Ohm’s Law is a relationship between three physical phenomena: current, voltage, and resistance. Current is defined as the flow of positive charge from a source to a negative charge source. The units for current are C/s for the amount of charge (C) that travels per unit time (s). The ampere (A) is the common unit of current equal to 1 C/s and the symbol for current is I. Current is an intrinsic property, as it depends on other aspects, such as the size of the system. To aptly compare the amount of current for different systems, the current is normalized per area or mass of the system. This is described as the following:
Where J is the current density in I/(m·m) or I/g depending on how the systems are compared, I is the current (A), A is the cross-sectional area (m·m), and m is the mass (g). Note that often j is used as current instead of I to prevent confusion with imaginary numbers. Therefore, one should pay attention to the symbols’ definitions, as they can vary case-by-case.
The voltage is another piece of Ohm’s Law that states the amount of work needed to move a charge. The unit for voltage is J/C, which is equal to the ubiquitous unit the Volt (V). The voltage measures the electric potential an object possesses in reference to a charge. By applying a voltage, work is done on the charge which enables the movement of the charge. The amount of charge compared to an individual charge, known as a point charge, can be determined by the following:
Where V is the electric potential (V), k is the constant 8.99 E 9 N·m·m/(C·C), q is the charge of the point (C), and r is the distance from the point charge (m).
The resistance is the opposition for the movement of charge. The resistance is similar to friction effects in flowing water or a sliding object. The units for resistance are Ohms, which is denoted with the capital Greek letter Omega. To calculate the amount of resistance in an object, the following equation can be used:
Where R is the resistance (Omega), Rho is the resistivity of the object (Omega·m), l is the length of the object (m), and A is the cross-sectional area of the object (m·m). The resistivity is different for every object and is based on the structure of the material. The calculation for resistivity is outside the scope of this article.
The resistance can also be normalized to provide an apt, case-by-case comparison. The normalized resistance is given by:
Where R is the normalized resistance (Omega·m·m). The resistance, which impedes the flow of charge, is inversely proportional to the current. As the current normalization is per units of area, the resistance normalization is multiplied by units of the cross-sectional area due to the inverse relationship.
The inverse of resistance (1/R) is known as the conductance, which measures the ability of an object to conduct charge given in units of Siemens (S). Further discussion of conductance is outside the scope of this article; however, it is worth noting the inverse relationship conductance has with resistance.
Given the current, voltage, and resistance, Ohm’s Law is defined as:
Eimensional analysis is needed to ensure consistent units.[1][2][3][4]
Ohm’s Law was originally an empirical derivation based on the relationship between current and voltage; however, it has remained consistent in microscopic and macroscopic observations. Ohm's Law is widely used in electronics and in creating circuits, as well as in battery development and other electrochemical applications. The scope of Ohm's Law is not limited to circuitry, as it can also be used to create molecules and polymers. Each atom contains protons and electrons, which can be harnessed to create chemical bonds with other atoms. By applying a voltage to a material, an oxidation-reduction reaction occurs, where one electron is removed from one molecule and attaches to another. This has a host of research applications, such as energy storage, materials chemistry, organic chemistry, and more. These applications use Ohm’s Law and have allowed scientists to make materials in novel ways.
To select the correct voltage, one needs to consider the resistances as well as the amount of charge to needed. If there is a lot of resistance and little voltage, there will not be enough current to apply the charge throughout. Conversely, if there is too much voltage, the current can harm the circuitry of the device or degrade the molecules. Using electricity through Ohm’s Law requires attention to the needs of the application to have the desired output.
The main issue of concern with Ohm’s Law is that the calculations can become complex with advanced circuitry and electrochemical phenomena. For example, the overall resistance is comprised of different types of resistance, such as Ohmic resistance, mass transfer resistance, and charge transfer resistance. In optimizing electrical performance of devices, there is a trade-off: reducing one resistance can increase another. This is a major consideration in design and optimization studies to find what values are best for a given application. Often, these different types of resistance are difficult to measure and require sophisticated machines to provide accurate values. Additionally, the resistance also changes over time as the structural integrity of a device degrades. This can also change the expected results of Ohm’s Law if this is not considered.[5][6]
Ohm’s Law is used in every electrical device to apply the correct amount of charge given the resistance. While clinicians will not need to readily calculate voltage, current, and resistance for these devices, understanding the relationship can provide intuition into how electrical devices work. Ohm’s Law is also present within the human body and has multiple applications. For example, nerves within the nervous system use electrical properties to relay messages to one another. These electrical signals can be mapped with sensors and be better understood by clinicians. Gao et al. and Su et al. have studied the electrical properties of bones and have progressed the treatment of bone ailments. The human body contains many electrical pathways and processes. By understanding the fundamental governing equation, clinicians can work to resolve issues in new ways.
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