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The relationship between oxygen consumption and equivalent biodegradable organic removal (i.e. BOD) in a closed container with respect to time is shown in the figure.Assume that the rate of oxygen consumption is directly proportional to the amount of degradable organic matter and is expressed aswhere, L1 (in mg/litre) is the oxygen equivalent of the organics remaining at time t and k (in d–1) is the degradation rate constant. L0 is the oxygen of organic matter at time, t = 0In the above context, the correct expression isa)Lt = L0(1 – e–kt)b)BODt = L0 – Ltc)L0 = Lte–ktd)BOD5 = L5Correct answer is option 'B'. Can you explain this answer? for GATE 2024 is part of GATE preparation. The Question and answers have been prepared
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the GATE exam syllabus. Information about The relationship between oxygen consumption and equivalent biodegradable organic removal (i.e. BOD) in a closed container with respect to time is shown in the figure.Assume that the rate of oxygen consumption is directly proportional to the amount of degradable organic matter and is expressed aswhere, L1 (in mg/litre) is the oxygen equivalent of the organics remaining at time t and k (in d–1) is the degradation rate constant. L0 is the oxygen of organic matter at time, t = 0In the above context, the correct expression isa)Lt = L0(1 – e–kt)b)BODt = L0 – Ltc)L0 = Lte–ktd)BOD5 = L5Correct answer is option 'B'. Can you explain this answer? covers all topics & solutions for GATE 2024 Exam.
Find important definitions, questions, meanings, examples, exercises and tests below for The relationship between oxygen consumption and equivalent biodegradable organic removal (i.e. BOD) in a closed container with respect to time is shown in the figure.Assume that the rate of oxygen consumption is directly proportional to the amount of degradable organic matter and is expressed aswhere, L1 (in mg/litre) is the oxygen equivalent of the organics remaining at time t and k (in d–1) is the degradation rate constant. L0 is the oxygen of organic matter at time, t = 0In the above context, the correct expression isa)Lt = L0(1 – e–kt)b)BODt = L0 – Ltc)L0 = Lte–ktd)BOD5 = L5Correct answer is option 'B'. Can you explain this answer?.
Solutions for The relationship between oxygen consumption and equivalent biodegradable organic removal (i.e. BOD) in a closed container with respect to time is shown in the figure.Assume that the rate of oxygen consumption is directly proportional to the amount of degradable organic matter and is expressed aswhere, L1 (in mg/litre) is the oxygen equivalent of the organics remaining at time t and k (in d–1) is the degradation rate constant. L0 is the oxygen of organic matter at time, t = 0In the above context, the correct expression isa)Lt = L0(1 – e–kt)b)BODt = L0 – Ltc)L0 = Lte–ktd)BOD5 = L5Correct answer is option 'B'. Can you explain this answer? in English & in Hindi are available as part of our courses for GATE.
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Here you can find the meaning of The relationship between oxygen consumption and equivalent biodegradable organic removal (i.e. BOD) in a closed container with respect to time is shown in the figure.Assume that the rate of oxygen consumption is directly proportional to the amount of degradable organic matter and is expressed aswhere, L1 (in mg/litre) is the oxygen equivalent of the organics remaining at time t and k (in d–1) is the degradation rate constant. L0 is the oxygen of organic matter at time, t = 0In the above context, the correct expression isa)Lt = L0(1 – e–kt)b)BODt = L0 – Ltc)L0 = Lte–ktd)BOD5 = L5Correct answer is option 'B'. Can you explain this answer? defined & explained in the simplest way possible. Besides giving the explanation of
The relationship between oxygen consumption and equivalent biodegradable organic removal (i.e. BOD) in a closed container with respect to time is shown in the figure.Assume that the rate of oxygen consumption is directly proportional to the amount of degradable organic matter and is expressed aswhere, L1 (in mg/litre) is the oxygen equivalent of the organics remaining at time t and k (in d–1) is the degradation rate constant. L0 is the oxygen of organic matter at time, t = 0In the above context, the correct expression isa)Lt = L0(1 – e–kt)b)BODt = L0 – Ltc)L0 = Lte–ktd)BOD5 = L5Correct answer is option 'B'. Can you explain this answer?, a detailed solution for The relationship between oxygen consumption and equivalent biodegradable organic removal (i.e. BOD) in a closed container with respect to time is shown in the figure.Assume that the rate of oxygen consumption is directly proportional to the amount of degradable organic matter and is expressed aswhere, L1 (in mg/litre) is the oxygen equivalent of the organics remaining at time t and k (in d–1) is the degradation rate constant. L0 is the oxygen of organic matter at time, t = 0In the above context, the correct expression isa)Lt = L0(1 – e–kt)b)BODt = L0 – Ltc)L0 = Lte–ktd)BOD5 = L5Correct answer is option 'B'. Can you explain this answer? has been provided alongside types of The relationship between oxygen consumption and equivalent biodegradable organic removal (i.e. BOD) in a closed container with respect to time is shown in the figure.Assume that the rate of oxygen consumption is directly proportional to the amount of degradable organic matter and is expressed aswhere, L1 (in mg/litre) is the oxygen equivalent of the organics remaining at time t and k (in d–1) is the degradation rate constant. L0 is the oxygen of organic matter at time, t = 0In the above context, the correct expression isa)Lt = L0(1 – e–kt)b)BODt = L0 – Ltc)L0 = Lte–ktd)BOD5 = L5Correct answer is option 'B'. Can you explain this answer? theory, EduRev gives you an
ample number of questions to practice The relationship between oxygen consumption and equivalent biodegradable organic removal (i.e. BOD) in a closed container with respect to time is shown in the figure.Assume that the rate of oxygen consumption is directly proportional to the amount of degradable organic matter and is expressed aswhere, L1 (in mg/litre) is the oxygen equivalent of the organics remaining at time t and k (in d–1) is the degradation rate constant. L0 is the oxygen of organic matter at time, t = 0In the above context, the correct expression isa)Lt = L0(1 – e–kt)b)BODt = L0 – Ltc)L0 = Lte–ktd)BOD5 = L5Correct answer is option 'B'. Can you explain this answer? tests, examples and also practice GATE tests.