In physics, **classical mechanics** and quantum mechanics are the two major sub-fields of mechanics. Classical mechanics is concerned with the set of physical laws describing the motion of bodies under the action of a system of forces. The study of the motion of bodies is an ancient one, making classical mechanics one of the oldest and largest subjects in science, engineering and technology.

Classical mechanics describes the motion of macroscopic objects, from projectiles to parts of machinery, as well as astronomical objects, such as spacecraft, planets, stars, and galaxies. Besides this, many specializations within the subject deal with gases, liquids, solids, and other specific sub-topics. Classical mechanics provides extremely accurate results as long as the domain of study is restricted to large objects and the speeds involved do not approach the speed of light. When the objects being dealt with become sufficiently small, it becomes necessary to introduce the other major sub-field of mechanics, quantum mechanics, which reconciles the macroscopic laws of physics with the atomic nature of matter and handles the wave–particle duality of atoms and molecules. However, when both quantum mechanics and classical mechanics cannot apply, such as at the quantum level with many degrees of freedom, quantum field theory (QFT) becomes applicable. QFT deals with small distances and large speeds with many degrees of freedom as well as the possibility of any change in the number of particles throughout the interaction. To deal with large degrees of freedom at the macroscopic level, statistical mechanics becomes valid. Statistical mechanics explores the large number of particles and their interactions as a whole in everyday life. Statistical mechanics is mainly used in thermodynamics. In the case of high velocity objects approaching the speed of light, classical mechanics is enhanced by special relativity. General relativity unifies special relativity with Newton's law of universal gravitation, allowing physicists to handle gravitation at a deeper level.

A **physical quantity** (or "physical magnitude") is a physical property of a phenomenon, body, or substance, that can be quantified by measurement.

**Force**
**Dynamics**

The following outline is provided as an overview of and topical guide to physics:

**Physics** – natural science that involves the study of matter and its motion through spacetime, along with related concepts such as energy and force. More broadly, it is the general analysis of nature, conducted in order to understand how the universe behaves.

In physics, **net force** is *the overall force* acting on an object. In order to calculate the net force, the body is isolated and interactions with the environment or constraints are introduced as forces and torques forming a free-body diagram.

The net force does not have the same effect on the movement of the object as the original system forces, unless the point of application of the net force and an associated torque are determined so that they form the resultant force and torque. It is always possible to determine the torque associated with a point of application of a net force so that it maintains the movement of the object under the original system of forces.

**Specific force** is defined as the non-gravitational force per unit mass.

Specific force (also called g-force and mass-specific force) is measured in meters/second² (m·s−2) which is the units for acceleration. Thus, specific force is not actually a force, but a type of acceleration. However, the (mass-)specific force is not a coordinate-acceleration, but rather a proper acceleration, which is the acceleration relative to free-fall. Forces, specific forces, and proper accelerations are the same in all reference frames, but coordinate accelerations are frame-dependent. For free bodies, the specific force is the cause of, and a measure of, the body's proper acceleration.

A **fictitious force**, also called a **phantom force**, **pseudo force**, **d'Alembert force** or **inertial force**, is an apparent force that acts on all masses whose motion is described using a non-inertial frame of reference, such as a rotating reference frame.

The force **F** does not arise from any physical interaction between two objects, but rather from the acceleration **a** of the non-inertial reference frame itself. As stated by Iro:

Science of *drugs* including their origin, composition, *pharmacokinetics*,

*pharmacodynamics*, therapeutic use, and toxicology.

**Pharmacology** (from Greek φάρμακον, *pharmakon*, "poison" in classic Greek; "drug" in modern Greek; and -λογία, *-logia* "study of", "knowledge of") is the branch of medicine and biology concerned with the study of drug action, where a drug can be broadly defined as any man-made, natural, or endogenous (within the body) molecule which exerts a biochemical and/or physiological effect on the cell, tissue, organ, or organism. More specifically, it is the study of the interactions that occur between a living organism and chemicals that affect normal or abnormal biochemical function. If substances have medicinal properties, they are considered pharmaceuticals.

- What is the mass of an object that's accelerating at 15 m/s squared when a force of 3000 N is exerted?
- What is the force of an object with a mass of 22 kg and an acceleration of 4 m/s?
- What is the force of an object with a mass of 20 kilograms with an acceleration of 1.5 m/s?
- Can you Calculate the force on a object that has a mass of 12 kg and an acceleration of for m/s to the 2 power?
- What's the force of an object with a mass of 2kg and an acceleration of 1 m/s?
- If a sled is accelerating down a hill at a rate of 1 m/s^2. If the mass of the sled is suddenly cut in half and the net force on the sled is doubled, what is the acceleration of the sled?
- If a mousetrap racer moved with a maximum velocity of -.881 m/s, an acceleration of -1.14 m/s^2, and with a net force of -.053N what's the average spring force?
- Can you Calculate the net force of an object moving at 2 m/s/s that has a mass of 5 kg?

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