In the era of cutting-edge technology, quantum computing stands at the forefront as a promising new frontier. 

In contrast to conventional computers, which use bits to process data, quantum computing uses fascinating qubit features to carry out complex computations with unrivalled speed and effectiveness. As researchers and scientists delve deeper into this enigmatic realm, the potential applications of quantum computing are anything short of revolutionary.

The qubit, a quantum equivalent of a bit, is at the core of quantum computing. At once, a qubit can be in numerous states according to the superposition principle, unlike a conventional bit, which can only represent a 0 or a 1. It allows quantum computers to run a vast number of computations at once, exponentially increasing their processing capability.

Entanglement is another intriguing characteristic of qubits. When two qubits are entangled, their states are instantly affected by one another, regardless of how far off they are from one another. Due to this phenomenon, quantum computers can create intricate correlations and resolve issues previously thought to be computationally impossible.

Susceptible to outside disturbances, qubits must be kept in their delicate quantum state to be used to their full potential. One of the biggest problems with quantum computing has been this. To overcome these difficulties and stabilize qubits, scientists have developed error-correcting codes and quantum error correction algorithms, paving the door for more dependable quantum calculations.

The solution to optimization issues may also get revolutionized by quantum computing. These issues are widespread across several industries, including supply chain management, banking, and pharmaceutical research. When tackling these optimization problems, quantum algorithms can exponentially speed up the process and provide more effective and ideal solutions.

Governments and the corporate sector have recently expressed a greater interest in quantum computing. To create the first commercially viable quantum computer, IT giants and startups have poured enormous resources into creating quantum hardware and algorithms. Nations are investing in research and development to keep up their competitive edge because they understand the potential strategic advantage that quantum computing could provide.

Despite the enormous potential of quantum computing, it is still in its infancy and faces several obstacles. The challenges include developing scalable and reliable quantum computers, enhancing qubit coherence, and addressing error rates. But with every development, quantum computing's potential is shown more clearly, bringing industry disruption and real-world issue solutions one step closer.

In conclusion, quantum computing, powered by the intriguing properties of qubits, offers a tantalizing glimpse into the future of technology.