increasing energy
An increase in energy input, such as heat transfer from a heat source or mechanical work, would increase the temperature of a substance. This causes the particles in the substance to move faster, leading to an increase in kinetic energy and temperature.
increasing energy Work increases the temperature of a substance due to friction.
The temperature of the substance would increase as the average energy of particle motion increases. Additionally, the pressure exerted by the particles on the walls of the container would also increase.
Solubility increases by adding more solvent. That is, the substance that the other is being dissolved into. For example, if mixing sugar and water, you would add more water to increase solubility.
Increase the pressure (at constant volume) or increase the volume (at constant pressure), or do both at the same time. This is based on the Ideal Gas Law, which says PV = nRT. You can also just apply heat to it!
if you were to constantly increase the temperature of a solid you would eventually reach the melting point for that particular substance, at which time the solid would melt to a liquid. if you were to keep heating the substance, at some point the liquid would reach its boiling point and would evaporate to a gas.
The substance that requires the largest amount of energy to increase the temperature is the one with the highest specific heat capacity. Water has one of the highest specific heat capacities of commonly found substances, so it would require the largest amount of energy to increase the temperature of 20 grams by 1.0 K.
There would be an increase
Increasing the temperature would shift the equilibrium to the right and increase the amount of product.
You can heat ice, for example, and measure the temperature while it melts. You should notice that you heat it for quite a while, but that the temperature doesn't increase until all the ice is melted.
Raising the temperature would increase the rate of diffusion, leading to faster entry of the substance into the cell. However, very high temperatures can denature proteins and disrupt cellular processes, potentially harming the cell.
CH4(g) + H2O(g) CO(g) + 3H2(g)