ溶かす。
19.レモン汁 5gを入れ混ぜる。
20.冷ました(19)を(16)に流し入れる。
21.冷蔵庫で冷やし、しっかり固める。
22.でけた。
むちゃくちゃ巨峰味。そして、さけるグミがフォークで切れるかたさになってて、むちゃくちゃ感謝したわ。
#レアチーズケーキ #水引 #さけるグミ
I made a no-bake cheese cake using a whole UHA Mikakuto "Nagaai sakeru Gummy Kyoho".
The three decorations trapped in the jelly are gummies tied in mizuhiki plum knots.
Plum knots are said to be auspicious and are often seen in mizuhiki. I was inspired by my daughter's cute craftwork that she made during her summer vacation using a lot of plum knots, so I decided to make it into a cake. Thanks to the gummy candies, I made a no-bake cheese cake with a Kyoho flavor. This kind of interesting and tasty snack is really wonderful.
*Recipe* (for 1 round mold 14.5 cm in diameter)
1.Divide the gummy candy into four pieces and make a plum knot.
Make the bottom.
2.Crush 70g of biscuits into small pieces.
3.Mix in 30g of melted unsalted butter (it was a little crumbly, so try 35 grams).
4.Place in a mold and chill in the refrigerator.
Make the rare cheesecake.
5.Sprinkle 10g of powdered gelatin into 35g of water.
6.Mix 100g of cream cheese at room temperature until smooth.
7.Mix in 60g of sugar.
8.Mix in 200g of unsweetened yogurt.
9.Heat (5) in a microwave oven at 600 watts for about 20 seconds to dissolve the gelatin.
10.Add (9) while mixing (8).
11.Set aside half the amount (about 200g).
12.Leave 3 plum knots from (1), put the remaining gummy candies (22g) in a heat-resistant container, and add 10g of water.
13.Heat in a microwave oven at 600W for 20 seconds to melt the gummy.
14.Add (13) to one half of (11) and mix. I colored it so that it would be light purple.
15.Pour into (4), cool in the refrigerator for less than 1 hour, and harden the surface.
16.Pour the other half of (11) into (15), cool in the refrigerator, and when the surface is about to harden, put three plum knots from (1) and harden the surface.
Make the top jelly.
17.Add 6g of powdered gelatin to 150g of hot water at about 80 ° C and dissolve.
18.Dissolve 30g of sugar in it.
19.Mix in 5g of lemon juice.
20.Pour cold (19) into (16)
21.Refrigerate and harden.
22.It's done.
Super Kyoho taste. And I was so grateful that the gummy candies could be cut with a fork.
#cheesecake #longlongman #gummy #mizuhiki
同步加速器光源中插件磁鐵的進階特性之研究
為了解決Knot 的問題,作者羅皓文 這樣論述:
本論文中研究了在現在與未來升級後的台灣光子源中三個與聚頻磁鐵技術有關的主題,第一是相位可調式聚頻磁鐵(adjustable phase undulator),有別於傳統聚頻磁鐵藉由調整磁列間隙達到改變共振光子能量的方式,相位可調式聚頻磁鐵則是改變磁列的縱向相對位置調整光子能量,然而此種操作模式在橢圓極化模式中會產生無可避免的磁場橫向梯度場(~100 T/m),此梯度場不但有機會降低同步輻射光源的品質還有可能改變儲存環中電子團的的工作條件,解析模型被提出以估計橫向梯度場對光源與電子團品質的影響,數值方法用來驗證解析模型對光源品質的估計。第二個主題是在雙極小值垂直貝塔函數(betatron fu
nction)磁格中的串聯式聚頻磁鐵,為了達到更好的聚頻磁鐵輻射與電子團的橫向相空間匹配,三個四極磁鐵被安裝在儲存環的直段中間壓低垂直貝塔函數,然而,將一台聚頻磁鐵分成兩台和插入其中的四極磁鐵都造成聚頻磁鐵輻射中額外的相位延遲與軌跡的改變,導致傳統估計聚頻磁鐵輻射品質的方法不適用於此種特殊光源,基於維格納分布函數(Wigner distribution function)的數值方法被用來計算此種光源的光源亮度,相關的主題如光源的橫向同調性與兩台聚頻磁鐵的校準也一併討論。最後一個主題是1:3利薩如曲線(Lissajous curve)式聚頻磁鐵,在傳統聚頻磁鐵中加入額外的不同週期長度磁列改變電子
軌跡,達到降低近軸區域的輻射功率分布以減輕下游光束線中光學元件的熱附載的效果,初步的概念設計說明這樣的磁場分布與大小以現有的光學元件實際上是可以達到的,推廣版的聚頻磁鐵輻射解析表達式被用來評估聚頻磁鐵輻射的品質與降低熱附載的效果並以聚頻磁鐵輻射數值計算軟體驗證。
A Christmas House Wedding
為了解決Knot 的問題,作者James, Victoria 這樣論述:
’Tis the season at The Christmas House, and Ruby Harris is getting married--but a winter storm of emotion could derail the whole affair in New York Times and USA Today bestselling author Victoria James’s second Christmas House novel.Ruby Harris, longtime owner of the historic B&B, The Christmas Hous
e, is tying the knot--on Christmas Eve! Olivia Harris is thrilled for her grandmother and can’t wait to help plan the event. Newly divorced, with an adorable baby girl, Olivia has spent the last year starting a new life in Silver Springs. First on her list is to renovate the old warehouse she’s purc
hased and launch her dance studio. Second is to find a date for the wedding. And third is to not fall for that date, because she’s sworn off relationships forever. When Olivia’s meets Scott, a talented contractor, she hires him for the renovation. She also tries to ignore the sparks that fly between
them. Then, an unexpected Christmas guest arrives: Olivia’s ex, Will, who’s come to rekindle their relationship. Now, Olivia must decide if she has it in her heart to forgive Will, or if she should pursue an exciting new relationship with Scott. Packed with Christmas cheer, this "heartwarming holid
ay romance" (Jenny Hale, on The Christmas House) will have you believing in the magic of the season. Victoria James is a New York Times and USA Today bestselling author of contemporary romance. Victoria always knew she wanted to be a writer and in grade five, she penned her first story, bound it (
with staples and a cardboard cover), and illustrated it herself. Luckily, this book will never see the light of day. After graduating University with an English Literature degree, Victoria pursued a degree in Interior Design opening her own business. Victoria is a hopeless romantic who is living her
dream, penning happily-ever-after’s for her characters in between managing kids and the family business. She lives in suburbia with her husband, their two children, and a very disgruntled cat.
抑制自縛增進高分子光電量子效率以及介面電場與量子點激發電荷之交互作用
為了解決Knot 的問題,作者魯 宣 這樣論述:
近年來放光材料如共軛高分子(conjugated polymer, CP)和量子點(quantum dot, QD)等被廣泛的應用於電子元件中,其中,CP雖然有著優秀的彈性、易加工及成本低等優點,但CP的放光效率(Quantum efficiency, QE)低迷限制了其應用發展。QD雖然在溶液態中QE極高,但用於薄膜元件中可能與基材或是基質材料產生異質介面電場,影響QE。有鑑於最近的文獻中提及透過施加應力於分子鏈段上能有效的提升CP放光強度[1-4],以及透過除潤影響膜內粒子分布[5],本篇論文將進一步研究拉伸應力導致CP的QE提升機制與其QE低迷的根本原因,以及研究異質介面電場如何影響Q
D內激發電荷,和透過除潤改變QD於膜內之分布進而提升QE。拉伸CP研究中,透過光惰性高分子polystyrene (PS)受拉伸時 產生微頸縮(纖化區)機制,拉伸共軛高分子MEH-PPV、PFO及P3HTrr,探究不同CP受拉伸應力時QE的變化。當CP分散於PS內近似於單分子狀態,且受到極限拉伸(拉伸比例~300%)時,這些CP的QE都有極大的提升,主鏈最堅硬的PFO以及次堅硬的MEH-PPV甚至達到接近100 %的QE,而主鏈最柔軟的P3HTrr雖然僅達到25%的QE,但QE增加倍率為最大的12倍。對於純CP薄膜進行拉伸,並不會有如PS一樣的纖化區產生,薄膜為均勻形變,因此單層薄膜僅能拉伸至
約20%應變,但透過雙層結構薄膜,利用下層PS產生之纖化區拉伸上層共軛高分子(應變約500%),PFO的QE能接近100%,MEH-PPV由於團聚效應僅上升至約50%,P3HTrr則因為結晶吸收應變能,QE幾乎無變化,結晶度能透過增大側鏈(P3EHT)來降低,結果也顯示拉伸後效率有著三倍的增益。這說明純CP薄膜拉伸須突破分子堆疊(packing)或分子鏈結(knot)才能有效的提高QE,且當分子鏈被極限拉伸時,QE能接近100%。接著透過飛秒時間解析光譜,觀察到MEH-PPV的激發電荷能量在兩皮秒內以〜0.03 eV / ps的速率損耗,且此損耗速率在大應力(215 MPa)時幾乎被抑制。而在
激發後也產生另一能量損耗較慢的路徑,約為兩皮秒內的10倍且不受應力影響。短時間內能量損耗來自分子鏈段的轉動,因此大拉伸應力能幾乎抑制分子鏈的轉動,而慢速損耗則與熱逸散有關的分子鏈段振動。基於此,我們認為CP未受應力時,分子鏈段的轉動會形成局部形變區拘束激發電荷,造成自縛現象(self-trapping),此為CP的QE低迷主因。電場對於QD內電荷之影響實驗中,通過摻入(1 wt%)QD的絕緣高分子薄膜中於窄能帶(Si-wafer)或寬能帶(cover glass)基材上的光致發光來研究基材能隙產生之內建電場帶來的影響。首先,QD在薄膜內的分布並不均勻,但與基材種類無關,集中於表面以及靠近基材處
,因而造成複雜的介面電場效應,且表面的聚集會產生表面遮蔽效應,使QD的放光減弱。於矽晶片上QD的放光強度隨電場增加迅速減小,我們認為在電場作用下電荷會透過QD的鏈狀結構滲透於矽晶片進行電荷淬滅(quenching)。而在玻璃上,因能隙較寬,PL因電場作用導致激子電荷分離而結合率下降,但下降受到量子侷限限制。透過除潤改變QD與基材之距離,進而影響量子點放光效率,結果顯示,10 nm薄膜除潤,QD與基材之距離增加至22~26 nm,電場效應減弱,QD放光強度於矽基材增加2.5倍,但於玻璃上變化不大。而80 nm厚膜除潤,則由於電場及表面遮蔽效應,QD放光強度於矽基材減少剩約16%,於玻璃上則下降剩
約70 %。綜合以上所述,透過抑制CP分子鏈段轉動提高QE,以及基材的選擇來調整電場對於QD的放光強度,本篇論文研究對於放光材料於光電元件中的應用具有重要意義。