為什麼[A(org)]=n[An(org)]成立 (第三張圖equation 7.9) 感謝

Experiment 7 Experiment 7 The partition of Organic acid between Water and Organic solvent Objectives Understand the partition of a solute between two immiscible solvents. Introduction A chemical analysis that is performed primarily with the aid of volumetric glassware (e.g., pipets, burets, volumetric flasks) is called a volumetric analysis. For a volumetric analysis procedure, a known quantity or a carefully measured amount of one substance reacts with a to-be-determined amount of another substance with the reaction occurring in aqueous solution. The volumes of all solutions are carefully measured with volumetric glassware. The known amount of the substance for an analysis is generally measured and available in two ways: 1. As a primary standard: An accurate mass (and thus, moles) of a solid substance is measured on a balance, dissolved in water, and then reacted with the substance being analyzed. 2. As a standard solution: A measured number of moles of substance is present in a measured volume of solution - a solution of known concentration, generally expressed as the molar concentration (or molarity) of the substance. A measured volume of the standard solution then reacts with the substance being analyzed. The reaction of the known substance with the substance to be analyzed, occurring in aqueous solution, is generally conducted by a titration procedure. The titration procedure required a buret to dispense a liquid, called the titrant, into a flask containing the analyte. A reaction is complete when stoichiometric amounts of the reacting substances are combined. In a titration this is the stoichiometric point. In this experiment the stoichiometric point for the acid-base titration is detected using a phenolphthalein indicator. Phenolphthalein is colorless in an acidic solution but pink in a basic solution. The point in the titration at which the phenolphthalein changes color is called the endpoint of the indicator. Indicators are selected so that the stoichiometric point in the titration coincides (at approximately the same pH) with the endpoint of the indicator.

化學問題，感謝。

100 dəsə bas,bosibindyd--q² 018 anogentia diod Cyclooctatetraene readily reacts with potassium metal to form the stable cyclooctatetraene dianion, CgHg²-. Why do you suppose this reaction occurs so easily? What geometry do you expect for the cyclooctatetraene dianion? ød an isqe ali toeleno o aejudium ludivinos andren has12- 72-idvd-Squ d-qe wol edt to low) odi 29fuis reportin besibirdyd al.e-anushistidan s asiq 2 K 2K+ golon

請問有人會這三題嗎

= 1x 10⁰ p -45. Perform the following unit conversions. meme a. Congratulations! You and your spouse are the proud parents of a new baby, born while you are studying in a country that uses the metric system. The nurse has gibre informed you that the baby weighs 3.91 kg and measures 51.4 cm. Convert your baby's weight to pounds and to ou ounces and her length to inches (rounded to the nearest 3.91 quarter inch). 4536 =8 9.9102 10 20. 2 in, 2b. The circumference of the earth is 25,000 mi at the equa- tor. What is the circumference in kilometers? in meters? 三 c.) A rectangular solid measures 1.0 m by 5.6 cm by 2.1 dm. Express its volume in cubic meters, liters, cubic inches, and cubic feet.

分析化學 拜託好心人士可以教教我🙏 高職畢業沒有基礎 老師又沒有教怎麼算 自己讀過還是看不懂🥲

22 分析化學 習題五 1.依據下列反應,以酸的式量的分數或倍數表示其當量: UHSOX+KOH-KHSO+HO (b2LOH + H.PO-Li HPO+2HO (c) Ba(OH)+2H1O, Ba(10)+2H.O id Na CO,+2HCICO+ HO+2NaCl 52 計算下列的毫當量數: (fw HSO) (fw H.PO/2) (fw HIO) (fw HC) (a)06498克的HgO,作爲滴定酸的一級標準: HgO+2HO° +4Br=HgBr²+3HO (07644克的AgNO作路硼氫的還原劑: 8Ag¹+BH +80H 8Ag+H.BO, +5H₂O (c)04602克NaH.PO+2HO發生下列反應: H.PO. +OHHPO (295) 53 500ml水溶液含921g K.Fe(CN),用下列方式表示溶液的濃度: (0.06M) (a)莫耳分析濃度 (blkº莫耳濃度 (02M) (c)關於下列反應的當量濃度 MnO+5Fe(CN) +8H" == Mn'" +5Fe(CN)+4HO【006M) 54 將877g KH(10)溶於水配成500ml溶液,用下列方式表示溶液的 (a)莫耳分析濃度 [0045M] 〔0.09M] (BIO 莫耳濃度 (c)用作酸的當量酒度 [0045M] (①用作下列反應之氧化劑的當量濃度 JO"+HNNE+2H' +2C=IC +N+3HO (0361) 5-5配製1000ml的004N KI溶液,需多少克KI? (a)氧化成 (664) (60) 第三篇 第五章 容量分析简介 243 (0.83g) (0.204g) (0.208g) (0.308g) (0.384g) (0.048g) [0153g] (1198) (135g) (1418) (18.8ml) (18.8ml) (22.4ml) (51.69ml) (28.78m1) (bIT 氧化成ION 56在48600m170005N溶液中含有多少克洛買? GalNaHCO (b) Ba(OH) (c)(產物IC) (d) Na.S.O. (S.o/ ) {elNaSO(產物SOP) (NaSO(或物SOF) 57 由下列試劑配製滴定濃度 40mgHNO/ml的溶液25000ml la) KOH UKI(產物NO及L) (KMnO(產物NO"及Mn") 团Ce(SO)(產物NO"及Ce") 58 計算0112N NaOH與下列溶液反應所需之體積 (a)2500ml的 0.084NHCIOL (b) 25.00m10 0.064N H.SO. (c)09783g的KH(IO) (d)03126g的H.COHO(產物CO) e04448g的NaH.POHO (產物HPO)

物化題目 拜託求解🙏

²A-Hmº (H₂O), 298.15 K) = -241.83 kJ/mole, Smᵒ (H₂O(g), 298.15 K)- 188.72 J/mole.K, 25°C% Smo (H2(g),298.15 K) = 130.59 J/mole.K, Smº (O2(g),298.15 K) = 205.03 J/mole.K. 態水的飽和蒸汽壓為3167.74 Pa, Vm (H2O(n)) = 18 L/mole, 試判斷在標準狀態下, H2(g) + 1/2 O2(g) ↔ H2O① 反應是否可自發進行?

請問B為何沒有異構物？ 不是有fac/mer嗎？

3. 下列哪一個配位化合物有異構物(isomer)存在? (A) [Co(H2O) C1] (B) [Pt(NH3)Brz] ) (C) [Pt(en)Cl2] (D) [Pt(NH3)3C1] 私醫 104 (13) 答案:(A) 解析: [Co(H2O) C12] # cistotrans ta ki 11 ***** C1 HO. 1 OH OH2 H2O. OH Co H2O | Ci C1 HOT OH2 Cl cis isomer trans isomer

我的實驗…. 求誤差原因可能是啥🤨

+ Z Ž T & F M 2 22 h 6,5 kcal/meler, 討論亥驗值理論值之間產生誤差的原因。

求這兩題詳解～😢😢

- ons is nilot od plass lo gorol arai (s) 29vom Sion los = 9 ) A 170 kg crate hangs from the end of affope of length L = 12.0 m. You push 人 horizontally on the crate with a varying force É to move it distance d = 3.50 m to L the side (Fig. 7-20). (a) What is the mag- nitude of † when the crate is in this final position? During the crate's displace-lid 250 bisw ment, what are (b) the total work done 32 on it, (c) the work done by the grav- 16 Hoold itational force on the crate, and (d) the kd work done by the pull on the crate from the rope? (e) Knowing that the crate is Figure 7-20 Problem 9. motionless before and after its displace- ment, use the answers to (b), (c), and (d) to find the work force + does on the crate. (f) Why is the work of your force not . ( equal to the product of the horizontal displacement and the answer to (a)? - -- your

請問 這些步驟的反應機構怎麼畫

b) Bno OBN Bng. OBn 7 steps 17-19 "OH Bno Bno Cbz 9 (285) 8

求解答案是否正確

Multiple-choice questions: (70 points) write the letter of statement that is not true: 1. A.B.U The Drude Model: (a) It is a classical approach using concepts from the kinetic theory of gases. (b) A relaxation-time approximation is used where the probability of collision is l/t. (c) No forces act on the electrons in between collisions. (d) It predicts accurately the electronic heat capacity of metals. 2. The Sommerfeld Model: (a) The crystal potential is replaced by an average Coulomb potential. (b) The separation of states is so close that a continuum model can be applied. (c) The electrons are highly localized due to a strong crystal potential. (Q) The energy of the highest occupied state at 0 K is the Fermi energy. 3. Density of states in k-space, N(k): (a) N(k) is determined by the boundary value conditions. (b) For lattices in any dimensions, N(k) is constant in k-space. (C) N(k) depends on the direction and magnitude of k. (d) It is directly proportional to the volume of the crystal. E影響, c 4. The Fermi surface of a metal: (a) is responsible for many of the transport properties of the metal, (b) depends on the nature of the chemical bonds, (c) is always a sphere, (d) can involve mixing of electron orbitals. ✓ 5. The conductivity of a material () increases with the mobility of its carriers, (b) increases with the density of carriers, (C) it is inversely proportional to the energy gap. cogu changes with temperature. 6. BID Plasmons: (a) They are an important characteristic of the Sommerfeld electron gas model. (b) Plasmons occur spontaneously in metals. (c) They are related to charge density oscillations. (d) The Plasmon energy is typically of the order of 10 eV. The Fermi energy Ef in intrinsic semiconductors 8) is usually close to y E, at OK (b) it ACiD. can increase or decrease with temperature depending on the ratio of hole and electron effective masses, (c) it represents the point at which the probability of occupation is 12, even though there may not been any states with that energy, (d) its value relative to the electronic bands must remain unaffected in the presence of defects or interfaces.