Factors that effect resistance are: # Heat- At a higher temperature their will be more resistance as the atoms within the wire begin to swell and make it harder for the current to pass through the wire; this causes more resistance. # Length- As the length increases so does the resistance. This is because there is a larger space for the electrons to jump across and more atoms for them to get through to complete the circuit. # Cross-Sectional area- As the CS area increases the resistance decreases as there are more places for a greater current to travel through. # Material- Different materials have different densities. The denser a material the higher the resistance.
Factors that influence resistance to blood flow include the diameter of blood vessels (smaller diameter increases resistance), length of the vessels (longer vessels increase resistance), blood viscosity (thicker blood increases resistance), and turbulence within the blood vessels (increased turbulence increases resistance).
The four main factors that influence resistance in a wire are the material of the wire, the length of the wire, the cross-sectional area of the wire, and the temperature of the wire. These factors determine how easily electrons can flow through the wire and affect its overall resistance.
The four factors that determine an object's resistance are its length, cross-sectional area, resistivity of the material, and temperature. These factors influence how difficult it is for electrons to flow through the material, affecting the overall resistance.
The speed of an object is influenced by factors such as the force applied to it, the mass of the object, and the resistance it encounters from the surrounding environment.
Factors that influence the resistance of materials composition include the type of material (metals, polymers, ceramics), impurities or defects within the material, temperature, crystalline structure, mechanical processing, and environmental conditions (e.g. corrosion). Each of these factors can affect the ability of a material to resist deformation or failure under stress.
The length of the material The cross-sectional area of the material The resistivity of the material The temperature of the material
Electricity travels through wires by the movement of electrons. Factors that influence its flow include the material of the wire, its thickness, temperature, and the presence of any obstacles or resistance in the circuit.
An electric current is produced when electrons flow through a conductor, such as a wire. Factors that influence the generation of an electric current include the voltage applied, the resistance of the conductor, and the presence of a closed circuit.
There are three factors that increase peripheral resistance. These factors include autonomic activity, pharmacologic agents, and blood viscosity. Each factor increases the constriction of arteries, which in turn causes peripheral resistance.
Electricity flows in a circuit when electrons move through a closed loop of conductive material. Factors that influence the movement of electricity include the voltage difference, resistance in the circuit, and the type of material the circuit is made of.
Resistance in a wire is caused by collisions between electrons and atoms in the wire, which slows down the flow of electrons. Factors that can influence the resistance of a wire include the material it is made of, its length, cross-sectional area, and temperature.
Yes, insulin resistance can have a hereditary component. Genetic factors may influence an individual's susceptibility to developing insulin resistance, alongside lifestyle factors such as diet and physical activity. Family history of conditions like type 2 diabetes can also indicate a higher risk for insulin resistance among relatives. However, environmental factors and personal habits play a significant role in its development as well.