really? height to low buddy, high to low. if you compress air where does it want to go?
Water particles usually diffuse from an area of higher concentration to an area of lower concentration, following the concentration gradient. This process continues until equilibrium is reached and there is an equal distribution of water particles throughout the system.
by cooling
The sugar particle will diffuse from an area of higher concentration (inside the tubing) to an area of lower concentration (outside the tubing) until equilibrium is reached. Water molecules will also move into the tubing to balance the concentration gradient as the sugar particles diffuse out.
Substances can diffuse in response to a stimulus, such as a concentration gradient or a change in temperature. The movement of particles from areas of high concentration to low concentration is driven by diffusion, and this process can be influenced by various external stimuli.
In diffusion, movement of particles across a membrane is driven by differences in concentration gradients, which is the difference in concentration of a substance on either side of the membrane. Particles naturally move from areas of higher concentration to areas of lower concentration until equilibrium is reached.
Particles will diffuse from areas of higher concentration to lower concentration to reach equilibrium. This process is driven by the random motion of particles. The direction of diffusion can be predicted by following the concentration gradient, where particles will move towards areas of lower concentration.
Down concentration gradients.
if something diffuses e.g. particles through the air or CO2 out of body cells means the particles go from a high concentration to a low concentration
When particles diffuse, they move from an area of high concentration to an area of low concentration. This process occurs spontaneously as the particles seek to reach an equilibrium state. Diffusion is driven by the random motion of particles and does not require an external energy input.
Water particles usually diffuse from an area of higher concentration to an area of lower concentration, following the concentration gradient. This process continues until equilibrium is reached and there is an equal distribution of water particles throughout the system.
by cooling
The sugar particle will diffuse from an area of higher concentration (inside the tubing) to an area of lower concentration (outside the tubing) until equilibrium is reached. Water molecules will also move into the tubing to balance the concentration gradient as the sugar particles diffuse out.
Particles diffuse at different rates due to differences in their size, shape, and mass. Smaller, lighter particles diffuse quicker than larger, heavier particles because they can move more easily through the medium in which they are diffusing. Additionally, the temperature and concentration gradient of the medium can also affect the diffusion rate of particles.
No. The particles in the solids have different mass as the particles in the liqiuds, so they diffuse at the different rate. but if their particles have the same rate, they will diffuse at the same rate.
Substances can diffuse in response to a stimulus, such as a concentration gradient or a change in temperature. The movement of particles from areas of high concentration to low concentration is driven by diffusion, and this process can be influenced by various external stimuli.
Yes, liquid and gas particles can diffuse together. Diffusion is the movement of particles from an area of higher concentration to an area of lower concentration, and it can occur between different phases of matter. The speed of diffusion may vary depending on the properties of the substances involved.
Fick's first law equation is: J -D(dC/dx), where J is the flux of particles, D is the diffusion coefficient, C is the concentration of particles, and x is the distance. This equation describes how particles diffuse in a system by showing how the flux of particles changes with concentration gradient. It helps us understand how particles move from areas of high concentration to low concentration in a system.