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1 Introduction to Quantum Entanglement

In the realm of quantum computing, the ordinary rules of classical physics no longer apply. To understand one of the most enigmatic phenomena in quantum mechanics, entanglement, an exploration of the deep connections that bind quantum particles and pave the way for revolutionary computational power is needed.

2 Theory of Quantum Entanglement

2.1 The Nature of Qubits and Entanglement

In classical computing, one deals with bits that can exist in two states, 0 or 1. However, in quantum computing, the concept of qubits is introduced, which can exist in a superposition of 0 and 1 states simultaneously. Mathematically, a qubit can be represented as \(a|0⟩ + b|1⟩\), where \(a\) and \(b\) are coefficients allowing for this superposition.

Entanglement takes this concept further, where two qubits can become entangled in such a way that their states are deeply intertwined. This means that the state of one qubit cannot be described independently of the other, no matter the distance separating them.

2.2 Creating Entanglement: The CNOT Gate

To create entanglement, quantum gates such as the CNOT gate (Controlled-NOT gate) are employed. This gate operates on two qubits, with one acting as the control and the other as the target. When applied, it entangles the two qubits, establishing a correlation between their states.

2.3 Bell States: Epitome of Entanglement

The pinnacle of entanglement is captured in the Bell states, such as the state \(\frac{1}{\sqrt{2}}\) (\(|00⟩ + |11⟩\)). These states represent maximal entanglement between two qubits, where the properties of one qubit instantaneously affect the other, regardless of distance.

2.4 Implementation: Exploring Entanglement and Simulation

Diving into the practical side of entanglement starts by creating qubits and applying quantum gates to observe entanglement in action.

  • Step 1: Creating Qubits and Gates. Creating qubit states and applying quantum gates like the Hadamard gate (H) and CNOT gate to entangle them.
library(qsimulatR)
library(qvirus)

# Create qubits
x1 <- qstate(nbits = 2)
x1
#>    ( 1 ) * |00>

# Apply gates
x1_sup <- H(1)*x1
x1_sup
#>    ( 0.7071068 ) * |00> 
#>  + ( 0.7071068 ) * |01>

x1_entangled <- CNOT(c(1,2))*(x1_sup)
x1_entangled
#>    ( 0.7071068 ) * |00> 
#>  + ( 0.7071068 ) * |11>

truth.table(CNOT, nbits = 2)
#>   In2 In1 Out2 Out1
#> 1   0   0    0    0
#> 2   0   1    1    1
#> 3   1   0    1    0
#> 4   1   1    0    1
  • Step 2: Observing Entanglement. The probabilities of states for entangled qubits to witness the entanglement phenomenon are computed.
# Print probabilities
normalize_check(x1_sup, probs = TRUE)
#> |00> |01> |10> |11> 
#>  0.5  0.5  0.0  0.0

normalize_check(x1_entangled, probs = TRUE)
#> |00> |01> |10> |11> 
#>  0.5  0.0  0.0  0.5
  • Step 3: Visualizing Entangled States. Finally, visualization of the entangled states using plotting capabilities.
# Plot entangled states
qsimulatR::plot(x1_sup, qubitnames = c("|0>"))

qsimulatR::plot(x1_entangled, qubitnames = c("|0>"))

Tensor products of quantum state vectors are also quantum state vectors and they represent independence among systems.

For example, the tensor product \(|\phi> \otimes |\psi>\) may alternatively be written as \(|\phi> |\psi>\) or as \(|\phi \psi>\).

\[ \begin{equation} |0> \otimes |1> = \begin{pmatrix} 1 \\ 0 \\ \end{pmatrix} \otimes \begin{pmatrix} 0 \\ 1 \\ \end{pmatrix} = \begin{pmatrix} 0 \\ 1 \\ 0 \\ 0 \end{pmatrix} = |01> \tag{2.1} \end{equation} \] The same result for the tensor product between quantum state vectors of Equation (2.1) is obtained when working with qstate objects.

a <- qstate(1) # |0>
b <- X(1)*a    # |1>
kronecker(a@coefs, b@coefs)
#> [1] 0+0i 1+0i 0+0i 0+0i
ab <- qstate(2, coefs = kronecker(a@coefs, b@coefs))
ab
#>    ( 1 ) * |01>

To get a detailed computational sense of what entanglement means is obtained by simulating a specific 2-qubit example, as in Equation (2.2).

\[ \begin{equation} |x1> = \begin{pmatrix} 0.8 \\ 0.6 \\ \end{pmatrix} \,\,\ |x2> = \begin{pmatrix} 0.38 \\ 0.92 \\ \end{pmatrix} \tag{2.2} \end{equation} \] After applying the first CNOT, Equation (2.3) is obtained.

\[ \begin{equation} |x1> = \begin{pmatrix} 0.8 \\ 0.6 \\ \end{pmatrix} \,\,\ |x2> = \begin{pmatrix} 0.63 \\ 0.77 \\ \end{pmatrix} \tag{2.3} \end{equation} \] After applying the second CNOT gate, Equationo (2.4) is obtained.

\[ \begin{equation} |x1> = \begin{pmatrix} 0.8 \\ 0.6 \\ \end{pmatrix} \,\,\ |x2> = \begin{pmatrix} 0.683 \\ 0.721 \\ \end{pmatrix} \tag{2.4} \end{equation} \]

The simulate_entanglement function of qvirus simulates the application of CNOT gates for two qubits to demonstrate entanglement.

The function performs the tensor product \(|x1> \otimes |x2> = |x1x2>\) and then applies the first CNOT gate and compute the probabilities for both qubits, \(|x1>\) and \(|x2>\), to be in states \(|0>\) and \(|1>\), respectively.

This means that an updated \(|x2>\) with updated probabilities is obtained, where its coefficients are computed knowing that \(\text{coef} = \sqrt{prob}\). Consequently, an updated quantum state \(|x1> \otimes |x2> = |x1x2>\) is obtained. Now, the second CNOT gate is applied and probabilities for both qubits comoputed, \(|x1>\) and \(|x2>\), to be in states \(|0>\) and \(|1>\), respectively, and as before the result is an updated \(|x2>\) with updated probabilities.

x1 <- qstate(1, coefs = as.complex(c(0.8, 0.6)))
x2 <- qstate(1, coefs = as.complex(c(0.38, 0.92)))
simulate_entanglement(x1, x2, iterations = 2, angle = pi/4)
#> [[1]]
#> [[1]]$iteration
#> [1] 1
#> 
#> [[1]]$x1
#>  |0>  |1> 
#> 0.64 0.36 
#> 
#> [[1]]$x2_before
#>       |0>       |1> 
#> 0.4008074 0.5991926 
#> 
#> [[1]]$x2_after
#>       |0>       |1> 
#> 0.4298603 0.5701397 
#> 
#> [[1]]$entangled_state
#>    ( 0.2821603-0.2829596i )  * |00> 
#>  + ( 0.683125-0.1168746i )   * |01> 
#>  + ( 0.5123437-0.08765597i ) * |10> 
#>  + ( 0.2116202-0.2122197i )  * |11> 
#> 
#> 
#> [[2]]
#> [[2]]$iteration
#> [1] 2
#> 
#> [[2]]$x1
#>  |0>  |1> 
#> 0.64 0.36 
#> 
#> [[2]]$x2_before
#>       |0>       |1> 
#> 0.4722261 0.5277739 
#> 
#> [[2]]$x2_after
#>       |0>       |1> 
#> 0.4803609 0.5196391 
#> 
#> [[2]]$entangled_state
#>    ( 0.4679217-0.2369806i )  * |00> 
#>  + ( 0.5721219-0.1938195i )  * |01> 
#>  + ( 0.4290914-0.1453646i )  * |10> 
#>  + ( 0.3509413-0.1777355i )  * |11>

Thus, the probability of (\(|x2> = |0>\)) increased from 0.15 to 0.47, the probability of (\(|x2> = |1>\)) decreased from 0.85 to 0.53. The (unchanged) probability of (\(|x1> = |1>\)) \(0.36 < 0.5\) thus, \(|x1>\) is closer to state \(|0>\). This means that applying the CNOT several times, with \(x1\) as the control bit and \(x2\) as the target bit, will make \(|x2>\) to converge to state \(|0>\) as well, therefore entanglement.

3 Harnessing Entanglement for Quantum Computing

Entanglement stands as a cornerstone of quantum computing, enabling vast computational power and novel applications such as quantum teleportation and cryptography. While its mysteries continue to intrigue physicists and computer scientists alike, its practical utilization marks a paradigm shift in computing capabilities.

Considering two quantum particles, qubits, labeling them Alice and Bob. Now, in the quantum realm, Alice and Bob can become entangled. This means that the state of one qubit becomes intimately connected with the state of the other, no matter how far apart they are. It’s like they’re always in sync, no matter the distance that separates them.

# Create qubits
AlBo <- qstate(nbits = 2)
x1
#>    ( 0.8 )   * |0> 
#>  + ( 0.6 )   * |1>

# Apply gates
H_AlBo <- H(1)*AlBo

Entangled <- CNOT(c(1,2))*(H_AlBo)
# Display the entangled state
Entangled
#>    ( 0.7071068 ) * |00> 
#>  + ( 0.7071068 ) * |11>

# Check normalization with probabilities
normalize_check(Entangled, probs = TRUE)
#> |00> |01> |10> |11> 
#>  0.5  0.0  0.0  0.5

Alice and Bob get entangled using the special quantum operation of the H gate and the Controlled-NOT gate (CNOT). The Hadamard gate puts a qubit into a superposition of states, and the CNOT gate creates entanglement between two qubits.

Alice and Bob are entangled. When measuring one qubit, say Alice, her state instantly affects Bob’s state, no matter how far apart they are.

Calculating the sum of the squared magnitudes of the coefficients of the qstate object or its probabilities measures the normalization of the entangled state.

This gives either the sum of the squared magnitudes of the coefficients or the probabilities of the entangled state, ensuring that the quantum state is properly normalized.

Qubits for Alice and Bob are entangled using the Hadamard gate and the Controlled-NOT gate. After entanglement, a measurement on Alice is performed.

Applications of entanglement, like in drug design, revolve around the design of a new anti-retro viral drug that binds perfectly with a virus protein. This requires complex chemical simulations that are very difficult for classical supercomputers. But with quantum computers and their ability to handle entangled states, much more accurate simulations can be performed, leading to better drug designs.

Quantum entanglement of connection between particles opens up new possibilities for faster and more accurate computations, making tasks like drug design much more efficient and effective.

# Application in drug design simulation
# Simulate entanglement to improve accuracy
# Quantum computer can handle complex states efficiently
# Suppose we're simulating a drug-protein interaction
# Here's a simplified example

# Quantum representation of drug and protein states
Bind <- qstate(nbits = 2)

# Entangle Drug and Protein states
Entangled_Drug_Protein <- CNOT(c(1, 2)) * (H(1)*Bind)

# Perform simulation operations using entangled states
# Measure and analyze results for drug-protein binding
# Quantum computer allows for more accurate simulations
Entangled_Drug_Protein
#>    ( 0.7071068 ) * |00> 
#>  + ( 0.7071068 ) * |11>

# Now, let's check the normalization of the entangled state
normalize_check(Entangled_Drug_Protein, probs = TRUE)
#> |00> |01> |10> |11> 
#>  0.5  0.0  0.0  0.5

When entanglement is applied in drug design simulation, quantum states are created for a drug molecule and a protein molecule and simulations of their interactions using entangled states lead to more accurate results.

The normalization function ensures the entangled drug-protein state is properly normalized, which is crucial for accurate quantum simulations.

Some concepts behind quantum computing and its implications for drug design, particularly in the context of anti-retro viral drugs for HIV, are of importance.

Practical applications related to HIV drug design have the goal to determine if a toy anti-retroviral molecule binds effectively with a toy virus protease. This involves using quantum chemistry algorithms to simulate the binding affinity between the molecule and the protease. The challenge includes tweaking the quantum chemistry setup for optimal performance under ideal quantum computing conditions. Quantum computing’s ability to handle entangled states and superposition offers a new frontier in drug design, potentially revolutionizing the way of developing treatments for diseases like HIV.

Superposition and entanglement are related concepts in quantum mechanics, but they’re not the same thing. Like a coin that can be either heads or tails. In classical terms, the coin is in one of these states at any given time. In quantum terms, the coin can be in a superposition of both states simultaneously, like being “half heads and half tails” until observation.

The two coins are entangle if, when one coin is heads, the other is guaranteed to be tails, no matter how far apart they are.

So, superposition is about a single object being in multiple states at once, while entanglement is about the relationship between multiple objects where the state of one directly affects the state of another.

Superposition allows qubits to represent multiple states simultaneously, which is a powerful computational resource. Entanglement, on the other hand, enables qubits to be correlated in such a way that operations on one qubit instantly impact others, leading to faster and more efficient computations

The H gate is essential for creating superposition states in individual qubits, which are then used in conjunction with other gates to generate entangled states between multiple qubits. This entanglement allows for the unique properties of quantum computing, such as simultaneous computation across correlated qubits.

The H gate is often used to create superposition in a single qubit. When applying the H gate to a qubit initially in state \(|0⟩\) (zero state), it puts the qubit into an equal superposition of \(|0⟩\) and \(|1⟩\), represented as in Equation (3.1).

\[ \begin{equation} H∣0⟩ = \frac{1}{\sqrt{2}} (∣0⟩ + ∣1⟩) \tag{3.1} \end{equation} \]

Similarly, applying the H gate to qubit initially in state \(|1⟩\) puts it into the superposition of \(|0⟩\) and \(|1⟩\), like in Equation (3.2)

\[ \begin{equation} H∣1⟩ = \frac{1}{\sqrt{2}} (∣0⟩ + ∣1⟩) \\ \tag{3.2} \end{equation} \]

These superposition states are crucial for quantum computations because they allow qubits to represent multiple classical states simultaneously.

Entanglement typically involves multiple qubits. For example, considering a system of two qubits initially in the state \(|00⟩\), where both qubits are in the zero state. To create an entangled state, a series of gates that involve H gates along with other gates like CNOT gate are applied.

For instance, applying a Hadamard gate to the qubit of Equation (3.1) followed by a CNOT gate (controlled by the first qubit and targeting the second qubit) creates the Bell state \(|\phi +⟩\), as in Equation (3.3).

\[ \begin{equation} |Φ+⟩ = \frac{1}{\sqrt{2}}(∣00⟩+∣11⟩) \tag{3.3} \end{equation} \]

In this entangled state, the qubits are correlated. Measuring one qubit and find it in, say, state \(|0⟩\), then instantly the other qubit is also in state \(|0⟩\) due to their entanglement.

To generate entangled states using the CNOT gate after applying the H gate for superposition, first the H gate to one qubit is applied to create superposition. Then the CNOT gate is applied with the qubit in superposition as the control qubit and another qubit as the target qubit.

Unlike in classical computing whith clear control and target roles, in quantum logic, after a CNOT operation, there’s a blur. The qubits’ states become intertwined. It can’t be said definitively if one qubit solely controls the other because they influence each other’s states.

When CNOT gates are applied for entanglement, starting with two qubits, measuring probabilities shows how their states evolve. If a qubit’s probability shifts, it means it’s becoming more entangled with the other qubit.

The last step involves checking the normalization of the entangled state using probabilities.

Imagining two entangled quantum systems, like a drug molecule and a protein molecule. To make sure the entangled state is behaving nicely, normalization makes sure everything adds up to one, double-checking that the entangled state isn’t misbehaving. These probabilities tell the chances of finding the system in different states when measuring it.

An entangled state, properly set up gives accurate results.

Separable qubits are quite the opposite of entangled ones. A separable state can be broken down into a product of individual subsystem states. Taking a 2-qubit system, if a state can be expressed as \(|\psi⟩ = |a⟩ \otimes |b⟩\), where \(|a⟩\) and \(|b⟩\) are single-qubit states, then it’s separable. For example, states like \(|00⟩\), \(|01⟩\), \(|10⟩\), and \(|11⟩\) are all separable.

Combining two quantum states with the tensor product, shows their independence. For instance, \(|\phi⟩ \otimes |\psi⟩\) means \(|phi⟩\) and \(|\psi⟩\) are not meddling with each other.

Now, applying CNOT gates, it might be observed that a qubit’s chance of being in state |0> increase while its chance of being in state \(|1>\) decreases. This tells how they’re becoming entangled. The more CNOT gates applied, the more intertwined their states become until they’re inseparable.

The HIV drug-protein interaction simulation represents entangled and separable states.

Defining quantum states representing the drug and protein molecules and then entangling them using the CNOT gate is a process to simulate their interaction. Entanglement affects the measurement results.

# Quantum representation of drug and protein states
Drug_State <- qstate(1, coefs = as.complex(c(1, 0)))  # State |0>
Protein_State <- qstate(1, coefs = as.complex(c(1, 0)))  # State |0>
# Entangle Drug and Protein states
# Perform simulation operations using entangled states
# Measure and analyze results for drug-protein binding
simulate_entanglement(Drug_State, Protein_State, 3, angle = pi/4)
#> [[1]]
#> [[1]]$iteration
#> [1] 1
#> 
#> [[1]]$x1
#> |0> |1> 
#>   1   0 
#> 
#> [[1]]$x2_before
#> |0> |1> 
#>   1   0 
#> 
#> [[1]]$x2_after
#>       |0>       |1> 
#> 0.8535534 0.1464466 
#> 
#> [[1]]$entangled_state
#>    ( 0.9238795+0i )  * |00> 
#>  + ( 0-0.3826834i )  * |01> 
#> 
#> 
#> [[2]]
#> [[2]]$iteration
#> [1] 2
#> 
#> [[2]]$x1
#> |0> |1> 
#>   1   0 
#> 
#> [[2]]$x2_before
#> |0> |1> 
#>   1   0 
#> 
#> [[2]]$x2_after
#>       |0>       |1> 
#> 0.8535534 0.1464466 
#> 
#> [[2]]$entangled_state
#>    ( 0.9238795+0i )  * |00> 
#>  + ( 0-0.3826834i )  * |01> 
#> 
#> 
#> [[3]]
#> [[3]]$iteration
#> [1] 3
#> 
#> [[3]]$x1
#> |0> |1> 
#>   1   0 
#> 
#> [[3]]$x2_before
#> |0> |1> 
#>   1   0 
#> 
#> [[3]]$x2_after
#>       |0>       |1> 
#> 0.8535534 0.1464466 
#> 
#> [[3]]$entangled_state
#>    ( 0.9238795+0i )  * |00> 
#>  + ( 0-0.3826834i )  * |01>

Now, the second CNOT gate is applied and the probabilities for both qubits are obtained, \(|x1>\) and \(|x2>\), to be in states \(|0>\) and \(|1>\), respectively.

As before, an updated Protein_State with updated probabilities is formed, and its coefficients are computed knowing that \(\text{coef} = \sqrt{prob}\).

The theory of the RX gate has great potential application in the context of HIV research. The function simulate_entanglement includes the angle parameter to specify the rotation to be applied on an Rx gate.

The RX gate is a single-qubit gate that performs a rotation around the X-axis of the Bloch sphere by an angle specified by the theta parameter. Mathematically, it is represented by the matrix of Equation (3.4)

\[ \begin{equation} RX(θ) = \left( \begin{array}{ll} \cos\Big (\frac{\theta}{2}\Big ) & -i \sin\Big (\frac{\theta}{2}\Big ) \\ -i \sin\Big (\frac{\theta}{2}\Big ) & \cos\Big (\frac{\theta}{2}\Big ) \end{array} \right) \tag{3.4} \end{equation} \]

The RX gate is commonly used in quantum computing for rotations in quantum states, particularly in the context of quantum simulations and quantum algorithms.

In the context of HIV research or drug design, the RX gate can be used to simulate the application of antiretroviral drugs on quantum states representing viral components or host cell interactions. For example, if a quantum simulation where qubits represent specific molecular states related to HIV infection or drug-target interactions is considered, applying an RX gate with an appropriate angle can simulate the effect of a particular antiretroviral drug on the quantum state of the system.

This simulation can provide insights into how different drugs or drug combinations might interact with viral components at a quantum level, aiding in the development of more effective antiretroviral therapies or understanding drug resistance mechanisms.

The flexibility of the RX gate in specifying rotation angles allows researchers to model various scenarios and investigate the quantum dynamics of drug interactions with viral components, contributing to advancements in HIV treatment strategies.

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