Answer:
ΔG = -1366KJ/mol
Explanation:
The detailed step by step calculation is as shown in the attachment.
The relationship between ΔG, Temperature, gas constant and the reaction quotient was applied.
Answer: P2 = 0.858 atm
Explanation:
Use the combined gas law: P1V1/T1 = P2V2/T2,
where the subscripts are the initial (1) and final (2) states. Temperature must be in Kelvin. We want P2, so rearrange the equation to solve for P2:
P2 = P1(V1/V2)(T2/T1)
Note how I've arranged the volume and temperature values: as ratios. Now it is easy to cancel units and see what is going to happen to the pressure if we lower the temperature. Since the pressure change is a function of (T2/T1), and we are lowering the temperature (T2), we'd expect this to decrease the pressure.
No information is given on volume, so we'll assume a convenient value of 1 liter. Now enter the data:
P2 = (0.917atm)*(1)*(322K/344K)
P2 = 0.858 atm
Answer: temperature.
Explanation:
This is the relationship between energy, heat, and temperature.
Thermal energy, or heat energy, is the transference of the kinetic energy of the molecules of matter from a warmer matter to a cooler one.
The particles (molecules) of matter are in constant motion, either translating or vibrating or both. Kinetic energy is the energy related to the motion (KE = 1/2 × mass × speed²): the faster the molecules vibrate or translate the higher the average knietic energy.
Temperature is the measure of how cold or hot a substance it. The temperature is, indeed, a measure of the average kinetic energy of the molecules in the matter.
Explanation:
Haemoglobin consists of heme unit which is comprised of an <u></u> and porphyrin ring. The ring has four pyrrole molecules which are linked to the iron ion. In oxyhaemoglobin, the iron has coordinates with four nitrogen atoms and one to the F8 histidine residue and the sixth one to the oxygen. In deoxyhaemoglobin, the ion is displaced out of the ring by 0.4 Å.
The prosthetic group of hemoglobin and myoglobin is - <u>Heme</u>
The organic ring component of heme is - <u>Porphyrin</u>
Under normal conditions, the central atom of heme is - <u></u>
In <u>deoxyhemoglobin</u> , the central iron atom is displaced 0.4 Å out of the plane of the porphyrin ring system.
The central atom has <u>six</u> bonds: <u>four</u> to nitrogen atoms in the porphyrin, one to a <u>histidine</u> residue, and one to oxygen.