When `alpha-D` glucose is dissolved in water, it undergoes a partial converion to `beta-D` glucose to exhibit mutarotation. This conversion stops when `63.6%` of glucose is in `beta` form. Assuming that equilibrium has been attained, calculate `K_(c)` for mutarotation.

During mutarotation of beta -D-glucose in aqueous solution angle of optical rotation

When either form of D-Glucose is dissolved In water, the solution gradually changes its optical rotation and finally attains a constant optical rotation of +52^(@) . Which form of D-GIucose is more stable?

A sugar exist in two isomeric form alpha-D & beta-D with specific rotation of 110^(@) and 30^(@) respectively. When alpha-D form of the suar is dissolved in water exhibits mutarotation till the equilibrium value of 90^(@) is attained. The equilibrium constant of mutarotation of beta-D form [Assuming only alpha and beta form in solution] is equal to:

When either form of D-Glucose is dissolved In water, the solution gradually changes its optical rotation and finally attains a constant optical rotation of +52^(@) . Which of the following statements, is true?

When either form of D-Glucose is dissolved In water, the solution gradually changes its optical rotation and finally attains a constant optical rotation of +52^(@) . What is the percentage of open chain D-Glucose in solution?

alpha-(D)" glucose "hArr beta-(D) glucose, equilibrium constant for this s 1.8. The percentage of alpha-(D) glucose at equilibrium is

D (+) Glucose has melting point 146^@ C and specific rotation [alpha]_(D)^(25) is + 112^@ C. Another D(+) Glucose has melting point 150^@ C and specific rotational [alpha]_(D)^(25) is + 18.7^@ C. The two form have significantly different optical rotation but when an aqueous solution of either form is allowed to stand, it rotation changes. The specific rotation of one form decreases and rotation of other increases until both solution show the same value +52.7^@ . The change in rotation towards an equilibrium value is called mutarotation. Mutarotation is characteristic feature of:

D (+) Glucose has melting point 146^@ C and specific rotation [alpha]_(D)^(25) is + 112^@ C. Another D(+) Glucose has melting point 150^@ C and specific rotational [alpha]_(D)^(25) is + 18.7^@ C. The two form have significantly different optical rotation but when an aqueous solution of either form is allowed to stand, it rotation changes. The specific rotation of one form decreases and rotation of other increases until both solution show the same value +52.7^@ . The change in rotation towards an equilibrium value is called mutarotation. For mannose the mutarotation can be shown in brief as follow:

When (+) sucrose is hydrolysed, the D -glucose mutarotates downward to +52.7^(@) . What does this indicate about the structures of (+) -sucrose?