km/h to m/s公式的問題，透過圖書和論文來找解法和答案更準確安心。 我們找到下列各種有用的問答集和懶人包

Galaxies in the Local Volume

為了解決km/h to m/s公式的問題，作者Koribalski, B. s. (EDT)/ Jerjen, H. (EDT) 這樣論述：

The Local Volume' (ie, the sphere of radius 10 Mpc centered on the Local Group) is known to contain at least 500 known galaxies, many of which congregate in well-known groups like the Local Group, the relatively loose Sculptor Group, and the more compact Centaurus A group. Accurate distances are no

w available for the majority of these nearby galaxies, allowing us to visualise the Local Volume in 3D, study the local Hubble flow and its dispersion, the (baryonic) Tully-Fisher relation, the local star formation density, etc. Individual galaxies in the Local Volume can be studied in amazing detai

l across a large range of wavelengths (some stunning examples are compiled in the Multiwavelength Astronomy pages).The first catalog of galaxies within 10 Mpc was compiled by Kraan-Korteweg & Tammann (1979); it contained 179 galaxies. Following numerous updates, the latest Catalog of Neighboring Ga

laxies' was presented by Karachentsev et al. (2004); it contains 451 galaxies. They find that about 85% of the LV population are dwarf galaxies which contribute approx. 4% to the local optical luminosity density and roughly 10-15% to the local HI mass density. For the majority of galaxies within 8 M

pc we currently have quite reliable, independent distance estimates either from the luminosity of Cepheids, the tip of the red giant branch (TRGB), or surface brightness fluctuations (SBF).Several large surveys of nearby galaxies have recently been carried out or are in progress. E.g., The Westerbo

rk observations of neutral Hydrogen in Irregular and SPiral galaxies' (WHISP, Swaters et al. 2002), which is based on the Uppsala General Catalogue of Galaxies (UGC; Nielson 1973), provides HI distributions and velocity fields of about 200 gas-rich galaxies with declinations larger than +20 degrees

and velocities less than 2000 km/s. This is complemented by The Ha Galaxy Survey' (HaGS; James et al. 2004), also based on the UGC, which provides star formation parameters for a large number of mostly northern galaxies. The HI Nearby Galaxy Survey' (THINGS; Walter, Brinks, de Blok et al. 2004), w

hich provides high-resolution HI imaging of initially 36 galaxies with declinations larger than -30 degrees, has just been completed at the Very Large Array (VLA). The THINGS sample is targeting galaxies from The Spitzer Nearby Galaxies Survey' (SINGS, Kennicutt et al. 2003), a comprehensive infrar

ed imaging and spectroscopic survey of 75 nearby galaxies with distances less than 30 Mpc, as well as key objects from the Spitzer GTO list. SINGS is supplemented by high-resolution studies at many other wavelengths covering the entire spectrum from X-ray to radio. Another multi-wavelength study is

The Survey for Ionization in Neutral Gas Galaxies' (SINGG, Meurer et al. 2006, Hanish et al. 2006), the largest star formation survey of an HI-selected sample (based on The HI Parkes All-Sky Survey', HIPASS) and its sister surveys SUNGG and SONGG, based on GALEX ultraviolet and Spitzer infrared ob

servations, respectively. Surveys of nearby galaxies currently underway in Australia include The Galactic All Sky Survey' (GASS), obtained with the Parkes 64-m telescope, The Local Volume HI Survey' (LVHIS), obtained with the Australia Telescope Compact Array (ATCA), and the Local Sphere of Influ

ence H-band survey' (LSI), obtained with the Anglo-Australian Telescope (AAT).Given the many recent advances in our understanding of the star formation and ISM composition of nearby galaxies and more generally in the field of Near-Field Cosmology', which are mostly based on the large amounts and su

perb quality of new ground- and space-based multi-wavelength data, it is timely to hold a conference on the subject and review the Local Volume by combining observations, simulations and theoretical developments. We hope to provide a vibrant forum for presentations and discussions accross a broad ra

nge of astrophysical topics, including what may be possible with future facilities such as the Atacama Large Millimeter Array (ALMA), and the international Square Kilometre Array (SKA). B.S. Koribalski (Physics Diploma and PhD from the University of Bonn, Germany; now Senior Research Scientist at

the CSIRO Australia Telescope National Facility; PI of the ＂Local Volume HI Survey＂ (LVHIS), etc.)

納米薄膜分析基礎（英文版）

為了解決km/h to m/s公式的問題，作者[美]阿爾弗德（AlfordT.L.）等 編著 這樣論述：

現代科學技術（從材料科學到集成電路）已深入到納米層次。從薄膜到場效應傳感器，研究的重點是如何把尺度從微米量級減小到納米量級。納米薄膜分析一書主要研究了材料表面及從表面到幾十乃至100納米深的結構與構成。主要討論了用入射粒子和光子來量化結構並進行成分和深度分析的材料表征方法。　　本書討論了通過入射光子或粒子刻蝕納米材料來表征材料的方法，入射的粒子能夠激發出可測的粒子或光子，這正是表征材料的依據，納米尺度材料分析實驗會用到大量入射粒子與待測粒子束的相互作用。其中較重要的有原子碰撞、盧瑟福背散射、離子遂道、衍射、光子吸收、輻射與非輻射陽縣躍遷以及核反應。本書詳細介紹了各種分析和掃描探針顯微技術。

Preface1. An Overview：Concepts，Units，and the Bohr Atom1.1 Introduction1.2 Nomenclature1.3 Energies，Units，and Particles1.4 Particle-Wave Duality and Lattice Spacing1.5 The Bohr ModelProblems2. Atomic Collisions and Backscattering Spectrometry2.1 Introduction2.2 Kinematics of Elastic Collisio

ns2.3 Rutherford Backscattering Spectrometry2.4 Scattering Cross Section and Impact Parameter2.5 Central Force Scattering2.6 Scattering Cross Section：Two-Body2.7 Deviations from Rutherford Scattering at Low and High Energy2.8 Low-Energy Ion Scattering2.9 Forward Recoil Spectrometry2.10 Center of Mas

s to Laboratory TransformationProblems3. Energy Loss of Light Ions and Backscattering Depth Profiles3.1 Introduction3.2 General Picture of Energy Loss and Units of Energy Loss3.3 Energy Loss of MeV Light Ions in Solids3.4 Energy Loss in Compounds Bragg’’s Rule3.5 The Energy Width in Backscattering3.

6 The Shape of the Backscattering Spectrum3.7 Depth Profiles with Rutherford Scattering3.8 Depth Resolution and Energy-Loss Straggling3.9 Hydrogen and Deuterium Depth Profiles3.10 Ranges of H and He Ions3.11 Sputtering and Limits to Sensitivity3.12 Summary of Scattering RelationsProblems4. Sputter D

epth Profiles and Secondary Ion Mass Spectroscopy4.1 Introduction4.2 Sputtering by Ion Bombardment—General Concepts4.3 Nuclear Energy Loss4.4 Sputtering Yield4.5 Secondary Ion Mass Spectroscopy (SIMS)4.6 Secondary Neutral Mass Spectroscopy (SNMS) 4.7 Preferential Sputtering and Depth Profiles4.8 Int

erface Broadening and Ion Mixing4.9 Thomas-Fermi Statistical Model of the AtomProblems5. Ion Channeling5.1 Introduction5.2 Channeling in Single Crystals5.3 Lattice Location of Impurities in Crystals5.4 Channeling Flux Distributions 895.5 Surface Interaction via a Two-Atom Model5.6 The Surface Peak5.

7 Substrate Shadowing：Epitaxial Au on Ag(111) 5.8 Epitaxial Growth5.9 Thin Film AnalysisProblems6. Electron-Electron Interactions and the Depth Sensitivity of Electron Spectroscopies6.1 Introduction6.2 Electron Spectroscopies：Energy Analysis6.3 Escape Depth and Detected Volume6.4 Inelastic Electron-

Electron Collisions6.5 Electron Impact Ionization Cross Section6.6 Plasmons6.7 The Electron Mean Free Path6.8 Influence of Thin Film Morphology on Electron Attenuation6.9 Range of Electrons in Solids6.10 Electron Energy Loss Spectroscopy (EELS)6.11 BremsstrahlungProblems7. X-ray Diffraction7.1 Intro

duction7.2 Bragg’’s Law in Real Space7.3 Coefficient of Thermal Expansion Measurements7.4 Texture Measurements in Polycrystalline Thin Films7.5 Strain Measurements in Epitaxial Layers7.6 Crystalline Structure7.7 Allowed Reflections and Relative IntensitiesProblems8. Electron Diffraction8.1 Introduct

ion8.2 Reciprocal Space8.3 Laue Equations8.4 Bragg’’s Law8.5 Ewald Sphere Synthesis8.6 The Electron Microscope8.7 Indexing Diffraction PatternsProblems9. Photon Absorption in Solids and EXAFS9.1 Introduction9.2 The Schrodinger Equation9.3 Wave Functions9.4 Quantum Numbers，Electron Configuration,and

Notation9.5 Transition Probability9.6 Photoelectric Effect Square-Well Approximation9.7 Photoelectric Transition Probability for a Hydrogenic Atom9.8 X-ray Absorption9.9 Extended X-ray Absorption Fine Structure (EXAFS)9.10 Time-Dependent Perturbation TheoryProblems10. X-ray Photoelectron Spectroscop

y10.1 Introduction10.2 Experimental Considerations10.3 Kinetic Energy of Photoelectrons10.4 Photoelectron Energy Spectrum10.5 Binding Energy and Final-State Effects10.6 Binding Energy Shifts—Chemical Shifts10.7 Quantitative AnalysisProblems11. Radiative Transitions and the Electron Microprobe11.1 In

troduction11.2 Nomenclature in X-Ray Spectroscopy11.3 Dipole Selection Rules11.4 Electron Microprobe11.5 Transition Rate for Spontaneous Emission11.6 Transition Rate for Kα Emission in Ni11.7 Electron Microprobe：Quantitative Analysis11.8 Particle-Induced X-Ray Emission (PIXE)11.9 Evaluation of the T

ransition Probability for Radiative Transitions11.10 Calculation of the Kβ/Kα RatioProblems12. Nonradiative Transitions and Auger Electron Spectroscopy12.1 Introduction12.2 Auger Transitions12.3 Yield of Auger Electrons and Fluorescence Yield12.4 Atomic Level Width and Lifetimes12.5 Auger Electron S

pectroscopy12.6 Quantitative Analysis12.7 Auger Depth ProfilesProblems13. Nuclear Techniques：Activation Analysis and Prompt Radiation Analysis13.1 Introduction13.2 Q Values and Kinetic Energies13.3 Radioactive Decay13.4 Radioactive Decay Law13.5 Radionuclide Production13.6 Activation Analysis13.7 Pr

ompt Radiation AnalysisProblems14. Scanning Probe Microscopy14.1 Introduction14.2 Scanning Tunneling Microscopy14.3 Atomic Force MicroscopyAppendix 1. Km for 4He+ as Projectile and Integer Target MassAppendix 2. Rutherford Scattering Cross Section of the Elements for 1 MeV4HeiAppendix 3. 4He+ Stoppi

ng Cross SectionsAppendix 4. Electron Configurations and Ionization Potentials of AtomsAppendix 5. Atomic Scattering FactorsAppendix 6. Electron Binding EnergiesAppendix 7. X-Ray Wavelengths (nm)Appendix 8. Mass Absorption Coefficient and DensitiesAppendix 9. KLL Auger Energies (eV)Appendix 10. Tabl

e of the ElementsAppendix 11. Table of Fluoresence Yields for K，L，and M ShellsAppendix 12. Physical Constants，Conversions，and Useful CombinationsAppendix 13. AcronymsIndex 對於國內的物理學工作者和青年學生來講，研讀國外優秀的物理學著作是系統掌握物理學知識的一個重要手段。但是，在國內並不能及時、方便地買到國外的圖書，且國外圖書不菲的價格往往令國內的讀者卻步，因此，把國外的優秀物理原著引進到國內，讓國內的讀者

能夠方便地以較低的價格購買是一項意義深遠的工作，將有助於國內物理學工作者和青年學生掌握國際物理學的前沿知識，進而推動我國物理學科研和教學的發展。 為了滿足國內讀者對國外優秀物理學著作的需求，科學出版社啟動了引進國外優秀著作的工作，出版社這一舉措得到了國內物理學界的積極響應和支持，很快成立了專家委員會，開展了選題的推薦和篩選工作，在出版社初造的書單基礎上確定了第一批引進的項目，這些圖書幾乎涉及了近代物理學的所有領域，既有闡述學科基本理論的經典名著，也有反映某一學科專題前沿的專著。在選擇圖書時，專家委員會遵循了以下原則：基礎理論方面的圖書強調「經典」，選擇了那些經得起時間檢驗、對物理學的發展

產生重要影響、現在還不「過時」的著作（如：狄拉克的《量子力學原理》）。反映物理學某一領域進展的著作強調「前沿」和「熱點」，根據國內物理學研究發展的實際情況，選擇了能夠體現相關學科最新進展，對有關方向的科研人員和研究生有重要參考價值的圖書。這些圖書都是最新版的，多數圖書都是2000年以后出版的，還有相當一部分是2006年出版的新書。因此，這套叢書具有權威性、前瞻性和應用性強的特點。由於國外出版社的要求，科學出版社對部分圖書進行了少量的翻譯和注釋（並且是目錄標題和練習題），但這並不會影響圖書「原汁原味」的感覺，可能還會方便國內讀者的閱讀和理解。 「他山之石，可以攻玉」，希望這套叢書的出版能夠為

國內物理學工作者和青年學生的工作和學習提供參考，也希望國內更多專家參與到這一工作中來，推薦更多的好書。

組織同形化與動態能力對電商營運模式之探討 ：以外貿廠商為例

為了解決km/h to m/s公式的問題，作者黃偉誠 這樣論述：

近年來行動科技的普及，使電子商務不但改變了消費方式，更帶動全球B2B和B2C電商市場規模急速成長，甚至改變全球交易行為和商業模式，更因為新冠疫情肆虐催化下，以致加速全球電子商務發展的腳步和節奏，使各電子商務平台迅速成長崛起，消費者需求越來越難以捉摸，使同業間的競爭越來越激烈，加上因為賣家數量的增加，使電商市場呈現出同質化現象越來越嚴重，投入跨境電商之企業趨同形現象發展，其中同形化範疇含括了物流、品牌行銷、廣告、數據分析、通路、零售及店舖經營、媒體、創意、人才培養等多方面，同形化市場加速了廠商間競爭窘境。有鑑於此，本研究欲探討外貿廠商投入電商營運活動中，在網路行銷、關鍵字規劃與分析、數據分析、

文案與數位媒體行銷等方式趨向模仿同形時，如何在同形化的電商市場中審視自身資源，充分發揮企業動態能力，打造自身差異化，進而擬訂營運模式。本研究採個案訪談法，共訪談五家曾獲得電子商務成就或優異表現之個案公司，探討個案廠商投入電商營運之動機，並如何從市場同形化過程中找出企業營運模式和發展動態能力以增加企業生存機會。本研究結果發現，在組織同形的跨境電商市場中，個案企業在投入跨境電商皆會使用投放廣告、官網SEO、Google關鍵字、Google ads、影音行銷商品影片在間接與平台一同串連，來達到曝光度最大化；平台選擇上，發現皆以阿里巴巴國際站為主要使用的跨境電商平台，因為阿里巴巴國際站長年開設客製化的

企業培訓課程輔助台灣中小企業邁入外貿，上述皆是在高度競爭同形化的電商市場中必須做的事情；最後真正突破同形化的關鍵為企業不斷增進自身企業能力以及審視整體市場來調整自身策略，進而從同形化中異形出自身公司的電商DNA，顯示出其企業自身差異化，達到企業的永續經營，在跨境電商市場之競爭趨向同形的現象中真正脫穎而出關鍵。本研究期能透過此研究，讓中小企業了解跨境電商之營運模式，讓有意轉型之中小企業了解企業在同形化市場當中具備之電商思維態度與能力，且需能與時俱進的調整營運方式，以追求企業成長和發展。