Assignment OI Physics-[1]

Need help with the attached question, please help with all parts of the question.

MECT361 Mechatronics Components and Instrumentation PLEASE GIVE ME THE short answer and wite it by keyword thanks

CCB 231/ CCB 211: Materials Science for Engineers Assignment I Question 1: Convert the following Miller indices to directions and sketch the directions within a cubic unit cell: (a) [301] (b) [301] (c) [301] (d) [122] (e) [122] [122] (g) [111] (h) [111] (i) [111] V) [111]

1 【Recommend】 Directly edit text and image in PDF Edit Question 1: University of Botswana Department of Mechanical Engineering Faculty of Engineering and Technology 2024/2025 session Semester I CCB 231/ CCB 211: Materials Science for Engineers Assignment I Due Date: 04/09/2024 Due Time: 14:00 Convert the following Miller indices to directions and sketch the directions within a cubic unit cell: (a) [301] (b) [301] (c) [301] (d) [122] (e) [122] [122] (g) [111] (h) [111] (i) [111] (j) [111] Question 2: The change of SO3 concentration with time is shown in Table 1. [C] t(s) 0 1.000000 100 0.778801 200 0.606531 300 0.472367 400 0.367879 500 0.286505 600 0.223130 800 0.135335 1000 0.082085 1200 0.049787 The process is governed by the rate law given by the equation: = In (SO3)-kt+In (SO3)-0 Where k is the rate constant and t is the time, and In is natural logarithm. By calculating the corresponding values of In[SO3] and plotting the graph of In [SO3] against time, t, determine the rate…

Orange light of wavelength 0.61 µm in air enters a block of glass with &r=1.44. What color would it appear to a sensor embedded in the glass? The wavelength ranges of colors are violet (0.39 to 0.45 µm), blue (0.45 to 0.49 µm), green (0.49 to 0.58 µm), yellow (0.58 to 0.60 µm), orange (0.60 to 0.62 µm), and red (0.62 to 0.78 μm).

What is the angle of incidence of the radio wave signal as it moves from air to glass (relative permittivity of glass is 7.8), if the angle of refraction is 8.2° ?(Use 2 decimal places for the final answer) a) Calculate the EIRP in dBm b) Calculate the power density (µW/m^2) at distance of 10km.

(Ch 23 HW C Exercise 23.28 A concave mirror is constructed so that a man at a distance of 30 cm from the mirror sees his image magnified 2.0 times. Part A R What is the radius of curvature of the mirror? Express your answer using two significant figures. V < 9 of 11 ΑΣΦ Review | Constants | Periodic Table www P ? cin

Option: -SC plane 110 -SC plane 100 -FCC plane 111 -SC plane 111 -FCC plane 110 -BCC plane 100 -BCC plane 111 -FCC plane 100 -None of the provided choices -BCC plane 110   could you please tell me how to get the answer

Question 4 The following diagram shows the basic structure of the gamma camera used for medical imaging to data-logger and computer Photomultiplier tube Sodium iodide crystal Lead grating Describe how the gamma camera detects gamma rays allowing the production of images. [Suggested word count 130] [2.1]

Hello. I was wondering if I could get help on a study question I am struggling with for my material science class. I would appreciate the help. Thanks.

These graphs show the effect of temperature on oxygen, beryllium and vanadium atoms moving through an iron sample. Which graph represents oxygen moving through iron? Atom Atomic radius (pm) Охуgen 66 In D Beryllium 96 C Vanadium 135 Iron 132 A O1. C O II. A III. B O O

Please answer within one hr i will give good rating.

Chap 1

The attached photo shows the Young’s modulus of a cubic single crystal as a function of orientation. where a1 a2 and a3 are the direction cosines between the direction hkl and [100], [010], and [001], respectively. For a certain crystal, E111 = 500 GPa and E100 = 90 GPa. Calculate Young’s modulus for this single crystal in the <110> direction

Don't Use Chat GPT Will Upvote And Give Handwritten Solution Please

Don't Use Chat GPT Will Upvote And Give Handwritten Solution Please

When waves approach an irregular shoreline, do the waves refract (bend) towards the parts of the coastline that stick out  (headlands/shallower water)?   Or do the waves refract (bend) towards the parts of the coastline that are recessed  (bays/deeper water)?   choose one Waves do not refract (bend) along irregular shorelines. Waves refract (bend) toward bays/deeper water Actually wave refraction (bending) depends on water temperature - not water depth. Waves refract (bend) toward headlands/shallower water.

Table 3.4 Modulus of Elasticity Values for Several Metals at Various Crystallographic Orientations Modulus of Elasticity (GPa) Metal [100] [110] [111] Aluminum 63.7 72.6 76.1 Copper 66.7 130.3 191.1 Iron 125.0 210.5 272.7 Tungsten 384.6 384.6 384.6 a) What is E0) for iron in GPa? Use Ej00) and Eu1) data from Table 3.4 to solve this problem. b) What is the value in Table 3.4 in GPa? a) i GPa b) i GPa

6) Draw the directions within the unit cells provided. 9a) [ 1 2 Ī] 9b) [ 171 3]

A woman wears bifocal glasses with the lenses 2.0 cm in front of her eyes. The upper half of each lens has power -0.500 diopter and corrects her far vision so that she can focus clearly on distant objects when looking through that half. The lower half of each lens has power +2.00 diopters and corrects her near vision when she looks through that half. (a) What are the far point and near point of her eyes? (b) While the woman is repairing a leaky pipe under her kitchen sink, she looks at close objects through the upper half of her bifocal lenses. What is the closest object that she can see clearly?

Quastions about renewable

(a) An infrared gas analyser has a span of 01% of the component being measured. It operates at atmospheric pressure and was calibrated when the barometric pressure was 0.995 bar. The barometric pressure changes to 1.015 bar. What will the instrument read when the actual percentage of the component is (i) 0.5% (ii) 0.8%?

The graph below shows the absorption spectra of a substance to determine the optimal wavelength. Based on the graph shown below, what value is considered the optimal wavelength for Molecule 1 to measure absorbance? Absorption 0.851, 0.800 0.600 0.400 A 0.0 251.97 300.00 0.851 0.400 280 395 400.00 500.00 Wavelength, nm 600.00 696.03