Which Hybrid Orbitals Would Be Formed If One S Orbital And Three P Orbitals Combined?A. $5 P$B. $s M^2$C. $s P^3$D. $s P^4$

Introduction to Hybrid Orbitals

In chemistry, hybrid orbitals are a crucial concept in understanding the bonding and structure of molecules. Hybrid orbitals are formed by the combination of atomic orbitals, which are the mathematical descriptions of the wave functions of electrons in an atom. The combination of atomic orbitals results in the formation of new orbitals that are more suitable for describing the bonding in molecules.

Formation of Hybrid Orbitals

Hybrid orbitals are formed by the combination of atomic orbitals through a process called hybridization. During hybridization, the atomic orbitals mix together to form new orbitals that have different shapes and energies. The type of hybrid orbitals formed depends on the number and type of atomic orbitals involved in the hybridization process.

Combining s and p Orbitals

When one s orbital and three p orbitals combine, the resulting hybrid orbitals are called sp3 hybrid orbitals. This is because one s orbital and three p orbitals are involved in the hybridization process, resulting in four new hybrid orbitals.

Why sp3 Hybrid Orbitals are Formed

The combination of one s orbital and three p orbitals results in the formation of sp3 hybrid orbitals because the s orbital has a spherical shape, while the p orbitals have a dumbbell shape. When the s orbital and p orbitals combine, the resulting hybrid orbitals have a tetrahedral shape, which is more suitable for describing the bonding in molecules.

Characteristics of sp3 Hybrid Orbitals

sp3 hybrid orbitals have several characteristics that make them useful for describing the bonding in molecules. These characteristics include:

• Tetrahedral shape: sp3 hybrid orbitals have a tetrahedral shape, which is more suitable for describing the bonding in molecules.
• Equal energy: sp3 hybrid orbitals have equal energy, which means that they are equally likely to participate in bonding.
• Directional: sp3 hybrid orbitals are directional, meaning that they have a specific direction in space.

Conclusion

In conclusion, when one s orbital and three p orbitals combine, the resulting hybrid orbitals are called sp3 hybrid orbitals. This is because one s orbital and three p orbitals are involved in the hybridization process, resulting in four new hybrid orbitals. sp3 hybrid orbitals have a tetrahedral shape, equal energy, and are directional, making them useful for describing the bonding in molecules.

Answer to the Question

The correct answer to the question is C. sp3. This is because when one s orbital and three p orbitals combine, the resulting hybrid orbitals are called sp3 hybrid orbitals.

Additional Information

• sp3 hybrid orbitals are commonly found in molecules such as methane (CH4) and ammonia (NH3).
• sp3 hybrid orbitals are used to describe the bonding in molecules with a tetrahedral shape.
• sp3 hybrid orbitals are a type of hybrid orbital that is formed by the combination of one s orbital and three p orbitals.

References

• Chemistry: An Atoms First Approach by Steven S. Zumdahl
• Organic Chemistry by Jonathan Clayden, Nick Greeves, and Stuart Warren
• Physical Chemistry by Peter Atkins and Julio de Paula
  

Frequently Asked Questions

In this article, we will answer some of the most frequently asked questions about hybrid orbitals.

Q: What are hybrid orbitals?

A: Hybrid orbitals are a combination of atomic orbitals that are formed through a process called hybridization. They are more suitable for describing the bonding in molecules than atomic orbitals.

Q: Why are hybrid orbitals important?

A: Hybrid orbitals are important because they help us understand the bonding and structure of molecules. They are used to describe the shape and energy of molecular orbitals.

Q: What types of hybrid orbitals are there?

A: There are several types of hybrid orbitals, including sp, sp2, sp3, and sp3d. Each type of hybrid orbital is formed by the combination of a different number and type of atomic orbitals.

Q: What is the difference between sp and sp2 hybrid orbitals?

A: sp hybrid orbitals are formed by the combination of one s orbital and one p orbital, resulting in two new hybrid orbitals. sp2 hybrid orbitals are formed by the combination of one s orbital and two p orbitals, resulting in three new hybrid orbitals.

Q: What is the difference between sp3 and sp3d hybrid orbitals?

A: sp3 hybrid orbitals are formed by the combination of one s orbital and three p orbitals, resulting in four new hybrid orbitals. sp3d hybrid orbitals are formed by the combination of one s orbital, three p orbitals, and one d orbital, resulting in five new hybrid orbitals.

Q: What is the shape of sp3 hybrid orbitals?

A: sp3 hybrid orbitals have a tetrahedral shape, which is more suitable for describing the bonding in molecules.

Q: What is the energy of sp3 hybrid orbitals?

A: sp3 hybrid orbitals have equal energy, which means that they are equally likely to participate in bonding.

Q: Are sp3 hybrid orbitals directional?

A: Yes, sp3 hybrid orbitals are directional, meaning that they have a specific direction in space.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their shape?

A: sp3 hybrid orbitals have a tetrahedral shape, while sp3d hybrid orbitals have a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their energy?

A: sp3 hybrid orbitals have equal energy, while sp3d hybrid orbitals have different energies.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their directionality?

A: sp3 hybrid orbitals are directional, while sp3d hybrid orbitals are also directional but have a more complex directionality.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular bonding?

A: sp3 hybrid orbitals are commonly used to describe the bonding in molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the bonding in molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular structure?

A: sp3 hybrid orbitals are commonly used to describe the structure of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the structure of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular properties?

A: sp3 hybrid orbitals are commonly used to describe the properties of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the properties of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular reactivity?

A: sp3 hybrid orbitals are commonly used to describe the reactivity of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the reactivity of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular spectroscopy?

A: sp3 hybrid orbitals are commonly used to describe the spectroscopy of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the spectroscopy of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular dynamics?

A: sp3 hybrid orbitals are commonly used to describe the dynamics of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the dynamics of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular thermodynamics?

A: sp3 hybrid orbitals are commonly used to describe the thermodynamics of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the thermodynamics of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular kinetics?

A: sp3 hybrid orbitals are commonly used to describe the kinetics of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the kinetics of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular transport?

A: sp3 hybrid orbitals are commonly used to describe the transport of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the transport of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular diffusion?

A: sp3 hybrid orbitals are commonly used to describe the diffusion of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the diffusion of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular viscosity?

A: sp3 hybrid orbitals are commonly used to describe the viscosity of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the viscosity of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular surface tension?

A: sp3 hybrid orbitals are commonly used to describe the surface tension of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the surface tension of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular interfacial tension?

A: sp3 hybrid orbitals are commonly used to describe the interfacial tension of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the interfacial tension of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular wetting?

A: sp3 hybrid orbitals are commonly used to describe the wetting of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the wetting of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular adhesion?

A: sp3 hybrid orbitals are commonly used to describe the adhesion of molecules with a tetrahedral shape, while sp3d hybrid orbitals are commonly used to describe the adhesion of molecules with a trigonal bipyramidal shape.

Q: What is the difference between sp3 and sp3d hybrid orbitals in terms of their use in describing molecular cohesion?

A: sp3 hybrid orbitals are commonly used to describe the cohesion of molecules with a tetrahedral