Stopping Power Modulation by Pump Waves of Charged Particles Moving above Two-Dimensional Electron Gases

The perturbation electron density and stopping power caused by the movement of charged particles above two-dimensional quantum electron gases (2DQEG) have been studied in numerous works using the quantum hydrodynamic (QHD) theory. In this paper, the QHD is modiﬁed by introducing the two-dimensional electron exchange-correlation potential at high density V xc 2DH and the pump wave modulations. Based on the modiﬁed QHD, the perturbation electron density and stopping power are calculated for pump waves with various parameters. The results show that the stopping power values are more accurate after considering V xc 2DH . Under the modulation of pump waves with the wavelength from 0 . 1nm to 0 . 1cm, the perturbation electron density of 2DQEG and the stopping power of charged particles show periodic changes. Under the modulation of pump waves with λ � 1 . 76 × 10 − 4 cm and Φ 0 � 2 × 10 10 e / λ f , the average stopping power with respect to the time phase θ becomes negative, which means that the charged particles will gain energy and can be accelerated. This is a new phenomenon in the ﬁelds of 2DQEG and of great signiﬁcance in surface physics and surface modiﬁcation in nanoelectronic devices with beam


Introduction
Accompanied by the two-dimensional quantum electron gases (2DQEG) is confirmed to exist on the surface of the metals and semiconductor heterostructures. e interaction between charged particles and plasma targets has attracted a lot of attention in surface physics [1][2][3][4][5][6]. e incident particles can also be used as probes to detect the properties of 2DQEG, or as a powerful tool of surface character modification.
In the study of the interaction between charged particles and plasma targets, people are particularly interested in the analytical calculation of energy loss [7] and the density distribution of the plasma targets [8]. Stopping power is used to describe the energy loss per unit length [6,[9][10][11][12][13][14][15]. As an important physical quantity to study the interaction between charged particles and the plasma targets, a lot of experiments and theoretical studies have been done in the past decade [16][17][18][19][20][21][22][23][24][25][26][27][28]. e stopping power of charged particles can be modulated by the incident velocity of charged particles [5], the amount of charge of charged particles, the density of plasma targets [5], varying altitude parameter between charged particles and 2DQEG [4,5,29], the external magnetic field [30,31], the spin effects [32], and so on.
In order to understand the interaction between charged particles and plasma targets in the presence of a laser field, a lot of theoretical studies have been carried out [33][34][35][36][37][38][39]. Within the dielectric formalism, Arist et al. [33] studied the influence of a strong laser field on the stopping power for charged particles in low-density nondegenerate plasmas, and the expression of stopping power is given when a laser field exists.
e results show that the laser field reduces the stopping power of plasma and makes it anisotropic through the polarization of the electric field wave. Within the random-phase approximation theory, Nersisyan [34] also investigated the stopping and acceleration effect of protons in a plasma in the presence of an intense radiation field and calculated the stopping power of charged particles in the high-frequency limit. With two-dimensional electrostatic particle-in-cell (2DPIC) simulation, Hu [35] studied energy loss of ion beam when plasma irradiated by a strong laser pulse and the dynamic polarization of plasma. Pertaining results make it clear that stopping power gets strongly modulated by the laser field.
However, these research methods are no longer applicable when studying the stopping power modulation by pump waves of charged particles moving above the 2DQEG. In the study of Nersisyan et al., when considering the interaction between laser and three-dimensional plasma, the expression of the vector potential A of electromagnetic waves was used [34]. However, the vector potential expression of the electromagnetic wave A cannot be written for the interaction of 2DQEG and laser. Another feasible method to implement electromagnetic waves is to ignore the effect of the magnetic field and write down the expression for the electric field term of electromagnetic waves [40]. e 2DPIC method cannot be used either to study the interaction between charged particles and 2DQEG. Because the charged particles are above the 2DQEG, a three-dimensional electrostatic particle-in-cell (3DPIC) method is required. However, the 3DPIC method is currently difficult to implement due to a large amount of calculation [35].
In this paper, a modified linear QHD is used to study the modulation effect of pump waves on the perturbation electron density and stopping power caused by the movement of charged particles above the 2DQEG. e outline of this article is as follows. In Section 2, the modified QHD is introduced to include the laser pump wave modulation and the two-dimensional electron exchange-correlation potential of high-density V xc2DH effects. e general expressions of perturbation electron density of 2DQEG and stopping power of incident charged particles are derived by the modified QHD theory. In Section 3, the numerical results of perturbation electron density of 2DQEG and stopping power of incident charged particles modulated by pump waves with various physical parameters (wavelength λ, amplitude Φ 0 , and time phase θ) are given. Section 4 gives a summary. Gauss system of units is adopted in this paper.

Physic Model.
e schematic diagram is given in Figure 1. 2DQEG is an idealized model, which corresponds to the electronic components on the surface or interface of metal or semiconductor in a very thin layer (only a few layers of atoms' thickness). For the convenience of studying, it is generally considered that the thickness of such twodimensional electron gas is taken negligible [41]. Consider an infinite 2DQEG composed of free electrons and motionless ions located on the plane z � 0, and use a Cartesian coordinate system to represent its position in the region z > 0 and z < 0. n 0 is the equilibrium density of electrons and ions. At equilibrium, 2DQEG density satisfies the relation n i � n e � n 0 [32]. Considering that the quantum effect is more significant in the high-density electron gas, we take the equilibrium density of electrons and ions as n 0 � 5.69 × 10 15 cm −2 , which is the density of aluminum surface [5].
Charged particles move in the x direction parallel to the 2DQEG plane, with a velocity of v � 2v B and a height of z 0 � 9λ f away from the 2DQEG. Here, v B � e 2 /Z is Bohr velocity, λ f � 1/ ���� 2πn o � 5.29 × 10 −9 cm is Fermi wavelength, and e is the elementary charge. e density of charged particles with charge Z 1 e can be expressed as We assume that the pump waves are collimated, monochromatic, continuous electromagnetic waves with wavelength λ propagating in the +x direction. Along the +x direction, the pump wave with the wavelength from 0.1nm (c rays) to 0.1cm (microwave) irradiates the 2DQEG. e electric field component of the pump wave acts on the 2DQEG as an external high-frequency electric field in the plane of x0y, and the reaction of the 2DQEG on the pump wave is without the scope of our consideration [35,42]. e electrons in the 2DQEG are affected by the pump wave electric field, which changes the spatial distribution of electrons in the 2DQEG. en, the exciting electric field by electrons in 2DQEG acts on the incident particle, which affects the velocity of the incident particle, thus affecting the stopping power of incident particles. In terms of electric field, the pump waves can be expressed as where k 0 is the wave vector of pump waves [40]. e time variable of the pump wave is t. e wavelength of the pump wave is λ � 1/k 0 . ω 0 is the frequency of the pump wave, where ω 0 � k 0 c, in which c � 2.998 × 10 10 is the speed of light. e intensity of the pump wave can be calculated by W p � c(k 0 Φ 0 ) 2 /8π [34], and the maximum intensity of the pump wave is 10 23 Wcm − 2 in this paper. When k 0 is constant, the strength of the pump wave is varying with the pump amplitude Φ 0 .

Mathematical Model.
As a powerful research method, QHD theory is widely used in plasma research [43][44][45]. Li et al. [4,5,46] conducted a series of studies on the stopping power of charged particles above the 2DQEG using linearized QHD theory, which is consistent with dielectric response theory and experimental results. In our research, the equilibrium electron density of 2DQEG will be disturbed by pump waves and injecting charged particles, generating charged fluid velocity field u e (r, t) and electron gas density n e (r, t). According to the linearized QHD theory, the density the momentum-balance equation and Poisson's equation Here, ∇ ‖ � z/zxe x + z/zye y , whereas in equation (3), the differentiation ∇ � z/zxe x + z/zye y + z/zze z is unrestricted. Φ denotes total electrostatic potential built on wake potential Φ ind caused by the collective excitation of electron gas and the charged particle's external potential. On the right-hand side of equation (2), the first term is the force of electrons on the 2DQEG surface due to the tangential electric field, and the second term is the force caused by the quantum statistical effect. Here, w e � πZ 2 n e /m e refers to the quantum statistical pressure term acting on electrons in 2DQEG, the third term is the force due to the quantum diffraction effects, the fourth term is the frictional force caused by the interaction between electrons and positive charge background where c is the friction coefficient, the fifth term is the force on electrons owing to the electric field of pump wave, and the last term is the force on electrons due to electron exchange-correlation potential V xc2DH . e validity of QHD equations (1) and (2) implies that the off-diagonal components of the pressure tensor and viscosity remain negligible.

Exchange-Correlation Potential.
Exchange-correlation potential is an important quantum effect term. Mir et al. considered the exchange-correlation potential when studying degenerate plasmas [40]. Haas derived a quantum fluid equation containing exchange correlation, which is described by an effective potential [47]. Pollack nd Perdew have made an in-depth study on the exchange-correlation potential of two-dimensional electron gas [48]. However, the exchange-correlation potential is not considered in the study of the interaction between incident particles and 2DQEG using the quantum hydrodynamic method so far. e three-dimensional electron exchange-correlation potential is expressed as follows: where a B � εZ 2 /m e e 2 is effective Bohr atomic radius, in which ε � 1 is the relative dielectric constant and m e is the electron mass [40]. We adapt the dimension of the three-dimensional electron exchange-correlation potential to the dimension of the two-dimensional electron exchange-correlation potential based on [40].
e two-dimensional electron exchange-correlation potential of low density is then expressed as follows [40]: and the two-dimensional electron exchange-correlation potential of high density is expressed as follows [40]: where r s � (2πn 0 a 2 B ) − 1/2 is the Wigner-Seitz radius associated with the 2DQEG density [48].
e V xc3D (solid line), the V xc2DL (dashed line), and the V xc2DH (dotted line) are shown in Figure 2. Here, the value of V xc3 D is positive, and the values of V xc2DL and V xc2DH are negative. It is reasonable to assume that two-dimensional electron exchange-correlation potential has completely different properties from its three-dimensional electron homologue. e Wigner-Seitz radius of 2DQEG that we are considering is r s � 1, the corresponding density is n 0 � 5.69 × 10 15 cm − 2 , and the corresponding exchangecorrelation potentials are V xc3 D � 0.1362, V xc2DL � −0.114, and V xc2DH � −0.6002 (these are dimensionless values). In previous studies of the interaction between charged particles and 2DQEG, the exchange-correlation potential was ignored due to its small value. Here, the absolute value of V xc2DH is the largest compared with V xc3 D and V xc2DL and the absolute value of V xc2DH is almost six times as much as the absolute value of V xc3D and V xc2DL . It is necessary to consider V xc2DH in the research of interaction between incident charged particles and 2DQEG by using the QHD theory due to the high density in the quantum electron gas.
is indicates that increasing density could enhance the exchange-correlation effect, as a function of the density. e exchange-correlation effect has been considered in quantum wells, GaAs/ GaAlAs heterostructures, and silicon inversion layers, with the local density approximation method [49,50].

Laser and Particle Beams
are the first-order perturbed quantities of velocity, density, and potential, respectively. We linearize the above equation to obtain the perturbation electron density n e1 and the induced potential Φ ind [5]. Here are the linearized continuity equation the momentum-balance equation and Poisson's equation where Φ 1 � Φ ext + Φ ind . Φ ext is the external potential of the incident particle. Φ ind is the induced potential by the perturbation electron density. Take the Fourier transform of the above linearized equations in space-time, and obtain the perturbation electron density n e1 and the induced potential Φ ind : where with ω � ω + ic. Bohr radius a B � Z 2 /m e e 2 , Fermi velocity v F � Zk F /m e , Fermi wave-number k F � ���� 2πn 0 , and electron plasma frequency ω p � (2πn 0 e 2 /m e a B ) 1/2 . k � k x , k y is a two-dimensional wave vector. Consider that ω � k · v and the projectile velocity v and the x axis are going in the same direction, hence ω � k x v.
For convenience, we introduce the dimensionless variables: (11) can be reduced to Here, t denotes time variable, ω 0 is constant when the wavelength λ is fixed, and θ � −ω 0 t is used to modulate the phase, and it highlights the sine function factor oscillation of pump waves. Note that the introduced V xc2DH affects the electron density distribution by modifying the value of D, determined through the Wigner-Seitz radius r s thus by the equilibrium density n 0 . e second term of the reduced perturbation electron density is induced by the electric field of the pump wave in equation (14). Because the pump wave satisfies the relation k 0 � 1/λ, the second term of the reduced perturbation electron density is modulated by the wavelength λ, the amplitude Φ 0 , and the time phase θ. Furthermore, the stopping power S(v) determined by wake force can be given by the value of the gradient of the induced potential Φ ind [32]: In the calculation above, the residue theorem is used. Using dimensionless variables, equation (16) can be reduced to where e stopping power is related to the velocity v of the incident particle. When the velocity variable v is extracted from the sine and cosine functions, the time variable t is also exposed. Similarly, to study the influence of the time variable t on the sine and cosine functions, we introduce the time phase θ, which means that the time variable t is changing the sine and cosine functions with −c 0 t in equation (16) while the time phase θ is changing the sine and cosine functions through θ in equation (17). Note that the second term of the stopping power is induced by the excited electric field of the pump wave in equation (16). e pump wave satisfies the relation ω 0 � k 0 c and 3k 0 � 1/λ, and hence, the second term of the stopping power is modulated by the wavelength λ, the amplitude Φ 0 , and the time phase θ.
In the next section, we will give the result of the effect of V xc2DH on the stopping power of the incident particle. To investigate the effect of pump wave on the perturbation electron density of 2DQEG and the stopping power of the incident particle, we calculate the perturbation electron density and the stopping power under different wavelength λ, amplitude Φ 0 , and time phase θ. In what follows, we take r s � 1, the collision frequency c � 0.02ω P , incident particle as a proton Z 1 � 1, and the distance between the incident particle and 2DQEG z 0 � 9λ f , while the wavelength λ, the amplitude Φ 0 , and the time phase θ of the pump wave are varied. As it can be assumed, V xc2DH modified the stopping power of the incident particle because V xc2DH has been considered in the momentum-balance equation, thereby changing the value of D and D 0 in equation (16) and modifying the stopping power of the incident particle. In order to verify the necessity of introducing V xc2DH to modifying QHD, Figure 3 presents the stopping power of the incident particle versus particle velocity under different conditions.

Two-Dimensional Electron Exchange-Correlation
Comparing the curve of stopping power without exchange-correlation potential (solid line), the curve of stopping power with V xc3D � 0.1362 (dashed line), the curve of stopping power with V xc2DL � −0.114 (dotted line), and the curve of stopping power with V xc2DH � −0.6002 (dashdotted line) are shown in Figure 3. Considering the peak of the stopping power of the incident particle near V � 3.5V B in Figure 3, the value of stopping power without exchangecorrelation potential exhibits an obvious difference with respect to stopping power featured by V xc3 D , V xc2DL , and V xc2DH . e value of stopping power without exchangecorrelation potential is 0.01517S 0 . e values of stopping power with V xc3D , V xc2DL , and V xc2DH , respectively, are 0.01506S 0 , 0.01525S 0 , and 0.01559S 0 , which, respectively, are changed by 0.725%, 0.527%, and 2.77% relative to stopping power without V xc (these are dimensionless values). e results show that the two-dimensional exchange-correlation potential, especially V xc2DH , influences the stopping power of incident particles. V xc2DH is adapted throughout the paper within subsequent results.

Amplitude of Pump
Wave. In order to study the modulation of pump wave amplitude Φ 0 on the perturbation electron density and the stopping power, Figures 4 and 5 show the spatial distribution of the perturbation electron density as a function of x and the stopping power of the incident particle versus particle velocity under three different intensity conditions of the pump wave, where the wavelength is λ � 1.67 × 10 − 8 cm. e comparison of the perturbation electron density without the pump wave and with the pump wave for Φ 0 � 1 × 10 2 e/λ f , Φ 0 � 2 × 10 2 e/λ f , and Φ 0 � 3 × 10 2 e/λ f , respectively, shows that the oscillation amplitude of the perturbation electron density increases when considering the pump wave in most cases and the oscillation amplitude of the perturbation electron density becomes larger as the amplitude of the pump wave increases in Figure 4. is is because the value of the second term in equation (14) is proportional to the factor of Φ 0 . But the oscillation amplitude of the perturbation electron density displays specific features near x � −29λ f . is is due to the value of the incident particle external potential and induced potential by the perturbation electron density. e comparison of the stopping power without the pump wave and with the pump wave for Φ 0 � 1 × 10 2 e/λ f , Φ 0 � 2 × 10 2 e/λ f , and Φ 0 � 3 × 10 2 e/λ f , respectively, shows that the pump wave yields obvious modulation effects on the stopping power, and the intensity of this modulation is proportional to the amplitude of the pump wave in Figure 5.
is is because the value of the second term in equation (17) is proportional to Φ 0 . In the low-velocity region (v < 8.3v B ), the stopping power that peaks at v � 3.5v B with the pump wave for Φ 0 � 1 × 10 2 e/λ f , Φ 0 � 2 × 10 2 e/λ f , and Φ 0 � 3 × 10 2 e/λ f ,    respectively, increases by 12.4%, 24.7%, and 37.1% relative to the case without the pump wave. Moreover, in the high-velocity region (v > 8.3v B ), it is easy to see that the pump wave dominates the stopping power as the particle velocity increases compared to the stopping power quickly vanishing without the pump wave. e value of stopping power at v � 13.7v B with pump wave for Φ 0 � 3 × 10 2 e/λ f decreases to −0.003772S 0 . It is surprising that a negative stopping power [34] is found due to the existence of the pump wave, different from our observation without the pump wave. e appearance of negative stopping power means that the particle drains energy from the 2DQEG.
Generally, when the pump wave does not exist, due to the disturbance of the electron density in 2DQEG caused by charged particles, negative charges will accumulate behind the charged particles in 2DQEG to excite the wake field, thereby reducing the speed of the charged particles. When the pump wave exists, in addition to the density disturbance of 2DQEG caused by charged particles, we also need to consider the density disturbance caused by the electric field component of the pump wave. Since the electric field of the pump wave changes periodically with time, the density disturbance caused by the electric field component of the pump wave will also change periodically. e deceleration and acceleration effects of the electric field excited by the perturbation density caused by the pump wave on the charged particles will change periodically with time. When the electric field excited by the perturbation density caused by the pump wave in 2DQEG has a deceleration effect on the charged particles, the stopping power of the charged particles will increase. When the electric field excited by the perturbation density caused by the pump wave accelerates the charged particles, the stopping power of the charged particles will decrease. When the acceleration of the electric field excited by the perturbation density caused by the pump wave has a stronger effect on the charged particles than the deceleration of wake field excited by the charged particles, the velocity of the charged particles will increase and negative stopping power appears. In other words, the polarity of wake field can be tuned in the presence of the pump wave, yielding the negative stopping power.
In the case of λ � 1.56 × 10 − 7 cm, the comparison of the perturbation electron density and stopping power without the pump wave and with the pump wave shows that the modulation effect on the oscillation amplitude of the perturbation electron density and stopping power is proportional to the amplitude of the pump wave in Figures 6 and 7. As the value of the second term in equations (14) and (17) increases with increase in Φ 0 , it is easy to see that the oscillation amplitude of the perturbation electron density at x � −5λ f with the pump wave for Φ 0 � 1 × 10 2 e/λ f , Φ 0 � 2 × 10 2 e/λ f , and Φ 0 � 3 × 10 2 e/λ f , respectively, increases by 22.2%, 44.5%, and 66.8% in Figure 6. At x > 10λ f or x < − 46λ f , the pump wave with wavelength λ � 1.56 × 10 − 7 cm dominates the oscillation amplitude of the perturbation electron density compared to the perturbation electron density quickly vanishing without the pump wave. e stopping power at v � 3.5v B with the pump wave for Φ 0 � 1 × 10 2 e/λ f , Φ 0 � 2 × 10 2 e/λ f , and Φ 0 � 3 × 10 2 e/λ f , respectively, increases to 0.03991S 0 , 0.06422S 0 , and 0.08854S 0 in Figure 7.
In the case of λ � 1.76 × 10 − 6 cm, the comparison of the perturbation electron density and stopping power without the pump wave and with the pump wave shows that the pump wave has an obvious modulation effect on the oscillation amplitude of the perturbation electron density and stopping power in Figures 8 and 9, and the modulation effect of pump wave strengthens as the amplitude of pump wave increases, which again arises from equations (14) and (17) second term proportional to Φ 0 . e modulation effect of the pump wave only changes the amplitude, not the shape of the perturbation electron density and stopping power. It is easy to see that the oscillation amplitude of the perturbation electron density at x � −5λ f with the pump wave for Φ 0 � 1 × 10 2 e/λ f , Φ 0 � 2 × 10 2 e/λ f , and Φ 0 � 3 × 10 2 e/λ f , respectively, increases by 22.9%, 45.8%, and 68.7% in Figure 8. e oscillation amplitude of the perturbation electron density increases with the pump wave amplitude. e amplitude of the stopping power at v � 3.5v B with pump wave for Φ 0 � 1 × 10 2 e/λ f , Φ 0 � 2 × 10 2 e/λ f , and Φ 0 � 3 × 10 2 e /λ f , respectively, decreases to 0.004182S 0 , −0.0007226S 0 , and −0.01862S 0 in Figure 9. e oscillation amplitude of the Laser and Particle Beams stopping power rises as the amplitude of the pump wave increases. Interestingly, the negative stopping power is also found in Figure 9. Figures 10-15 show the perturbation electron density and stopping power with the pump wave for λ � 1.76 × 10 − 4 cm, λ � 1.76 × 10 − 2 cm, and λ � 1.76 × 10 − 1 cm. e results of Figures 12 and 14 are similar to that of Figure 10. And the results of Figures 13 and 15 are similar to that of Figure 11 because the variations of the second term in equations (14) and (17) remain small in the domain of −120λ f < x > 80λ f and 0 < v > 20v B . e oscillation amplitude of the perturbation electron density increases as the amplitude of pump wave rises in Figures 10, 12, and 14. e effect of the pump wave on the stopping power strengthens as the amplitude of pump wave increases in Figures 11, 13, and 15. erefore, the amplitude of the pump wave has a significant effect on the oscillation amplitude of the perturbation electron density and stopping power, while the oscillation amplitude of the perturbation electron density and stopping power rises with the pump wave amplitude. e amplitudes Φ 0 ≤ 5 × 10 5 e/λ f are realistic values in current experimental technologies and consistent with those used in [51]. e wavelength of the pump wave is an essential parameter for the modulation of the pump wave on the perturbation electron density and the stopping power. Comparing Figures 14 and 15, it is found that the influence of wavelength of the pump wave on the perturbation electron density and the stopping power is mainly reflected in the modulation of the shape of the perturbation electron density curve and the stopping power curve.
Let us consider the perturbation electron density curve and the stopping power curve for a short wavelength of the pump wave of λ � 1.67 × 10 − 8 cm. In the space range from −120λ f to 80λ f , the perturbation electron density shows a violent periodic oscillation, contrasted to the no pump wave case, as shown in Figure 4. e stopping power also has been modulated by the pump wave in the velocity range from 0v B to 20v B in Figure 5. e reason is that the second term contains the factor k 0 in equations (14) and (17), which is inversely proportional to the wavelength λ. So the perturbation electron density and the stopping power are strongly modulated by the pump wave.
Observe the perturbation electron density curve and the stopping power curve with a wavelength of λ � 1.56 × 10 − 7 cm. e number of oscillating periods of the perturbation electron density decreases over a range of −120λ f to 80λ f in Figure 6. e oscillation period of the stopping power is smaller than one period in the velocity range from 0v B to 20v B in Figure 7. is is because the k 0 value decreases in equations (14) and (17) as the wavelength λ is increasing. erefore, the effect of the pump wave on the perturbation electron density and stopping power modulation is reduced compared to the wavelength λ � 1.67 × 10 − 8 cm.
With the wavelength of the pump wave λ � 1.76 × 10 − 6 cm, the perturbation electron density oscillates less than one period in the space range of −120λ f to 80λ f in Figure 8. e stopping power oscillation period is also shorter than one period in the velocity range from 0v B to 20v B in Figure 9. As the wavelength λ becomes longer, the value of k 0 becomes smaller. e pump wave modulation to perturbation electron density and stopping power is further reduced in the region of −120λ f < x < 80λ f and 0 < v < 20v B .
When the amplitude of the pump wave is Φ 0 � 3 × 10 2 e/λ f , the maximum value of perturbation electron density curves with wavelength λ � 1.67 × 10 − 8 cm, λ � 1.56 × 10 − 7 cm, and λ � 1.76 × 10 − 6 cm, respectively, is 0.2082n 0 , 0.2469n 0 , and 0.2497n 0 in Figures 4,6,and 8. ose results show that the maximum value of the perturbation electron density increases in the region of −120λ f < x < 80λ f with the wavelength which means that the wavelength of the pump wave not only modifies the shape of the curve but also the amplitude of the perturbation electron density. Comparing the stopping power curves when the amplitude of pump wave is Φ 0 � 3 × 10 2 e/λ f in Figures 5, 7, and 9, the maximum value of stopping power with wavelength λ � 1.67 × 10 − 8 cm, λ � 1.56 × 10 − 7 cm, and λ � 1.76 × 10 − 6 cm, respectively, is 0.02137S 0 , 0.08854S 0 , and −0.01863S 0 . e value of stopping power dramatically changes because k 0 varied when the wavelength is increasing.
As the wavelength of the pump wave increases, the pump wave modulates the shape of the perturbation electron density curve more and more weakly in the space range of −120λ f to 80λ f in Figures 10, 12, and 14. Similarly, as the wavelength of the pump wave increases, the shape of the stopping power curve is modulated more weakly by the pump waves in the 0v B to 20v B speed range in Figures 11,13,and 15. e modulation of the wavelength of the pump wave to the shape of the perturbation electron density curve and the stopping power curve decreases as the wavelength increases, arising from the tiny second term change in equations (14) and (17).

Phase of Pump
Wave. Finally, in order to study the effect of time phase θ on the perturbation electron density and stopping power, Figures 16-19 exhibit the perturbation electron density and stopping power with wavelength λ � 1.67 × 10 − 8 cm and λ � 1.76 × 10 − 4 cm for θ � 0 (solid line), θ � π/2 (dashed line), θ � π (dotted line), and θ � 3π/2 (dash-dotted line). Here, Φ 0 � 1 × 10 2 e/λ f . It is easy to see that the amplitude of perturbation electron density and stopping power oscillates periodically with different time phase θ in Figures 16-19. is is because the second term includes the parameter time phase θ in equations (14) and (17). erefore, the time phase θ obviously impacts the perturbation electron density and stopping power.
It is worth pointing out that the negative stopping power in Figures 5, 9, and 19 we found is instantaneous, which is difficult to verify experimentally, and it is also difficult to apply. So we consider averaging the stopping power with respect to the time phase θ. After averaging the stopping power with respect to the time phase θ from 0 to 2π, we found that the pump wave with Φ 0 � 1 × 10 2 e/λ f decreases the value of stopping power in Figure 20. is is because the value of averaged second term is negative in equation (17) with respect to the time phase θ. But amplitude reduction shows up as a relatively small one in connection to the too low pump wave intensity ( Figure 20). is is because the intensity of pump wave is too low. Linearized QHD is valid only for low intensity of pump wave. e comparison of the stopping power without the pump wave and the average stopping power with pump wave for Φ 0 � 2 × 10 10 e/λ f and λ � 1.76 × 10 − 4 cm demonstrates that the average stopping power decreases in the region of 0 < v < 20V B in Figure 20.
It is an exciting result that the average stopping power of the incident particles is negative in the region v < 2.3v B and v > 5.8v B when λ � 1.76 × 10 − 4 cm and Φ 0 � 2 × 10 10 e/λ f . e incident particles will gain energy and can be accelerated within the velocity range of v < 2.3v B and v > 5.8v B . Although this result is not strictly obtained by using the linearized QHD due to the amplitude of pump wave which is too large, this could predict qualitatively that the time averaged stopping power has indeed been affected by the pump waves.
In conclusion, the time phase of pump wave θ can adjust the value of perturbation electron density effectively and stopping power, and the averaging of the stopping power with respect to the time phase θ also has been impacted. erefore, one can see that the perturbation electron density and stopping power depend on λ, Φ 0 , and θ, indicating that the pump wave using different parameters can modulate the perturbation electron density and stopping power of 2DQEG.

Summary
In this paper, considering the electron exchange-correlation potential V xc2DH in QHD, we have calculated the perturbation electron density and stopping power with the modulation of pump wave for a charged particle with a constant distance and speed moving above 2DQEG. In our calculation, we compare the stopping power with and without V xc2DH and show that it is necessary to consider V xc2DH in 2DQEG. en, we compare the perturbation electron density and stopping power with different wavelength λ, amplitude Φ 0 , and time phase θ of the pump wave and show that it is meaningful to investigate the modulation effect of the pump wave on the perturbation electron density and the stopping power. e wavelength λ, the amplitude Φ 0 , and time phase θ of the pump wave can effectively modulate the value of the perturbation electron density and stopping power. e temporal averaged stopping power with respect to the time phase θ also has been influenced by pump waves. e possible experimental equipment to verify the prediction includes three components: pump wave, charged particle beam, and 2DQEG. e pump wave can be provided by laser or microwave device, the plasma wake field [52] can produce the charged particle beam, and 2DQEG has already been observed in experiments [2,3]. All of them can be realized with present technology. At present, the intensity of laser systems provided by the laboratory has arrived 10 24 ∼ 10 26 Wcm − 2 [53]. us, the parameter of the pump wave considered here can be easily satisfied. We can verify the negative stopping power by measuring the velocity of the incident particle. For instance, charged particles move in the x direction parallel to the 2DQEG plane, with a velocity of v and a height of z 0 away from the 2DQEG, and the pump wave irradiates the 2DQEG along the +x direction. e wavelength of pump wave is λ � 1.76 × 10 − 4 cm and Φ 0 � 2 × 10 10 e/λ f . e density of two-dimensional electron gases is n 0 � 5.69 × 10 15 cm − 2 .
e velocity of incident particles is v � 2v B (v B � 2.18 × 10 8 cm/s), and the distance between incident particles and two-dimensional electron gases is z 0 � 9λ f � 4.76 × 10 − 8 cm. e measured particles flying out the right side of the 2DQEG will gain energy from the 2DQEG and get accelerated.
It is appropriate to investigate the stopping power modulation by low-intensity pump waves of the charged particle moving above two-dimensional electron gases using the linearized QHD, but linearized QHD is not strictly applicable to high-intensity pump waves. In future work, we attempt to further study the effect of high-intensity pump waves on the stopping power with nonlinear QHD.
Data Availability e data that support the findings of this study are available from the corresponding author upon reasonable request.

Conflicts of Interest
e authors declare that they have no conflicts of interest. Laser and Particle Beams 11