In a relaxed fibril, H-zone, a lighter of low density can be seen in the cenre of ______

In a relaxed fibril, H-zone, a lighter region of low density can be seen in the centre of " " Or The dark bands (Black bands) of a skeletal muscle are known as

A long cylindrical vessel has a small hole of diameter D at its bottom. This vessel can be lowered vertically in water to a depth h without any water entering the vessel. Given : A=surface tension, B=density of liquid, C=acceleration due to gravity. The value of h is

Height h(400=m) from the ground at place A, from which the readiowaves can be transmitted. There is a receive at station B on earth at a distance d(=125km), which can receive the signal from station A. The radiowaves can reach the station B, either through earth's atmosphere or through satellite. There are four main layers in earth's atmosphere named D,E, F_(1) and F_(2) which play effective role in radio communication. The electron density of these layers is 4xx10^(8), 2xx10^(11),5xx10^(11) and 8xx10^(11)m^(-3) . The radius of the earth is 6.4xx10^(6)m . On a particular day, the maximum frequency reflected from the ionosphere is 9 MHz. On another day, it was found to increase by 1 MHz. The ratio of maximum electrom density of the ionosphere on the two days is

The density of ice is 901 kg m^(-3) . What percentage of ice lies below water ? The density of sea water is 1011 kg m^(-3) . What fraction of an iceberg can be seen by us if the ice berg has the same density as that of ice ?

A large container has a sliding vertical wall of height H so as to divide it into two parts. The partition wall is connected to the left container wall by an ideal spring of force constant k. when the spring is relaxed the dimentsions of the floor of the right part is Lxxb. Now water (density rho ) is slowly poured into the right chamber. what is the maximum volume of water that can be stored in the right chamber without spilling it into the other part. The partition wall slides without friction.

When water is filled caerfully in a glass . One can fill it to a height h above the rim of glass due to the surface tension of water . To calculate h just before water starts flowing model the shape of the water above the rim as a disc of thickness h having semicircular edges as shown achematically in the figure When the pressure of water at the bottom of this disc exceeds what can be withstood due to the surface lension , the water surface breaks near the rim and water starts flowing form there if the density of water, its surface tension and the acceleration due to gravity are 10^(3)kgm^(-3),0.07Nm^(-1)and10ms^(-2) , respectively, the value of h (in mm) is _________

Converting molarity to mole fraction, mass percent and molality: A 0.750 M solution of H_(2)SO_(4) in water has a density of 1.049 g mL^(-1) at 20 ^(@)C . What is the concentration of this solution in (a) mole fraction, (b) mass percent. And (c ) molality? Strategy: To solve this problem, we need to know the mass of solute as well as mass of solvent. There is 0.750 mol H_(2)SO_(4) per liter of solution. Let's pick an arbitrary amount of the solution that will make the calculations easy, say 1.00 L . Consider 1 L (=1000 ml) of solution and calculate its mass, using the density. We can then calculate the mass of H_(2)SO_(4) and find the mass of H_(2)O by difference. Now we can calculate the mole fraction, mass precent and morality.