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Chapter 3 second law of TMD

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PHYSICAL CHEMISTRY Chapter – Second law of TMD Dr Ngo Thanh An Chapter – Second law of thermodynamics Introduction Transferring heat to a paddle wheel will not cause it to rotate A cup of hot coffee does not get hotter in a cooler room Transferring heat to a wire will not generate electricity These processes cannot occur even though they are not in violation of the first law Chapter – Second law of thermodynamics Introduction Processes occur in a certain direction, and not in the reverse direction A process must satisfy both the first and second laws of thermodynamics to proceed MAJOR USES OF THE SECOND LAW The second law may be used to identify the direction of processes The second law also asserts that energy has quality as well as quantity The first law is concerned with the quantity of energy and the transformations of energy from one form to another with no regard to its quality The second law provides the necessary means to determine the quality as well as the degree of degradation of energy during a process The second law of thermodynamics is also used in determining the theoretical limits for the performance of commonly used engineering systems, such as heat engines and refrigerators, as well as predicting the degree of completion of chemical reactions Chapter – Second law of thermodynamics Thermal energy reservoir A source supplies energy in the form of heat, and a sink absorbs it Bodies with relatively large thermal masses can be modeled as thermal energy reservoirs • • A hypothetical body with a relatively large thermal energy capacity (mass x specific heat) that can supply or absorb finite amounts of heat without undergoing any change in temperature is called a thermal energy reservoir, or just a reservoir In practice, large bodies of water such as oceans, lakes, and rivers as well as the atmospheric air can be modeled accurately as thermal energy reservoirs because of their large thermal energy storage capabilities or thermal masses Chapter – Second law of thermodynamics Heat engine Work can always be converted to heat directly and completely, but the reverse is not true Part of the heat received by a heat engine is converted to work, while the rest is rejected to a sink The devices that convert heat to work They receive heat from a hightemperature source (solar energy, oil furnace, nuclear reactor, etc.) They convert part of this heat to work (usually in the form of a rotating shaft.) They reject the remaining waste heat to a low-temperature sink (the atmosphere, rivers, etc.) They operate on a cycle Heat engines and other cyclic devices usually involve a fluid to and from which heat is transferred while undergoing a cycle This fluid is called the working fluid Chapter – Second law of thermodynamics Thermal efficiency Schematic of a heat engine Some heat engines perform better than others (convert more of the heat they receive to work) Even the most efficient heat engines reject almost one-half of the energy they receive as waste heat Chapter – Second law of thermodynamics Can we save Qout? A heat-engine cycle cannot be completed without rejecting some heat to a low-temperature sink In a steam power plant, the condenser is the device where large quantities of waste heat is rejected to rivers, lakes, or the atmosphere Can we not just take the condenser out of the plant and save all that waste energy? The answer is, unfortunately, a firm no for the simple reason that without a heat rejection process in a condenser, the cycle cannot be completed Every heat engine must waste some energy by transferring it to a lowtemperature reservoir in order to complete the cycle, even under idealized conditions Chapter – Second law of thermodynamics 2nd law: Kelvin-Planck statement It is impossible for any device that operates on a cycle to receive heat from a single reservoir and produce a net amount of work No heat engine can have a thermal efficiency of 100 percent, or as for a power plant to operate, the working fluid must exchange heat with the environment as well as the furnace The impossibility of having a 100% efficient heat engine is not due to friction or other dissipative effects It is a limitation that applies to both the idealized and the actual heat engines A heat engine that violates the Kelvin– Planck statement of the second law Chapter – Second law of thermodynamics Refrigerator and heat pump The transfer of heat from a lowtemperature medium to a hightemperature one requires special devices called refrigerators • Refrigerators, like heat engines, are cyclic devices • The working fluid used in the refrigeration cycle is called a refrigerant • The most frequently used refrigeration cycle is the vapor-compression refrigeration cycle • Basic components of a refrigeration system and typical operating conditions In a household refrigerator, the freezer compartment where heat is absorbed by the refrigerant serves as the evaporator, and the coils usually behind the refrigerator where heat is dissipated to the kitchen air serve as the condenser Chapter – Second law of thermodynamics Coefficient of performance The efficiency of a refrigerator is expressed in terms of the coefficient of performance (COP) The objective of a refrigerator is to remove heat (QL) from the refrigerated space The objective of a refrigerator is to remove QL from the cooled space Can the value of COPR be greater than unity? Chapter – Second law of thermodynamics Statistical meaning of entropy • Number of particles: N • Arrangement: 2N • Each particle has only two possible quantum states ↑ or ↓ • Distribution: m • Total number of microstates (Ω): 2N • Total magnetic moment of all the particles is M = (N-N).à ã M just depends on the relative number of up and down moments and not on the detail of which are up or down • The relative number of ups and downs is constrained by: N↑ + N↓ = N Chapter – Second law of thermodynamics Statistical meaning of entropy Microstate: a microscopic description would necessitate specifying the state of each particle Macrostate (state) including a lot of microstate (don’t care which is up or down Just focuses on how much is up and down)  01 (State) ∝ 01 (m), which m equals N↑-N↓ Number m tell us the distribution of N particles among possible states: N↓ = (N-m)/2; N↑ = (N+m)/2  t(m): total number of microstates responding to a (macro)state: Chapter – Second law of thermodynamics Statistical meaning of entropy Chapter – Second law of thermodynamics Statistical meaning of entropy Chapter – Second law of thermodynamics The increase of entropy principle • For an isolated (or simply an adiabatic closed system), the heat transfer is zero, then ∆S = S − S = ∫     δQ T + Sgen ⇒ ∆S adiabatic = Sgen This means that the entropy of an adiabatic system during a process always increases or, In the limiting case of a reversible process, remains constant In other words, it never decreases This is called Increase of entropy principle This principle is a quantitative measure of the second law 53 Chapter – Second law of thermodynamics The increase of entropy principle • Now suppose the system is not adiabatic • We can make it adiabatic by extending the surrounding until no heat, mass, or work are crossing the boundary of the surrounding • This way, the system and its surroundings can be viewed again as an isolated system • The entropy change of an isolated system is the sum of the entropy changes of its components (the system and its surroundings), and is never less than zero • Now, let us apply the entropy balance for an isolated system: S gen = ∆Stotal = ∆S sys + ∆S surr ≥ 54 Chapter – Second law of thermodynamics Summary of the increase of entropy principle > irreversible process  S gen = reversible process < imposible process  Lưu ý: Entropy truyền vào hệ theo hình thức: truyền nhiệt, truyền khối Truyền công vào hệ không gây truyền entropy!!!!!! Chapter – Second law of thermodynamics Important remarks • Processes can occur in a certain direction only , not in any direction A process must proceed in the direction that complies with the increase of entropy principle A process that violates this principle is impossible • Entropy is a non-conserved property Entropy is conserved during the idealized reversible process only and increases during all actual processes • The performance of engineering systems is degraded by the presence of irreversibilities, and the entropy generation is a measure of the magnitude of the irreversibilities present during a process 56 Chapter – Second law of thermodynamics Entropy change for reversible processes: ∆S = S − S = ∫  δQ  T int rev  a Heating (cooling) process at constant pressure/constant volume: Isobaric process: CPdT δ QTN =∫ ∆S = ∫ T T Isochoric process: δ QTN CV dT ∆S = ∫ =∫ T T Chapter – Second law of thermodynamics Entropy change for reversible processes: ∆S = S − S = ∫  δQ  T int rev  a Heating (cooling) process at constant pressure/constant volume: Isobaric process: CPdT δ QTN =∫ ∆S = ∫ T T Isochoric process: δ QTN CV dT ∆S = ∫ =∫ T T Chapter – Second law of thermodynamics Entropy change for reversible processes: b Isothermal process: δ QTN QTN ∆S = ∫ = T T Ideal gas expansion: QT V2 P1 ∆S = = nR ln = nR ln T V1 P2 Phase transfer QT λ ∆S = = T T Chemical reaction ΔS°reaction = ΣnpS°products – ΣnrS°reactan Chapter – Second law of thermodynamics Boltzmann equation of entropy • States, S S = k lnW – The microscopic energy levels available in a system • Microstates, W – The particular way in which particles are distributed amongst the states Number of microstates = W • The Boltzmann constant, k = 1.38x10-23 J/K – Effectively the gas constant per molecule = R/NA W2 ∆S = S2 − S1 = k ln W1 Chapter – Second law of thermodynamics Absolute entropy So = lim ST = T →0 3rd law of thermodynamics: The entropy of a perfect crystal at K is zero Because: - all molecular motion stops - all particles are in their place ∆S = ST – So = ST Ví dụ: So298 entropy tuyệt đối chất atm, 298K (điều kiện chuẩn ) Xét q trình biến đổi chất sau: rắn 0(K)  → T chuyển pha ∆S1 So ∆S2 rắn  → T nóng chảy ∆S3 ∆S4 lỏng Tnóng chảy  → T hóa ∆S5 ∆S6 ∆S4 Tính ST 7  → T(K) ∆S7 ST T2 dT λ ST = So + ∑ ∆Si = ∑ ∆Si = ∑ ∫ C p +∑ T T i =1 i =1 T Ví dụ: Tính biến thiên entropy của trình đông đặc benzen áp suất atm trường hợp sau: a) Quá trình đông đặc thuận nghịch 5oC với nhiệt đông đặc λđđ = – 2370 cal/mol b) Quá trình đông đặc bất thuận nghịch – 5oC Biết nhiệt dung benzen lỏng benzen rắn 30,3 29,3 cal/mol.K

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