2.1 Analysis of two models of excited gravity
Excitation and the use of the gravitational field, the method 1 synthetic heavy chemical element, make element quality his little black hole, gravitational field, space and time distortion, control increased, dark energy, because the gravitation closely connected with dark energy, modern physics experiment confirmed that excite gravity method 2, like Einstein's general theory of relativity, space-time distortion within the space of the earth, the physical method to change the magnet or electric wire of atomic internal structure, as far as possible let magnet magnet magnetic field and the metal coil of the electric field force, expansion far field intensity range, to expand, expanding field line, if the field line string is the solar system, etc., Evolve into universal gravitation physical properties, chemical properties of the same force and field, the force of the same nature interact with each other, in the universe the magnitude of the gravitational force is greater than the earth's gravity, in the balance Angle of the force, using this principle to create spacecraft, can fly freely in space. Magnetism and electricity, the nuclear force is the force that we think of, and the force that exists in the universe, so we experiment with it. Unified field theory studies from electromagnetic field, nuclear force and gravitational field. Unified field theory holds that when any object in the universe is at rest relative to us, the space around it has a velocity C of light. Radiative motion, and therefore a body has a special resting momentum m'c, when the body is moving with a velocity V relative to us, its momentum is m(C-v).
Nuclear force, electromagnetic force and universal gravitation surface are the interaction forces between objects. Essentially, they are all caused by the changes of matter points in space relative to the motion state of our observer. They are all inertial forces and the rate of change of momentum P = m(c-v) with time t.
F = dP/dt = Cdm/dt- Vdm/dt + mdC/dt - mdV/dt
(C-V)dm/dt = Cdm/dt- Vdm/dt
According to unified field theory, it is the force of mass changing with time, and it is the electromagnetic force. Cdm/ dt is the electric field force, Vdm/ dt is the magnetic field force,
The inertial force in mdV/ dt in Newton's second theorem is also universal gravitation, and mdC/ dt is the nuclear force. Want to have a particle relative to the observer we rest, o space around an arbitrary point space geometry (in order to describe the movement of the space itself, we have divided our infinite space into many small pieces, each piece is called space geometric point, hereinafter referred to as geometric point) p C at light speed in zero time, this paper argues that the speed of light to the vector, the speed of light as a vector direction can change) starting from point o, along a certain direction, experienced a time t, in t 'moment will arrive at the location of the p, let xyzo point o in rectangular coordinate system origin, point to point p radius vector by point o R = C.
t = x i+ y j + z k
R is a function of the spatial position x, y and z, which varies with the change of x, y and z, denoted as:
R = R(x,y,z,).
We enclose the particle o as a Gaussian sphere s= 4πr² (the volume of the inner sphere is 4πr³/3) with the radius R =Ct which r is the length R in the Ct.
The gravitational field A around point o represents the displacement vector R = Ct of n geometric points in the volume 4πr³/3 around point o,
A = g(3k n /4π)R/ r³ = g mR/ r³
k is the constant of proportionality. g is the gravitational constant.
The mass m of the mass point o represents the ratio of the number n of the geometric point vector displacement R = Ct and the solid angle 4π within the Gaussian sphere s = 4πr² (the volume of the inscribed sphere is 4πr³/3).
m = 3 k n /4π
Thus, the above gravitational field equation A = g(3k n /4π)R/ r³ can be written as:
A = g m R /r³
Newton's law of universal gravitation states that the gravitational field a = gm/r² generated at the space p around the particle o (the radius of the vector from o to point p is R, the distance from point o to point p, that is, the number of vector R is r), Vector formula:
A = g m R/r³
The above gravitational field equation and Newtonian mechanics gravitational field equation are consistent.
In the mass equation introduced above m = 3 k n /4π, the angle is a constant 4π. In fact, the angle can be a variable, varying between 0 and 4π. Both n and m can be variables, and the mass equation still holds.
We introduce the concept of solid angle Ω and write the mass equation m = 3k n /4π in a general form:
m = k n /Ω
Correspondingly, there are more general gravitational field equations:
A = g m R /r³ = g k n R/Ωr³
The corresponding Gaussian surface is
s =Ωr²
In the unified field theory, the electric field E generated by a particle o with a mass of m at the surrounding space p is defined as the change of the mass m in the gravitational field with time t.
That is
E = g k’(dm/dt )R /r³ = qR/εo4πr³
g and k' are constants, and εo is the vacuum dielectric constant.
Humans have discovered that when charged particles move at a speed V relative to our observer, they can cause a change in the electric field in the vertical direction of V. The part of the electric field change can be regarded as a magnetic field, that is, the electric field that changes with the speed produces a magnetic field. Field theory inherits this view.
Imagine a point o, which is stationary relative to our observer, with a mass of m and a charge of q. An electrostatic field E is generated in the surrounding space p. The radius of the vector from point o to point p is R, which is generated by point p The electric field E is:
E = q R/4πεor³ = k’( dm/dt)R/4πεor³
K’ is a constant.
When point o moves relative to us at a speed V, it can cause a change in the electric field E. The part of the change can be regarded as the magnetic field B. The simple idea is that the electric field E multiplied by the speed V is the magnetic field B. Because of the speed V and the electric field When E is perpendicular to each other, the generated magnetic field is the largest, so there is a cross product between them, so there is the following relationship,
B = constant multiplied by (V × E)
From the geometrical equation of the electric field E
E = q R/4πεor³ = k( dm/dt)R/4πεor³,
The geometric form equation of magnetic field B can be obtained,
B = constant multiplied by [V ×(q R/4πε。r³)]
= constant multiplied by [V ×k’( dm/dt)R/4πε。r³]
Combining the constants, because we are discussing here in a vacuum, the above constant related to the magnetic field B uses the vacuum permeability μ. representation
B = μo[V ×k’( dm/dt)R/4π r³]
The above is the geometric form equation of the magnetic field in vacuum. This equation is closely related to the equation B = V ×E /c² that is satisfied by the relationship between the electric field and the magnetic field.
B =μo[V ×k’( dm/dt)R/4πr³]
= μo[V×(q R/4πr³)]
= μo[V×εo(q R/4πε。r³)]
= μoεo[V×(q R/4πε。r³)]
= μoεo(V×E)
In electromagnetics, it is considered that the magnetic permeability in vacuum is μ。. And the dielectric constant ε。. The product of is the reciprocal of the square of the speed of light c in vacuum (this is artificially specified), so the above equation can be written as:
B = V×E /c²
The above equation reflects the basic relationship between electric field and magnetic field. From this equation plus the space-time homogenization equation r²= c²t², it can be derived that Maxwell’s equations are variable magnetic fields to produce electric fields and variable electric fields to produce magnetic fields.
Note that the above magnetic field and moving electric field do not consider the relativistic effect, but only hold when V is very small or equal to zero.
The electric field E generated when the charge moves should be multiplied by the relativistic correction phase Ψ=(1- v²/c²)/{√[1- (v²/c²)sin²θ] }³, where θ is the geometric point displacement R and the x-axis Angle. The electric field equation multiplied by the relativity correction phase Ψ does not affect the relationship between the electric field and the magnetic field.
In unified field theory, mass and gravitational field are defined in this way. The universal gravitational field, electric field, and nuclear force field exist when the particles are at rest.
Gravity is proportional to acceleration and mass, and is the main force between objects with large mass and low velocity.
The force of the electromagnetic field is proportional to the change of mass over time, and the change of mass depends on the speed, and has nothing to do with the acceleration and the size of the mass. Therefore, the electromagnetic field force is the main force between objects with small mass and high speed.
The nuclear force is the force that changes the direction of the speed of light, and is related to the motion state of the particles being acted upon, so it is more complicated.
Below we use the basic electromagnetic field relationship B = V×E /c² combined with the gravitational field combined with the definition equation to derive the mathematical relationship between the changing magnetic field and the gravitational field.
We still use the previous o point as the object of description. When o point is stationary relative to our observer, there is a geometric point p in the surrounding space, and o point generates an electrostatic field E’ at point p.
When point o moves at speed Vx (for simplicity of description, we specify V along the x axis) relative to our observer, a magnetic field B is also generated at point o at p, and:
B = V×E /c²
We assume that the electric field E does not change with time t, and we obtain the partial derivative of the magnetic field B and velocity V with respect to time t in the above formula, and the result is:
∂B/∂t = (∂V/∂t)×E /c²
There are results:
∂Bx/∂t = 0
∂By/∂t = -(∂Vx/∂t)Ez/c²
∂Bz/∂t =(∂Vx/∂t)Ey/c²
According to the previous analysis, the gravitational field can be regarded as the acceleration of a geometric point ∂V/∂t. From the above equation, it can be seen that the changing magnetic field, electric field, and gravitational field are perpendicular to each other.
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hvn1RL7RL0aunJEu5Dgl4CrBCynn766aZx48YZQV988cXNww8/HEJNKrLWCEjQa63HZUOPtcdnzpxpunXrlhFzzC7Y0fv16xdru1R5dRCQoFdHP5Z0Fxqhl4TLaeZnnnnGrLrqqnUEvUGDBmazzTYzc+bMcVqXCqs9AhL02utzebnE2OdXXHFFHXOLNzGKT/qzzz4bY8tUdTUQkKBXQy+WeA8aoZcIzFH2uXPnmp49e9YZnXuCjk190KBBjmpSMbVKQIJegz0vQY+n06dNm2Y23HBDX0HH7LLnnnuan3/+2WnjeIi88cYb5tVXX6349corr5h33nnH/PXXX07bqMLcEZCgu2OZmpIk6PF01d13323waPFG5bnva6+9tnnttdecNu7CCy80rVu3Ns2bNzctWrQwyy+/vP2bd9wlOe73WnrppQ0vrsEcRBnk33TTTc1XX33ltI0qzB0BCbo7lqkpSYIefVf9/vvv5tRTT80r5oh706ZNzfXXX++0cYyob7/9dnPZZZeZHj161Kl/hx12MPfcc48ZM2ZMnRcBwwYPHmzOOeccs9dee1nB9x4+HTt21OSt0x5yW5gE3S3PVJQmQY++m4jXst1229URVE8ks9/79OkTWuPuvffeTP2Mvm+77baidWFewUe+Q4cO9lru4c8//yx6nTLEQ0CCHg/3WGuVoEeP//HHH7emi2zx9vu85ZZbmg8//DCUBvbt2zcj6Ouuu25Jsdj79+9vr+3Vq5f5+++/Q2mfCq2cgAS9coapK0GCHm2XYW658sorM2LqJ+TeMWzV999/v/MG/vLLL5kJWW8Clh2TgqahQ4faYGLnn3++BD0otBjySdBjgB53lRL0aHuAYFzYoj3RLvaO+6Jrs8bUqVPtJCd1N2rUyJx22mklQbjhhhtMw4YNzZ133mn++eefkq5V5ugISNCjY52YmiTo0XbF22+/bVZYYYXAgr777rubb775xmkjPUFG0LGfjxs3Lm/5/KLITddcc40V9Oeee06CngsnQX9L0BPUGVE1RYIeFWljfbbxMsk3Ksf8kXtu5ZVXNi+88ILTRu63337Gq2uttdYyX3zxhW/5N910k+ndu3e9cwMGDDBNmjQxb731Vr1zOpAcAhL05PRFZC2RoEeG2vz222+GzSyyRXu99dazsVsIyrXYYouZgw8+uI5rIBtfDBs2zPzxxx9OGsriIi/+OmaTffbZx9ek89NPP1k7O3lzE+6N+LT/8MMPuaf0d4IISNAT1BlRNUWCHhVpY1d+Zsc+32abbeyKzZNOOsksuuiidqHRAw88YB566KE6QbuOPPJI8+OPPzppKAHBvDZQ50UXXeRb7tNPP21H4SeeeGK98zyYfv31V5lb6pFJ1gEJerL6I5LWSNAjwWwreeqpp+zonFH3UUcdZb777jt7/JRTTskI+sSJE+2xN998024azWh+pZVWMp988omThl5yySWZgGCYTfxWo+IFQ8RHJkzZgEMpnQQk6Onst4paLUGvCF9JF5988sl2M+jzzjvPZLsJZgv6o48+minzs88+M4ceeqiNkc6o3YXPNx42mFp4UBAE7LrrrjNMko4YMcLceOON5uyzzzaEHSAPI/lvv/020x59SBcBCXq6+stJayXoTjAWLQTbdffu3c3IkSPr5c0n6GTkOsweLL/H1FFJmjVrVmaVJ4LOCH2JJZaw73zGhu9NlnK+S5culVSna2MmIEGPuQPiqF6CHg11JhBfeukl38oKCbp3AddWKugTJkzIrFBlBI63CrbySZMmmccee8wQDoDFQgTrQtAvvvhir3q9p5CABD2FnVZpkyXolRKs/Poggl55LcZccMEFdjSOWC+55JLm3Xff9S0WswzmGG2y4YsnNQcl6KnpKncNlaC7Y1luSVEIOl4pBx10UMakss466+T1Uunatas1zXiTttn3NWPGDOt/7rfgKDufPsdPQIIefx9E3gIJeuTI61UYhaC///77ZoMNNsj4wBOcyy+xqQYmFyZjcydhCVtw9NFHm+OPP14+6H7wEnZMgp6wDomiORL0KCgXriMKQcc+vuyyy2YEnb/9EiN5vF3YUSk34VJJGZdeeqlZsGBB7mn9nTACEvSEdUgUzZGgR0G5cB1RCDorO1lIhP2cXYfy2c9pKatSc4NuMSGL2+Uqq6zi67te+A51Ng4CEvQ4qMdcpwQ95g4wxoQt6N9//70NKYCY89p+++1NqTZwvGzatGljTjjhBDN//vz4oakFRQlI0Isiqr4MEvT4+zRsQWdj6OwNqQnJmzsCL0SBlaPY3Fu2bFkwMmOhMnQuegIS9OiZx16jBD32Lgh9hE54XDZ/9kbohCAImth27r777rNhAHbeeWfDaN8v8YAgoBeRG9k4OtfGTjlMquYe9ytLx9wQkKC74ZiqUiTo8XdX2CN0NoX2xJxwvJ9//nmgm2aC9IknnjDsnEQ0yKuuusr3OsR8+vTp5owzzjB77723YUu7UaNG1YniyENkq622Ml6sGt+CdNApAQm6U5zpKEyCHn8/uRZ0b7SMC+IHH3xg2CTDE/RddtnFjqIZTfu9Zs6cafA1ZwXpWWedZc0sXLvxxhsbXB/9EsJ/7LHH2o2m33vvPdO+fXtz+OGHmzlz5tjsuD8Sg53FTGyKoRQNAQl6NJwTVYsEPf7ucCnomDYItnXIIYdYX/Idd9zRjq49QWeEzgIj/MxzX1yD+BNpsUWLFpmHANf6hdH1yBGxcbfddrOhCcaOHWtjwuBV44UqIOwBo/zNN988I/LetXoPj4AEPTy2iS1Zgh5/17gUdLxXmMDcZJNNrDBvscUWZtttt7WeLXi3EIMdYUW0/V6c23LLLW2+7bbbzl63//77F3RV/Pjjj83kyZNtILGePXvahUnZuywRQZKHAm6PStERkKBHxzoxNUnQ4+8Kl4KOuYWQt59++qkh/K6LF3uaUm6xhKizXyq7LmVvyMHKUoKBZYcGLlaWzldOQIJeOcPUlSBBj7/LXAp6XHeDqeeWW24xbN5x7bXXZh4A2NGxv7PCFPdHpegISNCjY52YmiTo8XdFNQg6i41OO+00s/TSS9fxZJkyZYrdWg+7vVK0BCTo0fJORG0S9Pi7oRoEHf9ywvMS2MvzZMFMw1Z7uDz6bewRP/nqboEEvbr71/fuJOi+WCI9WA2CDjB8zdm+jm3spk6dav3S2RGJRU2u9kSNtGNSXpkEPeUdWE7zJejlUHN7TTUIOjZ0RunvvPOOIbTAwIEDrbAj5rvuuqtbYAkq7c8//7T3jXdRoVfupDJ/EwQt3zWwhGklSYJeCb2UXitBj7/j0i7oCA/heNn8Gq8aL3FfxH9hi7tqTNz3sGHDzCWXXGIuv/xyc+WVV9Z5XXHFFYZVuqyw9RZZeRxYvDV8+HAzZMgQ32suuugiuy1gJaESJOge7Rp6l6DH39lpF/R58+bZsLos7f/www8tUOK/tGvXziBMlYhS/L2TvwXcN/dMqINWrVrVWYjlLeQi3DAxcFiBm52efPJJ07lzZ+vO6eX13ldccUXDjlI8CFiFW26SoJdLLsXXSdDj77y0CzorQlnajycLK0UZmeKLzgi0EkGKv2cKtwBzy9tvv23nC+68804r0J4o884Cr8cff9x3/oCwDK+//rrp1q1b5kHAQi82DyHeDatvWWFbSZKgV0IvpddK0OPvuLQLOvZgVovecccd9nXPPfdYscrdwi5+0uG24LrrrsuIM4KOP36xxIbc5CW0AnF3XCYJukuaKSlLgh5/R6Vd0D2CTPLhj87ItRbTq6++atZaa62MqBN2odBmINje8QLq37+/wXzjOknQXRNNQXkS9Pg7qVoEPX6S8baA6JVEnfTMLo0bN7bhh/1aRQA1PIAQ87DMUhJ0P/JVfkyCHn8HS9Dj7wNXLcDslB2psnfv3vWKfuCBBwwTn7169cq7YUi9i8o4IEEvA1raL5Ggx9+DEvT4+8BVCwiKRrRKb5RODPjsEfjzzz9vPViIfPnll1+6qta3HAm6L5bqPihBj79/Jejx94HLFhDTplGjRhlRHzFihC2e1bO4Km666abOJ0D92i9B96NS5cck6PF3sAQ9/j5w2YJnnnnGtG3bNiPoXbp0MWzUjT96x44dDQHLokgS9CgoJ6wOCXr8HSJBj78PXLaAFaSYVDyzC6N1RH2NNdaoE4nSZZ1+ZUnQ/ahU+TEJevwdLEGPvw9ct4BVnk2aNMmIOvHgWXQVZZKgR0k7IXVJ0OPvCAl6/H3gugXEamH5vjdKX3PNNevEuXFdn195EnQ/KlV+TIIefwdL0OPvgzBagJmlQYMGVtSXWmopc9ttt4VRTd4yJeh50VTvCQl6/H0rQY+/D1y3YMCAAdbTxRN03vfYYw/X1RQsT4JeEE91npSgx9+vEvT4+8BVC4hfc/XVV9uwwWeeeabZaKONMmYXJkWj8nDhfiTorno1ReVI0OPvLAl6/H3gogWIOStFCaV70kkn2c0rLr744oygM0nK31ElCXpUpBNUjwQ9/s6QoMffBy5a8OCDD5qVV17ZHHbYYYa4LqRZs2YZYrp4k6OEy600LG7QtkrQg5KqonwS9Pg7U4Iefx9U2oInnnjCLhrCTv7FF1/UKY7Y8J6gE8PloYceqnM+rD8k6GGRTXC5EvT4O0eCHn8fVNKCyZMn2+X8eLW899579Yp6+OGHM94uDRs2NKeffrphU5CwkwQ9bMIJLF+CHn+nSNDj74NyW8CSfnYa2njjje3yfr9yML9kT46S3/VmFn71StD9qFT5MQl6/B0sQY+/D8ppwVdffWVH5mxqQRTFfInJUjaR9swuiy++uBk9enS+7M6OS9CdoUxPQRL0+PtKgh5/H5Tagq+//trssMMOpnXr1oZgXIUSW/Sxf+hyyy2XEfWjjz7azJkzp9BlFZ+ToFeMMH0FSNDj7zMJevx9UEoLXn75ZWtmWWSRRQz7pwZJv/zyiznqqKMygr788svbDaaDXFtuHgl6ueRSfJ0EPf7Ok6DH3wf5WsDoGjH+/PPPDZOfp556qllhhRWsMLP6c+jQoXakTT6/xPGZM2caHgK77LJLRtAxv/Tt29dOojLanzt3rt/lFR2ToFeEL50XS9Dj7zcJevx9kK8FP/74o+nTp4/dMo4wuIg4I/NFF13Uvji200471XNV9MpjUwuCdLEtHdcutthimWsph4dDhw4dzCGHHGIWLFjgXebkXYLuBGO6CpGgx99fEvT4+yBfC1gYxKic/T/ZiSj3deihh5rBgwfbUbxfGUyWHnDAAYa9RXFXzL2+X79+5qCDDjI33XST3+UVHZOgV4QvnRdL0OPvNwl6/H1QjS2QoFdjrxa5Jwl6EUARnJagRwC5BquQoKes0+fNm2cnVZ577jnrB8tihT/++KOku5Cgl4QrlMwS9FCw1nyhEvSUfAX+/PNPM3LkSLPvvvua9ddf36y77rqGxQ18ZgJn2rRpge9Egh4YVWgZJeihoa3pgiXoKeh+YkXsueeehtVmLCHGD5ZjL730ktl9993NwgsvbFZZZZXAcZcl6PF3ugQ9/j6oxhZI0BPeq9dee61p06aN9WVlJM4MfLb/60cffWS22more37VVVc1X375ZdE7kqAXRRR6Bgl66IhrsgIJeoK7/frrr7e7oLAgoWfPnubnn3/2be2gQYMy8ZcvueQS3zzZByXo2TTi+SxBj4d7oVqZiyL+yjvvvBP6Ev1C7ajknAS9EnohXjtp0iSz+uqr25F327Ztzbfffpu3tlGjRpnmzZvbvJtvvrnB3l4oSdAL0YnmnAQ9Gs6l1EJ4WwZPLBzCtIn/+AsvvGBmz55t5s+fX/T/qpS6wsorQQ+LbAXlsuR45513tl8uvmDXXXed+euvv/KWyM7i7DBO3nbt2hU1u0jQ86KM7IQEPTLUgSvyBJ3/o+wXAbb4hXzDDTfYcLks60fgiaiYtCRBT1iPMLpmBRmjBL5UTHa+//77BVs5cODATH6WFH/zzTcF80vQC+KJ5KQEPRLMJVWST+hNnscAACAASURBVNCzxb1Zs2Zmxx13NOecc4659957rXkmjJgsJTU8K7MEPQtGEj7y9N9tt90yIwSWH3t7Ffq1D7sfy4jZFYUvXufOnYvGh5Cg+5GM9pgEPVreQWoLIujZ4t60aVPTqVMnc8QRR5irrrrKPP744+bTTz+NdeQuQQ/S0xHmefPNN80SSyyREfRbb721oLnlk08+MdjNvS8afurFkgS9GKHwz2cL+sSJE8OvUDUUJVCqoHv/c977SiutZLp27WpOOOEEc8stt9h46IUGY0UbVEYGCXoZ0MK6BHdE9iL0viBEZXv22WcLVnfffffZgPveNf/5z38K5ufkv//9b1vHgAEDiuZVhnAIEPyJ6H2sLWCzYaX4CTBP5f0fVfrOnFbHjh3N3nvvbc477zyDk0PYm1tAUIIe//co0wLMJ8OGDct8qTbZZBPz4YcfZs77fWCk53352rdvb+Mw++XLPuYJ+qabbmrOOussgw1er+gYwBz2mMkIp0pkvjPPPFN9EPP3kIcsoW69/ycX74TP5aG97LLL2tXdrCXBieHjjz/O/pd09lmC7gxl5QUh6Hi0eF8kZtZ/+OGHvAWzWhT3Ki8/5pliiUlXwgV41+i9rkdDFDwQcm/OI4r6VEewPqZPlllmmdD/N/hlRrz0Cy+8sOD/d7H/Zb/zEnQ/KjEdw+TyyCOPZL5QbF+Vbwadn4dDhgzJeLfss88+eeMzZ98OoxBGhbhinXzyyebss8+2o3RGjXqFz+Dcc8813bt3zywEY3/K/v37qx8S8P0jdjliG8YDkHkxXIpxcsA7hhXeDOBcJwm6a6IVlkdH80/Ol4oJFnzS/dKLL75o1l57bZuPSVGuK5Z4WDRu3NjgehVkNF+sPJ0vnQC+yzyoeajSxzfffHPpheiKUAi4sqETW4n/Mxb7YUdngRI29CgmSCXooXw1yi+U8LiMmvlnb9mypRk/fnyd2C081V999VWDfZ08+MQWs7PTGnYgx8aOTY+RuFI8BJ5++mlDzB36DnNZvl9g8bSutmutxMuFdSNsOUcEVNyImQubPn165EAl6JEjL14hXwRmx/mnJ/DWuHHj7Aj8tddesxvU8qVhkgX3qBkzZhQtkA1picpIefvvv3/emDBFC1KGiggwAmS05tnPb7zxxorK08VuCZQq6E2aNDFrrLGG2XXXXQ3OCfyfso4kO3ie2xYWL02CXpxRLDkQdf75mcDccMMNzR577GFNMFtuuaU5/PDD7cidL2Cx9Pvvv9t9DRmZ8yAI8gAoVqbOl0fgjTfeMBtttJF9sK622mqGB61ScggEEXRcibfZZhtrNiMS6uTJk51PbFZCRIJeCb2Qr8UjhYVGPPlxdcL8gigg0kES9lps5UsuuaQd0WNDV4qPAKsJ+ZXE6+KLLw7cj/G1uLZq9hN0RuFrrrmmOfjggw2RTB966CFrSikWAC8uchL0uMhHUC+jByZOmaS54oorioYEiKBJNVsFk9vdunWzYs4o76233gqFBT/3v/vuO/PUU0+ZBx54wK5YvPTSS81FF12Ud4KdhuAey0T7M888E/iFCfCLL74wQX4phnKzjgsl4BYPW0ScOSrMKHfeeaeZOnWqjbgYpykl6K1K0IOSSlk+NsLwIjbiVVHInz1lt5a65vJLaezYsRlXxRNPPDG0eYzvv//ezpcwSccvM1YssrCFCbtXXnklLztCRpCXa1q1amWWX355+8K9FW8NPKNyX/hsr7jiitYkyD3xazLNCYcD4qHDiQB3v/zyS6xxWcphKUEvh1rCr2HEhI85ow3sfcWiNSb8dlLfPB6mbCFIfzA6D3OpP33/6KOPmquvvtqwNgH3OerFbMDIPV/imuHDh9tfcp6d32svaxc4x4Yr2a8LLrjAbL311tYFk1+BPAjuuOOOgrGH8tWflONh+IZHeW8S9ChpR1AXPwsZDfLPSLAgbH5K8RGgPzB/MLqlT3r06GEYRUeR2HsWkfXqxcsmSMJ7imt4MXJfsGBB3st4WPXr1y+Tf+mll7abQqTBPJH3plJ8QoKe4s7zazr+5vwM5mf2+eef75dFxyIkgBged9xxVvAwXQQJnuaqedjOvdgkt99+eyB3ul9//dVsscUWtr14Rp1xxhlFm4ONmaXs3kOAXwZpH+kWvemEZpCgJ7RjymkW29RtsMEG9h/rkEMOSZ39r5x7Tvo1hDf2/M6Z04jKVfHHH380hx12mP0uYA4h7k+Q9Nlnn2WWv2M/59descQvDrxAPEFnQMF9K0VPQIIePfNQamRERJwI/qmYocf7QCleAkyGsiqXPsGWfdlll0XWIDY6JqIjdW+88cYF96TNbtSYMWMywszmDZRTLDEBf+CBB2auY54gyOrlYuXqfOkEJOilM0vkFfg4MxJjQ2kmuJTiJ4CrIv2BqDLRGHSU7KLlxNX3Igcee+yxBlNKkIRHFO3F3LLXXnsFcklk0j17kxV+JfILQSl6AhL06Jk7r/HBBx+0Ab2wl7IASSkZBPD9RhxxIWTVb5TpyiuvzIyYR40aFcjzhOBRrEqmzfyiYN/MIOmuu+7KRP3kWq7TpGgQcu7zSNDdM420RFaOejHREY2gq0gjbWQNVkZMDyLtIXB4GzFxGFbCtIMdm3cSO+N49nO8a/iOBEksFMIXnTYzumeUXyzhr80kKNfwwkwjc0sxauGdl6CHxzb0konUd+ihh9p/JFYhYstUSgYB/LUJkYsZjE2Ew0iYOlhvQIAoJjCJ1UOUP+zeni856xCCTsSyuYo3gYvferF5GMw4xx9/vDXPIOasSn7++eczD5Yw7lllFiYgQS/MJ7FnGYkTD4R/QP6R075KL7Gg8zRs9uzZ5u233/Y9S5wPRqqIHBsbFFqh6VtAkYOMxInRQ4AvPEoI6zBhwgRz0kkn2ZWeLPbx/M/ZbpAVj0ESETmxnfOdYtRdyG+d+QBs7DywuE/COOMyK1NLENLh5ZGgh8c2tJL5h2bBEKMyflKPHj3aJDVYUGgQYi6YuOYsuvFLd999txVWhG777bf3y1L2MeLlDx482MYbQbQxi3jCi3AjrNTLC9s9G2gE+W5gP2dgwHX8sujbt69dWYobo/fCFZFY/MTrx5MF4Se2O5sgF1qFWvbN6sKSCUjQS0YW/wX8Y3k/qdlcuNBKvvhbW50tQCgRvly3Pkaou+22mx3psriLAFmuEr/KMKkgpJTNKN2zm1MHn5kg97ZRIx4LJpAg6bnnnrMRORF0RukMFvDQadOmjX3xmQcIZfOiDfw9YsSIIMUrT0QEJOgRgXZVDT/1WTTEP95+++0X2L/YVf0q578EmICmD3IXcE2cODFj7mBzEm/0XCk3HhTEgGnatGmmXr+Aa5hC2PyEtjGvkm8Lw9z2EBrWi/vCFoiYibJfL7/8sv2biVPagUkG4eehhh09qJ0+t1797ZaABN0tz1BL46cz0eD4Z1133XVtzIxQK1TheQl4O0pheiDkLInFXcccc4wVOfqI5fauEhOQO+20k+174qUQBCs3IfpPPvmktdtTP5tPBw1t69nPuS6fKSm7Pkw0bLpCfl6sFC02iZp9vT6HQ0CCHg7XUEplGTbxQPiHJk6zUjwEEE5vFSaTgozSGYkzisU7BIHr3Lmz0yBcxLb3xJNdq/z2q+SB7/mfMxkbdIs7XB69dnM/eOgESS+88IL9PtIuRupcpxguQciFl0eCHh5bpyUzGYV7Gv88QQImOa1chdUhkC2A9Aej9Pvuu88QThZh49hNN91U5xr+QOyY/yDmTrbtu17GnANc563gpOw+ffrk5Pjvn8ylMLomD9+VZ5991jdf7kF2ssJmznVMsufz3sm9DjOL9yDgWpb/w0YpPgIS9PjYB66Zn7ddunSx/3DE1dZO8YHRhZIROzUijojxYoKQpe/ETOFvRI65DhImD3YCuuaaa+yagd69ewcWTK/xPABatmxpy2bkzV6WfgkvF89dcYcddjBfffWVX7Z6x3B/pVza3r59+8Cuh9jn27VrZ6/jWnzeg9ZZrxE64ISABN0JxnALwYWMCSjcyvx+aodbu0rPJYBHCF4miJj3wlThhart2bOnYZEO4s0m34g/+fEZZxl+EDfC7DqnTJmSqWeVVVYxuEz6pWyzTL5RfO51jOpZnMZDiXsJuggKsxMTpN4DhGv5daDFbbmEo/1bgh4t75JrY+cZtgVjBIWQKMVPAL9/TwA9Qc9+xxOFfSk98wvnMGVg3y4n4Z7olU+s8hkzZvgWM2jQIJuPuthhiIRt/4MPPjDsl+mXOOe5wFIHcVmCJModOXJkpl1ce+GFF+atJ0iZylM5AQl65QxDK4Gdbjy7Of7HpdhdQ2uUCrYLezyBDfKOOyBL9MuNs+OF4OUhsv/++/uKJqYdbw9ZzCBMWJKIvLnyyivnXa2Knzz+6twHZp2gK45zFzFRR1Cbvb5C4RGQoIfHtqKSsUV6bmq4hMl7oCKcTi8+/PDD64xMC4k6phh8tpkHKTfhI04djPiPPvpo32JwGfTs7Nttt11mfQI71+NXni9gFvZzbyEScwAIdbGEyYg5Ae++aRcL3PL9CvDKw7wDB+rwBieM9PkbE45S5QQk6JUzdF4Ck57YzfmHYXFK0MUhzhuiAn0J4DboiVmhd+Y9yMty/UrS448/nhF0YpvnJoQU/3fawgOESIsk7NnEdWHlqt8ipOxdjbj2X//6V27R9f6mLlbJevfNrw8WFhV7EDBAYbNpXG7Zro5fDnBhZSveMcWur9cQHfAlIEH3xRLfQUY/+A8zicZyaxaKKCWLAEGxPEEr9M6INzc0QDl3gseMt2cn4kx4XC8hhAMHDsysIGViFuEksWqV0fkNN9zgOxFLSF8mbb17KBQuFyEnDC+i73nEEGoXU5Ln0eO1KfedNp577rnWdx/xZ1EWi5JoNwuaiBqp5IaABN0NR2elMPFJ/Gx+xuIp4f00dVaBCqqIAEGo8FbxRDDfO6FkXdqU2Vya7wRxyvFxpx1EN8QEg6sh4ugF18JnHW8oTHX8QiC4FgkbPl42mFkw4xAtMbv9J5xwgj3O5tLZL4KB8cugQ4cONj+DDdw0WUgUxJSEv/rQoUNte2kHZhYmUNnZSAOWir6O9S6WoNdDEt8B/vH4icw/GSYX+ZvH1xf5as511csWRO8zo2JGxy4TcyiILD7uCCt2eXzNGemOGzfOPvgxX3COAQHeMJjrJk2alLFPI77My/ALg4lTHgCIKrsU4enCtRzPffHAYHKe8hhh80DBFz9oQsB5eYmwBTw88M9XcktAgu6WZ9mlEavDWw3IpNZHH31Udlm6MDwCeIXgRuqJd+47LovEcMkWMFetYVKRFcO33HKLHR0j5NkLefg1R0AtBBe3RT5n+7zzmclRxLjU17vvvmvdJYPuTep3z7SfWETEaA/qTeNXjo7lJyBBz88m0jPsP8lP6lJCnkbaQFVmCbBK04tKmCvmeItgyqhE9IJg5mFRyOsJ4c4W8iBlhp2HX5uYhXDBzJ7k//nnn8t25wy7zWksX4KegF5jswpso0w2+cUASUATE9kEXN1YZBNl/BDC5norQrMFHR9xohvKTFb/q4I3DZOimIyybe543hAugNAGSm4ISNDdcCy7FEYrq6++ul15yFJxpdIIsPgKWzLsxo8fb8UhzNEpy/pxDcwWcz4Tm54Nk5XqEsA1ETHHBo+vOmYgvGIw/bBIqlevXnUv0F8VEZCgV4Svsov5sjO5hSAQjtXPV7iyGmrjauyynhmEzR3w7sAr5Msvv7TBsTBPuFi4QhnMb+Bf7gk6n5mADBqhsDZ65L93iWmIMAm4JvLgPe644wyujky+4o/OJKt+0bj9RkjQ3fIMXBpfdmyKjPbwStAkaGB0vhlxq/NWPHpiy5wEo3d+6rMUnhE09u1yXUF5AGeHi6UeNhohKJZSfQJMghJfxtv4gr+ZrOXXVD7f+Pql6EgpBCTopdBymJeRS4sWLexGvvfee6/DkmuzKOy0uX7VnrDzTrAsRtI8RMeMGWMX/JQ6OsS3m2iHXrm4JxZajFObPaG7jpOABD0G+iwIwf8XYcCuqOSGAL9ygizLZ2EM/I888ki76TKLuTDPFEuYDbxAVkxiexENi12n8yIQFQEJelSk/1cPwuHtKnPQQQfZzXVZwcfPUb0qY8BkKKszg6zk9EbZvLPQpnv37nb0zs5D7CpEX+Sm2267zfqgY6+/4oorck/rbxGInYAEPcIuIMTpOeecY+3mjRo1sqv2sCfq5Y4BGzTgNZQt2EE/M8GJGWWTTTaxfUJMnewVkSyZxy5PH4btax7h11JVVREBCXqEnXn//fdbWy5ijs85E6J6hcMgqIjny0e/0EfstYk3Bl4zRDE86aSTigajivArpapEoA4BCXodHOH98dZbb1lvFn6uYzfHfotgMFmnl1sG2MizXQvziXah41y/3nrrWVc74rJ8+umnZuzYsfI1D+9fRCU7ICBBdwCxWBH4l++6667WDMBiClY24pUxbdo0G5uD+Bx6uWGADb1r164lm1wQcGK0dOzY0drSmQCdOXNmxn8dV0ds9C782Yt9X3ReBMolIEEvl1wJ1/EzndEgIVXz7RxTQnHKmocAYkt42EIjb+8cJhVMX+y/iTsj9vGXX345T8k6LALpICBBD7mfmFgjzgeTbYQ3VQqPADFxMLd4op37zsIjViiyDJ3VpLgdeotewmuVShaB6AhI0ENkPWXKFMNSdEaCeEYohUcAkxVxu3NFHK+UNm3a2CX7xJhnV3tcR2U6Ca8vVHJ8BCToIbFnVSHeEQgMAYiKbaAbUjNqoliW9LODjifmxAthST7+/uyMw6RmdtzwmoCim6xJAhL0ELqdJeX4liMwrFwMsgoxhGbURJFsxXbIIYfYMArYwhmF33rrrdYero2Ha+IroJvMIiBBz4Lh6iPBoHBPxNyC2UUpPAIE3RoyZIh55JFHbIAzLfgJj7VKTj4BCbrjPkJY2rZtaydCWSoexlZkjpuc6uKIgChzVqq7UI13SECC7hAm+y56mzyffvrphu21lERABEQgKgISdEekWSjUp08fazffbbfdzGeffeaoZBUjAiIgAsEISNCDcSqYix1xbr75ZivmK6+8snnmmWcK5tdJERABEQiDgAS9Qqr4M0+aNMk0bdrULlphIZGSCIiACMRBQIJeIXWW8m+44YZ2dM4Sf3lZVAhUl4uACJRNQIJeNjpjN7hlt3f8zXfccUctXqmApS4VARGonIAEvQKGAwYMsGJObBCWntdimjNnjvUBxxd88ODBdmn9rFmzLApcNtmNSUkERCAaAhL0MjkTE4Rwq8Q0Z/ODWkyEqt1jjz2s3/22225runXrZjdR7tGjhw0N3L9/f+v58/bbb9ciHt2zCEROQIJeBnJWJ6611lp2dE6sEOJk11o6//zzDR49rIgdNmyY3fhh9uzZ5sorr7S7/LRr185GPiQ4FseUREAEwicgQS+RMeFWd9ppJyvmBx54YM0tHmLz5H79+tlfJvw6yfXqYTHVAQccYFfKMrdAONvHHnusRMrKLgIiUA4BCXoJ1HBR/Pe//23FnJ3iP//88xKuro6sl1xyid0UArE+/vjjfW9q6NChmTxs2KzgZL6YdFAEnBOQoAdEipgTxa958+b2RUjWWoup/cQTT5hVV13VPtDYPJl9Nv0SMWzghOjvvvvufll0TAREIAQCNS/oiPJvv/1mWO1ZKGE379ChgxWpq6++uubs5phaDj30UHv/CPUpp5ySFxcmGXYHIt+IESPy5tMJERABtwRqXtCx+d5yyy3m9ttvzxu1D5MB8VkQqMMPP9x4bnluuyLZpfFAW3PNNTOC/txzz/k2mPjkeLvAarHFFjPycPHFpIMiEAqBmhf0jz/+2OCRwWbBgwYNMl9//XUd0Kz8PO2006xAbbbZZjUpUHjx4M3ToEEDy4E47/kiSSL88ETQN9poI4OfupIIiEA0BGpa0P/++28zevRoKz4IEILFtmXZm1IwemeHeGKcT5gwIZpeSVgtbPGGLRxGvPiVgpnKL11zzTWmSZMmNh+hEGptnsGPiY6JQFQEalrQGT3uv//+GaHyBIv9KMeOHWuefvppu8EwpoPLL7+8ZjereO+99+xo2+Nz7bXX+s4h8IA85phjMjwfffTRqL7HqkcERMAYU9OCPm3atMxo0hMr771Vq1bWZowfNSPSWl7C/tJLL9kHG2zgwQpRv5E35qttttnGCjoPQW+ugVjxRx99tBk3bpz+6URABEIkULOCjiCdccYZmdGkJ+TZ75hg2rRpYx5++OEQuyD5RfNLBTdF2Cy//PJmxowZvo3GlXOllVay+bp27ZqJPPnAAw/YFaWYr5REQATCI1Czgo43hrd8P1vEcz8j6h07drQxz8PrhmSX/Prrr2cmOtdee23fhUK4NWY/IM8991z7q4YH51FHHWUfCG+++Wayb1StE4GUE6hZQR8zZkzB0XmusC+zzDIG23Etxjvn4cdkMUxat25tPvnkkzpfe8xRo0aNsht8kKdhw4bmzjvvNNjUcfnEf3/XXXf1NdPUKUh/iIAIVESgZgV9++23L0nQPYFntImgERq2lhJ++kSXhMNNN91kF2Ih2HPnzjXXX3+9NcUQrAsbO15B2Ms5P3z4cLubE5PMSiIgAuESqElBZ7GL51rnCXUp74w289mRw+2u+ErHI4jVoY0aNTLEZyFkMCGEiefSvn17c9ZZZ5knn3zS7LDDDlb0e/XqZVeJrrLKKqZ3797xNVw1i0ANEahJQUeYShHw7LyYXo477riaDMz1ww8/mKuuusrsvPPOZquttrLvuH2OHz8+Y0558cUXzRFHHGHP4/GCLzphdZVEQATCJxCZoLPasJKXKxSYCLwAU9lCHeQzk6h4ajABWMsJhu+88459qGFWyU3ExcEslS94V25+/S0CIuCGQCSCjv21b9++dV78VGeky0IUfJSzXxzjnHcNf998882+i1lKxcDkHT7SQQQ8Ow8x0Ilf4idgpbZB+UVABEQgDAKhC/r3339vfZOJvsfLiweCWLLbDUvq8YIg8FP2C39ndrvxovYRT6VYRMRigPDG2GuvvTKbL2QLdr7PiP+pp55qZs6cWax4nRcBERCBWAmELuhMnnmijGius8465oorrjAEcXrrrbfMRx99ZH+a8/Oc12effWY3HV5xxRUzo2hstrmucuVQw76bXW4+EfeOs4kF7o21bmIph7WuEQERiJ5A6IJ+yCGH2BExI90TTzzR4NNcKBHtcM8998yI+QYbbGCmTp1a6JLA5xjl46XhCXah96233to+cAIXrowiIAIiEDOBUAWd0TYjcoSTVYTFEiFZcXfzhJZl5OyS4yKxwAXPDK/sfO+YgbDv1+ICIhecVYYIiEB8BEIVdFYLspEwQlpsIQ5mDSZBPaHFNML1rhITsy1atMiU79WT/Y4/NZOmfoGnXLVD5YiACIhAWARCFXQ8V5jYfOihhwq2H7EfPHhwZsKUFYlDhgwp+hAoWGjWSTxTiJiYLd7Zn7Hx48WCjV1JBERABNJKIDRBx1a+4YYbmvXXX9/89NNPefkgtsOGDbNLxhFZbNz9+/d36h74yiuv2ABb2SLufWbUzkKjzz//PG8bdUIEREAE0kAgNEFnGTgmDHawKeS7zQ7xxB5HYHFpZFQ/b948Z+wwnzDa95sMxb5/6623Ovsl4KzRKkgEREAEyiAQmqDjrfLII48U9GrhPKLvjZaJ6Md2Zy4T7cjePs2ra7/99jOTJ092WZXKEgEREIFYCYQm6MXuCns1LomewHbp0qXeBs3Fyghynm3QWrZsmakHL5ZLL71UC4WCwFMeERCBVBGIRdDZo3K77bbLiCx2dhYYuU6//PKLXeXpPTQwsRDWNd8Gx67rV3kiIAIiECWByAWdJfQHH3xwRsxZjfn888+H4ipIiFvPD3633XYz7JhTyJ4fJXjVJQIiIAKuCUQq6Hi7DBgwICPmeJjg0hiG3zfCfd9999nNFvCaYaNiJREQARGoZgKRCfr8+fPNBRdckBFzfM1vvPHGUMScDuPhMXDgQDNy5Mhq7j/dmwiIgAhkCEQm6Nddd13G17xp06bm7LPPzuueSFRERtSVjNyxn2OrVxIBERCBWiEQiaCPHj3aNGvWzI7OWZVJrBR2v/FLiDm+6cR+IbaLkgiIgAiIQDACoQs625Mtt9xyVszZDX7vvfc2s2bNytu6L774wq7qJGSuBD0vJp0QAREQgXoEQhX0p59+us6Se3zNp0+fXq8R2QdYYcpoHl9xJREQAREQgeAEQhN0YphvuummmYBbnTp1Mu+//37BlmEzP+yww8yyyy5riL+iJAIiIAIiEJxAKIKO//cuu+yS8WhhOzl8wIulV1991Ya43WyzzYpl1XkREAEREIEcAs4FnT1E+/TpkxmZYz5h+X2QhH194YUXDrQZRpDylEcEREAEaomAU0FnEhPvFG+pfZMmTazHSjH3Q86zzyjXtW7d2u43WkudoHsVAREQARcEnAk68VGIa+6JOeFqCVv7559/5m3nH3/8YfBqueiiizIbSbOXJ8eVREAEREAESiPgRNARbbaLa968eUbQ2QEIj5Vp06aZ119/PfPCTo73y4QJE+yofIsttshcQzz0c889t7Q7UG4REAEREAFLwImgf/jhh4aJT290zjsha1dZZRXTtm3bOq8VVljBsFI0O6/3eZllljFvvPGGukYEREAERKAMAk4EndC3/fr1M8cee6w57rjj7Iudh5gc9XsdddRRdmei7PzHHHOMITyAzC1l9KIuEQEREAFjjBNBZ1ITGzoBuCp5sVm0kgiIgAiIQHkEnAh6eVXrKhEQAREQAZcEJOguaaosERABEYiRgAQ9RviqWgREQARcEpCgu6SpskRABEQgRgIS9Bjhq2oREAERcElAgu6SpsoSAREQgRgJSNBjhK+qRUAERMAlAQm6S5oqSwRE8sT1pQAAIABJREFUQARiJCBBjxG+qhYBERABlwQk6C5pqiwREAERiJGABD1G+KpaBERABFwSkKC7pKmyREAERCBGAhL0GOGrahEQARFwSUCC7pKmyhIBERCBGAlI0GOEr6pFQAREwCUBCbpLmipLBERABGIkIEGPEb6qFgEREAGXBCToLmmqLBEQARGIkYAEPUb4qloEREAEXBKQoLukqbJEQAREIEYCEvQY4atqERABEXBJQILukqbKEgEREIEYCUjQY4SvqkVABETAJQEJukuaKksEREAEYiQgQY8RvqoWAREQAZcEJOguaaosERABEYiRgAQ9RviqWgREQARcEpCgu6SpskRABEQgRgIS9Bjhq2oREAERcElAgu6SpsoSAREQgRgJSNBjhK+qRUAERMAlAQm6S5oqSwREQARiJCBBjxG+qhYBERABlwQk6C5pqiwREAERiJGABD1G+KpaBERABFwSkKC7pKmyREAERCBGAhL0GOGrahEQARFwSUCC7pKmyhIBERCBGAlI0GOEr6pFQAREwCUBCbpLmipLBERABGIkIEGPEb6qFgEREAGXBCToLmmqLBEQARGIkYAEPUb4qloEREAEXBKQoLukqbJEQAREIEYCEvQY4atqERABEXBJQILukqbKEgEREIEYCUjQY4SvqkVABETAJQEJukuaKksEREAEYiQgQY8RvqoWAREQAZcEJOguaaosERABEYiRgAQ9RviqWgREQARcEpCgu6SpskRABEQgRgIS9Bjhq2oREAERcElAgu6SpsoSAREQgRgJSNBjhK+qRUAERMAlAQm6S5oqSwREQARiJCBBjxG+qhYBERABlwQk6C5pqiwREAERiJGABD1G+KpaBERABFwSkKC7pKmyREAERCBGAhL0GOGrahEQARFwSUCC7pKmyhIBERCBGAlI0GOEr6pFQAREwCUBCbpLmipLBERABGIkIEGPEb6qFgEREAGXBCToLmmqLBEQARGIkYAEPUb4qloEREAEXBKQoLukqbJEQAREIEYCEvQY4atqERABEXBJQILukqbKEgEREIEYCUjQY4SvqkVABETAJQEJukuaKksEREAEYiQgQY8RvqoWAREQAZcEJOguaaosERABEYiRgAQ9RviqWgREQARcEpCgu6SpskRABEQgRgIS9Bjhq2oREAERcElAgu6SpsoSAREQgRgJSNBjhK+qRUAERMAlAQm6S5oqSwREQARiJCBBjxG+qhYBERABlwQk6C5pqiwREAERiJGABD1G+KpaBERABFwSkKC7pKmyREAERCBGAhL0GOGrahEQARFwSUCC7pKmyhIBERCBGAlI0GOEr6pFQAREwCUBCbpLmipLBERABGIkIEGPEb6qFgEREAGXBCToLmmqLBEQARGIkYAEPUb4qloEREAEXBKQoLukqbJEQAREIEYCEvQY4atqERABEXBJQILukqbKEgEREIEYCUjQY4SvqkVABETAJQEJukuaKksEREAEYiQgQY8RvqoWAREQAZcEJOguaaosERABEYiRgAQ9RviqWgREQARcEpCgu6SpskRABEQgRgIS9Bjhq2oREAERcElAgu6SpsoSAREQgRgJSNBjhK+qRUAERMAlAQm6S5oqSwREQARiJCBBjxG+qhYBERABlwQk6C5pqiwREAERiJGABD1G+KpaBERABFwSkKC7pKmyREAERCBGAhL0GOGrahEQARFwSUCC7pKmyhIBERCBGAlI0GOEr6pFQAREwCUBCbpLmipLBERABGIkIEGPEb6qFgEREAGXBCToLmmqLBEQARGIkYAEPUb4qloEREAEXBKQoLukqbJEQAREIEYCEvQY4atqERABEXBJQILukqbKEgEREIEYCUjQY4SvqkVABETAJQEJukuaKksEREAEYiQgQY8RvqoWAREQAZcEJOguaaosERABEYiRgAQ9RviqWgREQARcEpCgu6SpskRABEQgRgIS9Bjhq2oREAERcElAgu6SpsoSAREQgRgJSNCLwP/zzz/N/PnzzW+//WYWLFhQ58UxzvH666+/CpaUrxzK4PXPP/8UvF4nRUAERKAYAQl6AUKI8Lhx48xBBx1kjjrqKNOvX786r+OPP94cfPDB5thjjzVvvfVW3pJ4ENxxxx1mn332Mcccc4w58cQTbTl9+/Y1Rx99tP08e/bsvNfrhAiIgAgEISBBL0Dp119/NUOHDjVbbbWV6dSpk2nQoIFZaKGFMq+WLVuarbfe2vTq1cu8+eabeUuaO3euOf/8880KK6yQuZZy+HvjjTc2ffr0Md9//33e63VCBERABIIQkKAXofT333+b33//3fzwww+mR48eZpFFFrGivPDCC5szzzzTcL6YucWr4rbbbjNNmzY1Sy+9tDn55JPNCy+8YH7++WdbhpdH7yIgAiJQLgEJegnkJk2aZMWY0XXDhg3N4YcfHvjqefPmWfNKmzZtzE033WQfEoEvVkYREAERCEBAgh4AkpeF0fjaa6+dMZusuuqq5ttvv/VO533/448/zMUXX2yWW245M3z48MAj+rwF6oQIiIAI+BCQoPtAKXSICU3MLYzSMZ/cfvvthbJb75XRo0fbkf1ZZ51lPVoKXqCTIiACIlAmAQl6ieBefPFF06hRIyvomF3wcimUJk+ebJZZZhlz2GGHWXt5obw6JwIiIAKVEJCgl0iPCdBss8uaa65pPv/8c99SZsyYYVZaaSWz7bbbmpkzZ/rm0UEREAERcEVAgl4GydNPPz1jR8djZeTIkfVKQcA7d+5s2rdvb6ZPn17vvA6IgAiIgGsCEvQyiE6dOtV6uXg+6UcccUSdUubMmWO6d+9uWrVqZZ5//vk65/SHCIiACIRFQIJeBln80jfaaKPMKJ3PH330kS2JxUisKm3evLm55557yihdl4iACIhAeQQk6OVxM4MHD84IerNmzezSfoo644wzDH/jnqgkAiIgAlESkKCXSfuNN97IeLtgeiGuy+WXX27dEy+44AJDHBglERABEYiSgAS9TNpEWCSOi2dHx16OXzp+6tjQlURABEQgagIS9DKJs2r0qquuygg6wn7AAQeYr776qswSK7/sp59+qrwQlSACIpBaAhL0MruO+OUPPfRQRtBxT2TRUVyJB8nVV18dV/WqVwREIAEEJOhldgILjM4+++yMoO+7775m1qxZZZZW+WUjRowwXbt2rbwglSACIpBaAhL0MruOTSs233zzjKCfc845ZZbk5rIdd9zRtGvXLtaHips7USkiIALlEpCgl0kOv/Mll1zSCjqrRe++++4yS6r8MmznxJchZgw7LCmJgAjUJgEJepn9PmbMmMzofP311zdvv/12mSVVftn9999v27LYYouZ/v37V16gShABEUglAQl6md3Wu3fvjKDvtddehpjncSUiOXruk926dTNspqEkAiJQewQk6GX0OT7oHTp0yIyKiXMeVyIMwSqrrJIRdLxtpkyZEldzVK8IiECMBCToZcDHvOJtcrH88subiRMnllGKm0vYl7Rx48YZQSfswPXXX++mcJUiAiKQKgIS9ADdxSj41VdfNRMmTLC+5zvttFNGQFu2bGkuvfRS8+ijj5pnn33WEJwrykTsmAYNGmTag+nl6KOPjtUEFOX9qy4REIH/JyBB/38WeT/dd999hpE4k46MhhdddFH7mb8ZqfPOsRYtWpiXXnopbzlhnNhiiy3qiDmCvuWWW5qPP/44jOpUpgiIQIIJSNADdM7s2bPtKtCnnnrK8GJF6HvvvWfeeecdOyrn2BNPPGGmTZtm8E+PKtGG1q1b1xN0jo0fPz6qZqgeERCBhBCQoCekI8ppBqtDF1988XqCjgnm4osvNsSbURIBEagdAhL0FPd1jx49MpOzntui937QQQcZflkoiYAI1A4BCXpK+/qbb74xnTp1qjc69wSdzatff/31lN6dmi0CIlAOAQl6OdQScA2RHonB7gl47nvDhg3N2LFjE9BSNUEERCAqAhL0qEg7rmfgwIF1dkzKFXT+PvXUUyN3o3R8mypOBESgBAIS9BJgJSXrL7/8Ynbddde8o3NP3HFf/PLLL5PSbLVDBEQgZAIS9JABh1E8S/uxkXvCne99kUUWMVOnTg2jCSpTBEQggQQk6AnslGJNwl2RJf75hDz7+E033aQNq4sB1XkRqBICEvSUdSS+5ccff3wgMUfY99tvP0VfTFkfq7kiUC4BCXq55GK67pNPPjFdunQJLOhLLbWUdjGKqa9UrQhETUCCHjXxCusjsmMhd8Vsc4v3mbAESiIgAtVPQIKesj6+8sorA4/OPUHv27dvyu5SzRUBESiHgAS9HGoxXcNSfpb7e0Id9H211VZTON2Y+kzVikCUBCToUdKusK53333XIM5BhTw7H5EglURABKqbgAQ9Rf3rbQadLdRBP5933nkpulM1VQREoBwCEvRyqMVwDZtQ33vvvaZ79+5m3333rfPCNbFJkyY2lO6OO+5o9t9//zrn9957b3P++efH0GpVKQIiECUBCXqUtCus659//rExzvFFz35R7EorrWR3VXrttddsLdnnvc8VVq/LRUAEEk5Agp7wDgraPE/QFTI3KDHlE4HqIyBBr5I+laBXSUfqNkSgAgIS9ArgJelSCXqSekNtEYF4CEjQ4+HuvFYJunOkKlAEUkdAgp66LvNvsATdn4uOikAtEZCgV0lvS9CrpCN1GyJQAQEJegXwknSpBD1JvaG2iEA8BCTo8XB3XqsE3TlSFSgCqSMgQU9dl/k3WILuz0VHRaCWCEjQq6S3JehV0pG6DRGogIAEvQJ4SbpUgp6k3lBbRCAeAhL0eLg7r1WC7hypChSB1BGQoKeuy/wbLEH356KjIlBLBCToVdLbEvQq6UjdhghUQECCXgG8JF0qQU9Sb6gtIhAPAQl6PNyd1ypBd45UBYpA6ghI0FPXZf4NlqD7c9FREaglAhL0KultCXqVdKRuQwQqICBBrwBeki6VoCepN9QWEYiHgAQ9Hu7Oa5WgO0eqAkUgdQQk6KnrMv8GS9D9ueioCNQSAQl6lfS2BL1KOlK3IQIVEJCgVwAvSZdK0JPUG2qLCMRDQIIeD3fntUrQnSNVgSKQOgIS9NR1mX+DJej+XHRUBGqJgAS9Snpbgl4lHanbEIEKCEjQK4CXpEsl6EnqDbVFBOIhIEGPh7vzWiXozpGqQBFIHQEJeuq6zL/BEnR/LjoqArVEQIJeJb0tQa+SjtRtiEAFBCToFcBL0qUS9CT1htoiAvEQkKDHw915rRJ050hVoAikjoAEPXVd5t9gCbo/Fx0VgVoiIEGvkt6WoFdJR+o2RKACAhL0CuAl6VIJepJ6Q20RgXgISNDj4e681rQK+oIFC8xbb71lbrrpJnPhhReaUaNGmZkzZ5p//vnH/Pnnn/bFZyUREIHiBCToxRmlIkfaBP2vv/4y77zzjjnooIPMUkstZdZZZx3TpUsXs/TSS5uNNtrIvPLKK6Znz55ml112MW+//XYq+kCNFIG4CUjQ4+4BR/WnSdD//vtvc++995rWrVubxRdf3AwePNj8+uuvlsQTTzxhWrZsaYV9oYUWMosuuqgZPny4I0oqRgSqm4AEvUr6N02Cftttt5lGjRqZhg0bmosuuqheD5xwwgkGMefVqlUrM2XKlHp5dEAERKA+AQl6fSapPJIWQZ84caJp0aKFFesddtjB2spzgTNKb9y4sc2z/vrrm99++y03i/4WARHwISBB94GSxkNpEPRZs2aZzTff3Ao1o/PHHnvMF/WYMWMyI/g+ffr45tFBERCB+gQk6PWZpPJIGgT9sssuM02aNLGC3r59e8PEqF/q3bu3WXjhha39/K677vLLomMiIAI+BCToPlDSeCjpgj537lyz9dZbWzHHNn7iiSf6YkbkMbOQh8nRL774wjefDoqACNQnIEGvzySVR5Iu6I8++qhp06ZNRtCff/55X864K+L9gqBjnlESAREITkCCHpxVonMmXdAvvfRS66KIUC+33HLmxx9/9OV59dVXmyWWWMIK+tlnn+2bRwdFQAT8CUjQ/bmk7mjSBb1v376Z0Xm3bt0Mvuh+6YADDjANGjSweSdPnmyz4OXy5Zdfmnnz5vldomMiIAL/IyBBr5KvQtIFvVevXhlBP/fcc32pI9qdO3e2+bCfY09n2f/48ePNmmuuaSZMmOB7nQ6KgAj8l4AEvUq+CUkX9H79+mUEfeTIkb7Ux44da80xmGX23Xdfm4fR+b///W+z2mqrKQSALzUdFIH/JyBB/38Wqf6UdEFn+f6SSy5pRX3EiBH1WL/33ntm2223zYj+tddea/N89913ZsMNNzSYYv7444961+mACIjA/xOQoP8/i1R/Srqgf/LJJ6ZTp05WsA899NA6rAm+xapRgnThf84IHa8Y0rhx4+zx0aNH17lGf4iACNQnIEGvzySVR5Iu6EBlkVCzZs3sKlBG6YTNHTp0qLWP77bbbua+++4zHTt2tILOJOqkSZPMeuutZ3r06KHl/6n8VqrRUROQoEdNPKT60iDoTHASp2Wbbbaxos6InEVE1113nfn+++8tmVdffdWeZ6SOiYYQuoQMUBIBEShOQIJenFEqcqRB0AGJqOO98vvvv5uffvrJfs52YfTOE06XV/a5VHSEGikCMRKQoMcI32XVaRF0l/dcqCxG/IzseXDooVCIlM5VEwEJepX0pgS9bkdiumG3oyOPPNLcc8895v333zdz5syRp0xdTPqryghI0KukQyXo9TuSXZGaNm1qJ1lXWGEFs/feexvcIZ977jkb9Gv+/Pn1L9IREUgxAQl6ijsvu+kS9Gwa///5mmuusTsj4QrpvZZZZhnrJjlw4EC7FR7eNt4WeP9/pT6JQPoISNDT12e+LZag+2Kxk7ADBgzIiLkn6t478dk33nhjQ2gCAoO98MILRiN3f5Y6mnwCEvTk91GgFnqCPm3atED5aynTzz//bFeaeiKe732xxRYz7dq1s6P3U045xcaO4VolEUgLAQl6WnqqSDs9QX/zzTdtzgULFhi9/ssATxdWo26wwQZ5R+q5Ir/IIouYZZdd1qyzzjp29H7nnXeamTNnFukFnRaBeAlI0OPl76x2BJ2NIa644gqzxRZbmA4dOpi11lpLr/8xIFojtvNc4Q7yN4uciNEOX1a0Xn/99ebDDz80f/75p7P+U0Ei4IKABN0FxQSUgaAjWPvtt19ZohVE2JTnvxOrCPy6665rbe7ffPONtdMn4CugJoiAkaBXyZfAM7kQmpYJvu7du5s99thDr/8x2HXXXc3qq69e8sOOzTYWXXRRu7k15hfCAD/++OPWnPXII4/Y+DOE+FUSgSQQkKAnoRcctMETdM+G7qDIqioCLqUIOv7rK664oo0rM2jQIMNep7nhe9ki7+CDD1asmar6pqT7ZiTo6e6/TOs9QX/99dczx/ThvwQwi2y55ZZFR+etWrWyIX4xW+G/zurSfIk4NORr0aKFjRqZL5+Oi0CUBCToUdIOsS4Juj9cFgwRfz2f/X/llVc2O++8s90V6e677zaffvqpf0E5RwktgAmGcu+44w4bZCwni/4UgcgJSNAjRx5OhRJ0f65nnHFGHTHHHo73D2F5GYU/+eSThhF8qen222+3IYARdOYstNK0VILKHwYBCXoYVGMoU4JeHzqCjeA2btzYrgZlxSiBuljqP3v27PoXBDyCeJ988smZBwXsy3koBKxO2UQgMAEJemBUyc4oQa/bPy+++KIdOV9++eU2GNdXX31l5s2b58TF8OOPPzabb755RtB5aLBxh5IIxE1Agh53DziqX4JeFySTlizbxzOFTTNcpqefftq6MiLk3osRu+t6XLZZZdUGAQl6lfSzBD2ajuQBMWTIkIyQe4KOSyShFpREIE4CEvQ46TusW4LuEGaBotgJaaeddqon6Ag78WKURCBOAhL0OOk7rFuC7hBmgaI++OADO8nqjcyz388555wCV+qUCIRPQIIePuNIapCgh4+Zza3/85//+I7OEfaOHTtW3IjvvvvOeuGwMhWXygcffNA89thj5ocffvAtmwBhn332mf118O6775rc1zvvvGNyXzyU8LdnSz6l6iIgQa+S/pSgh9+RhOHdd9998wp6w4YNzSeffFJ2Q5hUPf74462fPCtQW7ZsaYjR3rlzZ5MvpMP06dNtBEiiSeJfv95665n111/frnjlb4KI5b7IQ0RO/Odx7UTglaqDgAS9OvrRSNDD70hGzwhttpkl9zMTpuUmfgHcfPPNZvDgwaZPnz6ZegiyRt1+6euvvzZXXnmlvYaHDQ8Ar029e/c2F198sT1Hmbwuuugig2lo++23t/lYaNWlSxf7a8CvfB1LFwEJerr6K29rJeh50Tg7MW7cuIxYeqKZ+77NNttUXB8j9SlTpmTqOu200wqW6blLYg7yHjhsij1r1ix7HedzX99++60NLOa1f9NNN7WmmYIV6WTiCUjQE99FwRooQQ/GqZJcjHg9Acz3zi5HM2bMqKQae+2wYcNsXcS4HzVqVKDyzjzzTEO4X9q21157Fb3m888/z4zoGdkTJkEp3QQk6Onuv0zrJegZFKF8YJVpmzZtigo6YQZGjBhRcRv23HNPWxcBwILsE0s4gv333z/TvqFDhwZqAyN57+FE9EjuUym9BCTo6e27Oi2XoNfB4fyPp556KjP69QTQ752J0X322aei+ufPn2+aNWtmhZaNOYJsVI0ny8Ybb2yvYT/U1157LVAbmjdvLkEPRCodmSTo6einoq2UoBdFVFGGf//73xnh8xPy7GNrr722+fLLL8uu77nnnrN1sdXdiSeeGKicBx54wHrF0I527doFGmnj3cKkKNfwECB8gVK6CUjQ091/mdZL0DMonH/A1xtXv2zRRgARXI4tvvjidc5h9x47dmzZ7Tj33HNteUsvvbQhTG+QhDeL174jjzzS4GJZLA0cODBzDeakRx99tNglOp9wAhL0hHdQ0OZJ0IOSKj0fm1k0adIkI36wxt68/PLL22PEVsev2xNURr3sPVoszZ07125tN2HCBOs2SFgB0mabbWbLIj7Mhx9+WKwYw3U9evTI1H/rrbcW3XBj8uTJZrnllrPX8GAitLBS+glI0NPfh/YOJOjhdeQFF1yQEUsW6YwfP9688MIL1rSBiLNjEeYLFup4or7ttttaoc3XKkbD7Ee60UYb2X1L11hjDSvKRHJkhE85W2+9db7L6xzHfs5iIq7hl0O+RUjeRc8//7zZcMMNbX68Yvr27WuITqmUfgIS9PT3ob0DCXp4HbnVVltZ8cPzxNuzFUFfddVV7XEWA5GYvLzkkksMG0wz+vWLkY755sILLzStW7c2q6yyihk9erTdu/T++++3m1KzupMRM6P8k046KdBNPfzww7ZOBJ0HBCN/v0SIANqHjZ28mJFwj/zll1/8sutYCglI0FPYaX5NlqD7Uan8GKNffMtPP/30OrsSMXGZLegINYnwuvfee68VS79gXaeccordum7FFVestzqTlZx4ySC2SyyxhGGis1iiviuuuMJew3WYgXBfZB9V74U5hgiR7du3tyN4NsNm44+PPvqoWPE6nzICEvSUdVi+5krQ85Gp7DgjaDaPzvXPzifo1Pb3339bk8yNN95YZ7TMEn381FnEc+2119ZrGA8Pb6UnZpcff/yxXp7cAwTtwoaPmPPCjMMCIxYJZb9OPfVUa/dnopWHxu67715R3JncdujvZBCQoCejHypuhQS9YoS+BSDkxFjJTYUEnbwstf/tt9+MN3InCiJmFkS3U6dOvmYORsyMnsmDmSdIIhgYbpJcQzCvl19+2T5QGLnnvnjQEL2R7wr5+ZVAJEel6iEgQa+SvpSgR9uRxQQ9tzWMnD1zyqBBg3JP27/5NcAIHrHFdbFY4qHx+OOPWxMO1+ywww6G5fzFEvV79fAAmTlzZrFLdD4lBCToKemoYs2UoBcj5PZ8KYKOB0zbtm2tUCOkuEH6JULn4qWC5wnlF0uMwDHjIOa8+vfvb1hlWiwR+Mv7JcBDJsjDo1iZOp8MAhL0ZPRDxa2QoFeMsKQCShF0Fv14fuzEZsEUk5vYjxQ3RYQZO7dfntxr8E4hzIAn6LfddltuFt+/ecB45h8eHoQXUKoOAhL06uhHxUOPuB9LEXQiH3qiS8RGv8R+pF7wr6AC+8UXX2RG/quttprBvzxIIi6NN/mKoAeJzBikXOWJn4AEPf4+cNICjdCdYAxcSFBBnz17tl045Al6vlE0HjFLLrmkFX52ESIxick2cYze/RJt8Mrt1q1b4PgxuCx6vxgQ9Eo25fBrl47FR0CCHh97pzVL0J3iLFpYUEHHC8WLgoi74htvvOFb9rHHHpuJDfPWW2/ZPOTFpILNOzcxIXrppZdmBP2EE07w9cbJvY5FRzvuuGPmuqWWWsqw65FSdRCQoFdHP8rkEnE/BhV0oi56sVny+Zaz7J5t4Bhts4qTFae4OzKSxrXQW52afYsE32JUzjUsQrr++uuzT+f9fPXVV2d+CXDtZZddljcvJyqJGlmwYJ0MhYAEPRSs0ReqEXq0zIMKOj7sO++8sxVeBN0vZgqbUXjxz1kkRGLCEzdERNvPc4WAXN412M+JAVMssYKVB4RnpsGen2/y9ZtvvjHHHHOMOe6440zXrl3rrJLlgUNYXzbyCBLVsVi7dN4dAQm6O5axliRBjxZ/UEGnVcRuwV2xUaNGhgVG2emhhx6yoQU8kfVGzPiTcw3L+v3SxIkTM8LMIiQvUqNfXkb7jMzxnvHqISBXvpgv5GfDaTbJYLKWa4YPH54pmuiQPJww+UjQM1gS8UGCnohuqLwREvTKGZZSQimCzoi2c+fOVhjxFUcwWYFKlEb8wYnS6NnZWaLPdnJ9+vQxHTt2zGz0zBL/O++80/qdE2CLwF6eOJMP88xVV11lz+Ob7r0YSfPdIC9Bv7iOzaSeJn23AAAgAElEQVT9Vr9693/LLbeYs846y6405WGEbzwi7qXzzz/flgcDpWQRkKAnqz/Kbo0EvWx0ZV1YiqBTwfvvv29jpjMJyaTkdtttZ8UVESYRThcfdaI0co7AX9lmFEbyLPHnAUAeFiqtvPLK9oW7IwHE/F4E6+rQoYM13RBZMUh8GGLXMCHLwiUeADwwPLMPD5a9997btsXFZthlwddFeQlI0POiSdcJCXq0/VWqoNM6RuVjxowxjHAJuUs42+zEZhaILguRcjeGxtZN/unTp5f0wssG18egCe8ZLxH3BbdG2uulqVOnWpHHK4dfHkrJIiBBT1Z/lN0aCXrZ6Mq6sBxBL6uiGC866KCDrL86USC9dNddd1lzSz5/ei+f3uMhIEGPh7vzWiXozpEWLLAWBB1TDWYdb9TOAie2qsPkwxZ2SskjIEFPXp+U1SIJelnYyr6oFgQdn3hs+V4iNC/fM0ITfPfdd95hvSeIgAQ9QZ1RSVMk6JXQK/3aWhB09k5lohV7OSF3veBheMAoJZOABD2Z/VJyqyToJSOr6IJaEHRiyRAWgP1TWa2KSyVeNtoUo6KvTqgXS9BDxRtd4RL06FhTUzULOn7wrBJlhSgLh7ChE9kR98UDDzwwNYuJeCCxAQgmIlbr7rLLLvVeHOee6M/shJfRbrvtVi8/ZXANq3jffPPN7EsS8VmCnohuqLwREvTKGZZSQjULOmF4mQw9+uijbaRHVpT269fPbL755vVcLUthFnVeFnCNHTvWmorY9o+YN95iLN7Z3IM5AjbTzl3B++STT9rFYN4uU951rJBdb731rKgTHiFpSYKetB4psz0S9DLBlXlZNQs68WZ69OhhiDGDHR0b+pFHHpn6qIyssM0WdUba/BrJl/hl4sWyZ/HWaaedZt577z274CrfNXEfl6DH3QOO6pegOwIZsJhqFnQQsGiIFaMsgMK7pRoSvzS8DbUZcW+00UZ5Y81zv5iZGNljakrLvIEEvRq+qcYofG7E/Vjtgh4xzsiqO/nkk21sGgSdTT7GjRvnW/e3335rwyUQyfKll17yzZPEgxL0JPZKGW3SCL0MaBVcIkGvAF6MlxK6wNsZCvv4AQccUK81RK7E1EIcnGeeeabe+SQfkKAnuXdKaJsEvQRYDrJK0B1AjKkIPFS8SU4mRYmh4yXi0DN/gP89IYrTliToaeuxPO2VoOcBE9JhCXpIYCMolrDFnqAvvvji5qKLLrK1EtqADT3wtScwWRqTBD2NvebTZgm6D5QQD0nQQ4QbctGEAMYt0xP1nXbayXq7nHfeeaZFixZm1KhRifZkKYRHgl6ITorOSdCj7SwJerS8XdfG5Kgn6PzvEOOdoGPEp2ekntYkQU9rz+W0W4KeAyTkPyXoIQMOuXhCGSy22GIZUUfcBw4cmNnII+TqQytegh4a2mgLlqBHy1uCHi1v17URFoCdobxROlsAsqtU2pMEPe09+L/2S9Cj7UgJerS8w6iNnaE8QceV8Z577gmjmkjLlKBHiju8yiTo4bH1K1mC7kclPccIvuVtzO2JOh4uhD1Ic5Kgp7n3stouQc+CEcFHCXoEkEOqgngsm2yyiV36z8IiT9DXWGONREZQLAWDBL0UWgnOK0GPtnMk6NHydlUbG20TNXL99dc37JXKSlBP0Hm/8cYbDVEa05ok6GntuZx2S9BzgIT8pwQ9ZMAhFI//OatE27dvb9544w1bAxt4bLXVVhlRJwY6+dKaJOhp7bmcdkvQc4CE/KcEPWTAjoufP3++jc/CKtBXX301s/H1X3/9ZX3PvVE64XWnTJmSOe+4GaEXJ0EPHXE0FUjQo+Hs1SJB90gk//23334zRx11lGnWrJl5+umn64k1Ar7CCitkRulnnHGGVoomv1uru4US9Gj7V4IeLe9ya2MDCza1btq0qRk9enQ9MafcH3/80fTs2TMj6Jhkvvvuu3KrjPU6jdBjxe+ucgm6O5ZBSpKgB6EUbx7MLFdeeaVh27ghQ4YYzCv5Eht5NGrUKCPqCs6Vj5SOR0JAgh4J5kwlEvQMikR+wMwyfPhw07p1azNgwADD34WS58ro2dK7d+/uO5ovVEYSzmmEnoRecNAGCboDiCUUIUEvAVbEWVnCf/bZZ9v9Q/E3D+q1cswxx2RG6Isuuqh5++23I2555dVJ0CtnmIgSJOjRdoMEPVrehWrDtPLEE0+YG264wZx44olm0003zQgzG1hcdtll5uOPP/YtgpE71xITHd90b4TOOy6OI0eOtLHRCeaVhiRBT0MvBWijBD0AJIdZJOgOYVZYFH3BZs5e9MQGDRrUEWZG27fddptvLexWxFZz2ULulcMxNsDgPCP+NCQJehp6KUAbJegBIDnMIkF3CLPCotg2bvr06TZa4gcffGA++ugju60cn3lhgpkzZ45vLcQ+x35OHi8/ZSH03rWcmzlzpu/1STsoQU9aj5TZHgl6meDKvEyCXiY4XRYqAQl6qHiDF/7PP//YWXXvPfiV/80pQS+VWGX5JeiV8dPV4RCQoIfDNXCpTOjMmDHDLnpghRqTOpdccoldnjxv3rzA5UjQA6NyklGC7gSjCnFMQILuGGgpxRHtDQFnY9rVV1/d7Lnnnma//fYziPPCCy9s+vTpY4gOFyRJ0INQcpdHgu6OpUpyR0CC7o5l4JIIz8kyZG92/fjjjzdffPFF5vp3333XbLjhhnbmvVu3bnZpcuZkng8S9DxgQjosQQ8JrIqtiIAEvSJ8pV+MmF999dUZF6sLLrjAtxD8X4n8huvUpZde6psn+6AEPZtG+J8l6OEzLlYDC4YmT55svvnmm2JZa+a8BD3irr7llltsbAmEmoBA+eJL4DKFKYZ8G2ywQdGg+xL0aDtSgh4tb7/aCIO75ZZb2s2eTzrpJPOf//zHuh+meYMKv/ss5ZgEvRRaFeZ9+eWXzXrrrWdFunHjxubTTz/NWyJ+sJ6gL7XUUuarr77Km5cTEvSCeJyflKA7R1pygYzOPbMli4n4f1l77bXtXBS/fJ999lnz888/l1xumi+QoEfUe3iznHzyyVbMGXUfdthheUfnNGnChAmGncjJS+hPdlYplCTohei4PydBd8+01BIR9DZt2mT+p/hf4YW4s8Jz2WWXtXNROBfcfffdRQdFpdafxPwS9Ih6hZ+HjB68L93EiRMLRnMbPHiwYRRP/rZt2xbdjVyCHlFH/q8aCXq0vP1qyyfo3v+Y947HGP9LbGLRtWtXO4eFh1k1Jgl6RL3K5rPeFwzxLWZCOfDAA03Dhg3tNWxq+/fffxdsqQS9IB7nJyXozpGWXGBQQff+77LfEfg11ljD9O/f39CXBOnif4yFfWlOEvQIeg9zy6mnnpoR9H333begbY/dUjp06JDJf+655xZtJYJO7Gd+CZCYGNIrHAbwZSszIvkhEjysiQki3uHw9uOK+L7wwgu+Jpds4Q76mU0wevToYU0zn3zyiY39Qp+mLUnQI+gx3Kt69eqVEWhCdRb6suCyuPTSS9v8LVu2zBv6M7vpTA5hc2e1KbuvjBgxQq+QGNx0003mlFNOMfQNgnHooYeaYcOGiXdIvP2+y4TKHThwYKYPggp3kHzsXLT99tubCy+80Dz55JM2SNdPP/2U/e+W2M8S9Ai6hj0LjzjiiIygP/DAA3l/2vGT76CDDsrk5UtbLD311FMZ80yQL6zy/HfyTBzSzYHJz+xt48LoTwZKxx13nHnppZeK/Rsm4rwEPYJuwD6HMHtfuPHjx+cVdLxbVlxxRZt32223LbpZLaE+O3bsaPMfeeSR5pprrjFXXHGFXiExuOqqq8zpp5+e2SUeLwv6Vsyj/c6xV+i//vWvjGuv979V6TveMeuss4454IADDK6P48aNs6F0S4mrFIGk5K1Cgp4XjdsTY8aMMU2aNLHCe/311/u6LCLO/NTjS8muK1OnTi3YCHxs9957b5ufODBp+dIVvKkUnHz00UcNmybQT+ecc07R/SpTcEupbOIrr7zixIbOOg/+70477TQbkoP/u6Db1iUNnAQ9oh759ttvM+KL18rcuXPr1EzExV133dWKxHbbbWeCbHnFFxCXrPbt29eJBVOnYP3hlAC2VGzmiHm7du0MoqIUD4EpU6aULei4MDIJii3+xRdftP8/OC+kPUnQI+zBN954w2y22WZWDLbZZhvz0EMP2Zn6888/3670JHYLk5rFFhHR5FGjRplWrVrZmDB8IZWiIUAfeu6k/fr106+iaLD71lKq2yLrQPA2w0Pp888/t2s78KCppiRBj7g32crq4osvtouM8JJAlInVwp6FbHUVxA8W18R1113XPhjwaCnmox7xLVZtdb///rshMiajc0Z4Dz/8cNXeaxpurJig4/XFPBTzSmxL57mWBvkfS8P9+7VRgu5HJaJjCMQff/xRUm08EPBjR1SOPvpo8+uvv5Z0vTKXT4DYO82aNbPsiVuP91LYCfHxFrzwudyXV0bY7Y2y/GxB51cTc1SrrbaaNYnde++9qdkH1CUzCbpLmiGXxQhj0KBBVlC22mqrwJtfhNysmimeCVAepEyiETUz7MTDnrkUJtTHjh1rEKnsF8cKvXLzMtlXTSYGfql27tzZbLHFFtZU6a34DLtfkly+BD3JvZPVNkZm9913nw06hFsjCx6UoiPALyPPnRQBmTVrVuiVs2IY76VFFlkkEz+fB4r3Ys6lefPmdhEaC9F40HAM1zuu8fJ57/yqmDNnTujtjqoCJqhZ1ZkvBHVU7UhSPRL0JPVGgbYwGUfsCdzlhg4dKrt5AVZhnMLvGWEkBgiT2FEkTHKEXGby/NZbb60TDqJTp07mscces5PqeHvwYoSKXZ/8xAbHj5pfcp6g9+3b11CmUvUSkKCnoG/xid1ll13sP+ZRRx0lz4qI++yXX34xa621luVP/JYgXkium8hIFBH3xJll6UES2xl6UT6DxAQKUqbyJJeABD25fZNpGRtJ84/MaOvLL7/MHNeHaAgQuwV/f17sjBNHuuuuu+rELQmyToF2YjP3bP/XXXddHE1XnRESkKBHCLucqojkh5mFmBLM6itFS4CJSW/tAHbqjz/+ONoG/K+2M888M7M6le9CULsxgs4DCQ+Qe+65J5a2q9LoCEjQo2Ndck3PP/+83XVlscUWM0RgVIqeAJ4inqvi4YcfHn0DjLETmZ6rKr/UWOEYNCHohJogtDJB3JSqm4AEPaH9ixcFC474Bz7hhBMS2srqb9buu+9utzTjoVostk5YNKjX24uW78Odd97pWxWbprz99tt11jbg6sokLhPqnFOqbgIS9AT2L4tAvBC6Xbp0MUzKKUVPgCXimDcQUdwH40rsh+nFx6ct+eZRevbsaYgThIull4hPwq48fI9y4wd5efRePQQk6AnsyyFDhli/Y/yeP/zwwwS2sDqahG9/oXTMMcfY0Tki+vjjjxfKGto5bOV4p9AGXhtvvLHvA56l7YzicU3MjrrJPeJ7ni3yoTVWBcdOQIIeexfUbQCbRxMnBH/n+++/v+5J/eWUACPdfDvRTJs2LeOqSDwQYtrHkbJDPSDoZ511lm+8H3ZMYjER3jDFHlRx3IfqjIaABD0azoFqYTTOKkT+cfEz1j9mIGxlZ2LZPL+G/NJ5552XGZ2TL66Ee6LnA8/3gtE6D/1JkybZXw3EZr/sssvMKqusYrcg5EGkVLsEJOgJ6XsCPfXu3duKOfbzKAI/JeTWY2vG8OHD7a8holxmJ1wTt9xyS9sXxAqJYpl/dv3Zn/mVlr2Mnx2SWNzEpuD8ksu2rXft2lVx8bPh1eBnCXoCOh3XMm9p+YYbbihvhIj6xNsWkK37shOBt7wdiTBl0D9xJDxUWL7PyJwXC8twX2WSlFAAtI1fEt4WhGx4wjVKtUtAgp6AvufnM4GVll12WdnNI+yPgw8+2JpViJtNrBwSO0vtscceVkA7dOgQ66Q09vPu3btnBB0zXHYsFryhCJ98ySWX2Dy33357hPRUVRIJSNBj7hXignhBtwiNK7t5dB3CVn/e6BczFwn7NNEKOU5/xDnife+998xyyy1n24LZxW+SnJWsbJiCCYbgXLmJydy07o+Zey/6uzgBCXpxRqHm8EZg2uQ5VMz1CmeDbezjnqAzSmeH9+OOO84ew2XUb2s/HriEtc3nHVOvojIPUA/RFL32sX+p9ysiu0ja0atXL8OWhrlBwxD7nXfe2e5lm32NPlcvAQl6jH2LCxr/sGwnxybRStERmD59ullzzTUzgsmON/xSwuxFnxDVkolpfLpZgYndGuFkQ25s72Enfhmwv6wn6MQy50GSmzC5jB492jzwwAO5p6wXDDFciAekVBsEJOgx9TMxq/lnZV/RCRMmxNSK2q0W80Tbtm0zgukJZ4MGDewmEYRbYJ/X7FG8J/RRUGPkvckmm2Tax+QnI+6giRE+cwGrr7664deIUm0QkKDH0M/8dMb9DLsoPsRK0RNgWzcepp6QB3k/4IADIrOps+iJhwvtYsKcXwilJAJxsTiNh5JS7RCQoEfc13hR/F97Zx4qVfnG8T/0aqm5XBc0pasIBmld0yhLr140EXHNMhFRcilIjVJyoUDKUEJx6w9RsQQ31JAgMQ0ll/rDJRU1W6wQzVY1RMUlrefH9+V3hnHuLGdmzsw9Z/y8MJy5Z3nPO5/33u8987zPMmDAAPeHOn78eBZBi8zfu92iRYvck7gfIdc5skUXM3xeWR69sSmk32/+c30+mWH69etn5eXlWaf7ZVHe+w2J5hZBL+K8yeNg+vTp7g9VPsXFFIgifsxI3OrNN990BSs80Uy3VcKrYufUmTRpUkzQlTr3woULvrl6hcT1wJCpqV/53Stnuh421M6dO2eKQFViL1q0CCDoRZwvBYWoiK8i/FQrklZ7BJTbPJ2Ie8fki67q8sVuigbVGLRYq+IWfpps7LK1y0SjwKhkXjrx/fz2228uIlYLwXqal6eVcvCrKpN82uN93uOv4314CSDoRZqbr776yi1Q6Q9UCZQUFEKrHQJacPSChzzhTraV0Cnoq5hN3+L0++GNR+6Uq1evTjoEPV3rm8O+ffucL3pVVZWrTKRrlQYg0+/YqFGjXHk6+bvrn5ailZ966imbOXMmqSeSEg//TgS9CHOkBS7Pbi5XtPj0pkW4PbdIICCTgkxenmgm28rdb/369RlFMaHrnH6UW6Rs3vr21qhRo7tyt2hsKq4hYVflpPiXxqggKB1P/AyywWdqEnIvcEpbpRlQ/dpszDuZ7sHx4hJA0AvMW3bIGTNmuD84Vb9JVZygwMOg+zgCWmD08p8kCqF+lvfR/PnzfdftjOs6p7dK/iVfcYX2z5s3L6+XRFnFoLOxf+sbiwpJa32HYio5TWFoLkLQCzgV+srreSsoiCVZaHYBb0/XKQgoAlOh8snEvE6dOqbCFtkIYorbRGK37Oj6vLK9e01FNfB28WhEa4ugF3C+lJtai036urxy5coC3omusyGwdu1at3CYKOha35BtPVlEZjb9R+VcRctqcXjdunWxIcscuH379pjHS+wAbyJBAEEv0DTJBUwLTBIN2SVp4SGwZMmSpHZnFRcptntibVHRw0b37t2dB42e0uW7riRey5YtcykOzpw5U1tD4755EEDQ84CX6lK5eynvh8Rci12q6UgLBwGZE5SLxYvC9J7SZRI7cOBAOAZZ4FGcOnXKRo4cadOmTXMuinrwUO6a4cOHu8ViZZykRZMAgl6AedOCmgSjoqLC9MdDCw8BmRTig3Yk6K1bt7bdu3eHZ5AFHokqNSn1gZrWClQYQ9kaX3nlFdu7d29RPHsK/BHv2e4R9ICnfuvWrdayZUuXR2Pbtm0B9053+RJQdK6eRL0n8/r167u0ufn2G5Xrtdgpc6C+qXhNAUly5cSd1iMS3S2CHuDcnTx50lRCTmKxcOHCAHumq6AInD59+i4fdJVyixe3oO5DPxCoDQIIekDUZSdX5J3EfOzYsaQsDYhr0N0cOnQolgd97ty594x7YtAc6S+cBBD0gOZFASES88rKSsNDICCoBehGPuhNmzY1Ja5SAQsaBEqJAIIewGyqQEWzZs2cUOzatSuAHumiUATkc63qP1SIKhRh+q1NAgh6nvTlxfL444+7p/OlS5dij82TZyEvv337tilJ2pEjRwp5G/qGQK0RQNDzQH/x4kUbM2aME/OJEyfa5cuX8+iNSwtNgHD2QhOm/9omgKDnOAPyjFD+C9nNe/Tocc9EGOaIi8sgAIEiEEDQc4S8ZcsWl+5UQSlE1uUIkcsgAIFACSDoOeBUkef27du7NKvKfUGDAAQgEAYCCHqWs6BQaSVxkqllwoQJpig7GgQgAIEwEEDQs5wFBQ0pzaoiQkm6lSU8TocABApKAEHPAu8HH3zgSn41b96cpFtZcONUCECgOAQQdJ+cVYi3Xbt27ul806ZNPq/iNAhAAALFI4Cg+2CtUP7q6mpnN1d9UBoEIACBMBJA0DPMigroTp061Yn5oEGDsJtn4MVhCECg9ggg6GnYK3hoxYoVzj1RFW3krkiDAAQgEFYCCHqamfnyyy+tTZs2rsizV+ElzekcggAEIFCrBBD0FPhVOFdFdFVKbs6cOaY6oTQIQAACYSaAoCeZHZlaRo8e7ezmzz33nKuGnuQ0dkEAAhAIFQEEPcl0LF682Il5586d7fjx40nOYBcEIACB8BFA0BPmZP/+/VZWVmbl5eX28ccfJxzlRwhAAALhJYCgx83N2bNnrUOHDs6rZfbs2XFHeAsBCEAg/AQQ9P/P0dWrV23o0KHO1DJs2LDwzxwjhAAEIJBAAEE3M1Wyefvtt2N28z/++CMBEz9CAAIQCD+Bkhf0GzduZJyF9evXuwLPLVq0MPme0yAAAQhEkUDJC/qHH35o77zzTsqQ/YMHD5q8WZTffNWqVVGcQ8YMAQhAwBEoaUFXHhbZw5W/fMiQIfb999/fNe0KHho+fLgT8+nTp9uVK1fuOs4PEIAABKJEoKQFfdeuXS7lrZ6+FfHZqVMn+/TTT938yBSjCFAd69+/v/38889RmjfGCgEIQKAGgZIV9H///deZWiTY8a/GjRu7/du2bXP7O3bsaHv27KkBhh0QgAAEokagZAX9xx9/tF69et0l5p6w62m9SZMmbiGUIs9R+5VlvBCAQCoCJSvoW7dutTp16iQVdE/YH3nkEdu5c6dzW0wFiP0QgAAEokKgJAX98uXLNnHixLRi7ol669atbfny5aZraBCAAASiTKAkBf3EiRP24IMP+hJ0CXu9evXstddeM5lpaBCAAASiSqDkBP327du2dOlS32LuPalr269fP9NiqSJHaRCAAASiRqDkBP3SpUv2zDPP5CToEvXJkydHbQ4ZLwQgAAFHoOQEXS6I8U/d2byfMWOGnTlzhl8NCEAAApEkEJigy0xx8eLFnF9BLEpqDC+99FLWgt6yZUvbsGGDXbt2LZKTyKAhAAEIiEAggi4xHjt2rBPSunXrunzi2sptUC+F3ie+tD/+3GbNmtl3332X16z88ssvzrc8m6fynj172tdff53XfbkYAhCAQBgIBCLo8g5p1KhR7Mm4YcOGLuHVqFGj7PXXXzeVdFu3bp1t3rzZveQjPmHCBLv//vvdNRL3l19+OW8e2SyG6t4aw4ULF/K+Lx1AAAIQCAOBvAVdIfYbN26MPZ0/+eSTTrTlbZKqqU5nZWVl7B/AiBEj7NatW6lO97X/n3/+scceeyzWZ7qn9Hbt2tmiRYt89ctJEIAABKJCIG9BlxArk6EEVNuffvop7Wf/9ttvrbq6Oia8zz77rP35559pr/Fz8Isvvoj1mUrM9U2gd+/etnv3bj9dcg4EIACBSBHIW9BV3ee+++6zLl262MmTJ9N++HPnztnzzz8fE17Zr0+fPp32Gr8HX3jhhVi/yQRduVumTJli58+f99sl50EAAhCIFIG8BX3Lli1OSFVEIl1TbnLZyT2x1T+Aw4cPp7vE9zGJdHl5eaxv7x7e9uGHHzYVurh586bvPjkRAhCAQNQI5C3oejKW29/Zs2dTfnbZ0+XjLU8XiexDDz3kkmKlvCDLA3PnzrWysrKkgq7CzwcOHMiyR06HAAQgED0CeQm6KvzoyXjMmDFpP/n7778fy3youp3yeAmqaTG0e/fuNcRcZqBZs2YZBZ+DIk0/EIBA2AnkJeh37tyxzz77zGQbT9U++ugjq1+/vhNcuTYuWLDA5BkTVPvkk09M/yQ884q28mJR4ed0njZB3Z9+IAABCISFQF6CnulD7Nixw+STLpFVRkP5pActsooM9Uw5KlyhohZyi6RBAAIQuNcIFEzQDx48aG3atHFirojQkSNH2vXr1wPl+80338R8z2ViefXVV+3q1auB3oPOIAABCESFQEEEXb7m8UE+ffv2tb///jtwJooMVcSncp+vXbs28P7pEAIQgECUCAQu6MpW2L9//5hN+4knnkjrAZMrLAUjvfjii1ZVVWVHjhzJtRuugwAEIFAyBAIV9N9//91Gjx4dE3PV7Dx16lRBYB09etRU4Fn3pEEAAhCAQEDZFgVSgUNa9FR4vRZB27dvb/v27UvKWN4xP/zwg8ntMdem+924cSPXy7kOAhCAQMkRCOQJXZ4r7733Xsw9sVWrVqaMiqma8q4oidf+/fsp95YKEvshAAEIZEkgEEFfvXq1y+eiJ/MHHnjAVq5caQr4SdXeeustd16m3C+prmc/BCAAAQjUJJC3oH/++efWoEEDZ2ZR+P27776b1hSiIhR9+vSxgQMH2l9//VVzROyBAAQgAIGcCOQl6MeOHYtVCFJQz6RJkzKWcVNkp57klyxZYrKl0yAAAQhAIBgCOQu6qhQpyZbEWWI+ePBgy1QXVE/k8oJRKgDZz2kQgAAEIBAcgZwEXZkVtagpMdfr6aefNplS0jUtnK5Zs8adP2DAgIznp+uLYxCAAAQgUJNA1oL+61gXdHgAAAG5SURBVK+/mlLSemL+6KOPZsydcu3aNVemrm3btu46ecT8999/NUfDHghAAAIQyJlAVoJ+6dIlZyf3kmFVVFTE8pqreITK0Wkr/3JFcipqVAm6pk2bZs2bN3dirkyIWkilQQACEIBAsAR8C7qEes6cOc5e7j2dS9C1EKqMh95r3LhxpqIXCv+XKSYxta32B1FDNFgM9AYBCEAg+gR8C7qezt944w1TOH/Xrl3dq1u3bm5bWVlp8S+ZYTp37uxeeq/zdVwCLzs6DQIQgAAEgifgW9BVlEKirvqdsqN7L/2c+PKOJW6Vd4Vw/eAnkR4hAAEIiIBvQQcXBCAAAQiEmwCCHu75YXQQgAAEfBNA0H2j4kQIQAAC4SaAoId7fhgdBCAAAd8EEHTfqDgRAhCAQLgJIOjhnh9GBwEIQMA3AQTdNypOhAAEIBBuAgh6uOeH0UEAAhDwTQBB942KEyEAAQiEmwCCHu75YXQQgAAEfBNA0H2j4kQIQAAC4SaAoId7fhgdBCAAAd8EEHTfqDgRAhCAQLgJIOjhnh9GBwEIQMA3AQTdNypOhAAEIBBuAgh6uOeH0UEAAhDwTeB/wOtfMcHzh+YAAAAASUVORK5CYII=)
According to the description of the unified field theory, the Faraday electromagnetic induction principle is:
The changing magnetic field produces an electric field and a gravitational field, and the changing magnetic field, gravitational field, and electric field are perpendicular to each other.
However, the gravitational field generated by the changing magnetic field is a vortex field. Its curl is not zero, and its divergence is zero. Unlike the gravitational field generated by universal gravitation, which is distributed symmetrically around a point, the divergence is not zero, and the curl is zero. Therefore, the changing magnetic field cannot directly interact with the gravitational field. This is the reason why the world's use of changing electromagnetic fields to produce antigravity experiments failed. Gravitational field, nuclear force field and electromagnetic field have many things in common. If you want them to unify the experiment, extreme physics and extreme environment will make them qualitatively change. The same is true for the beginning and evolution of the universe.
2.2 Simulation experiment of chemical elements precipitated by gravitational waves designed using the principle of black holes
If a simulation experiment is designed based on the principle of black hole formation, the realization of space-time distortion in earth space excites gravitational waves. The gravitational wave acting force is greater than the earth's gravity of 9.8 N / kg, and then escapes from the constraints of the earth and flies to other stars in the universe.
How to get excited gravitational waves in experiments? It needs to be performed under extreme physical conditions and special physical environments. The experiment of simulating the physical changes of stellar nuclear fusion may distort space-time (the hydrogen bomb is fusion, but the explosion time is too short to be space-time twisted). The experimental goal is to physically change the internal structure of the magnet and the atom of the metal coil to make the magnetic field of the magnet as much as possible. With the electric field of the metal coil, the gravitational field becomes larger. When the gravitational force reaches a certain level, it can interact with the forces of other planets in the universe. The gravitational wave strength and the proportion of the force are balanced to determine the spacecraft's flight direction. The nuclear fusion during the experiment radiates many rays: (including alpha rays, beta rays, gamma rays, infrared rays, ultraviolet rays, high-energy particles, etc.), and the products after nuclear fusion form a variety of chemical elements. (5) This confirms the experimental synthesis Elemental success rate is high.
The origin of the chemical elements of the universe has not been stated so far. This article intends to design experiments based on the extreme physical conditions of the universe. The formation of chemical elements in the universe is the product of stellar fusion (6), (3), (4). At the same time, various rays, such as infrared, gamma rays, x-rays, and ultraviolet rays, play an important role in chemical reactions. These rays are the physics of atomic nuclei. Changes radiate, indicating that they are strongly connected to the atomic structure. The experiment used high-density hydrogen, deuterium or tritium to represent the initial formation of hydrogen clouds. Alpha rays, X rays, infrared rays, ultraviolet rays, beta rays, gamma rays, neutron flow, proton flow, radiation and high-energy particles representing nuclear fusion radiation; an experiment is known that the radiation energy nuclear reaction equation, that is, a combination of neutrons and protons The deuteron emits 2.22 mega-electron volts of energy. This energy is radiated by gamma photons. In the opposite process, the tritium or deuterium nucleus is bombarded with gamma rays to be divided into neutrons and protons. Various types of radiation and counter-radiation provide energy for the synthetic elements. The energy includes dark energy (dark energy changes in the range where the value of space-time effect changes) and other different levels and different types of energy. In the experiment, there are neutron flow, proton flow, and β-ray (high-speed electron flow). Kind of ray, magnetic field (make the electron flow move farther around the circle), and quantum science knows that the main particles of atoms are neutrons, protons and electrons. As long as appropriate physical conditions are designed, artificial elements are not impossible. After the operation of our nuclear reactor, a large amount of waste is often generated. These wastes are not the original uranium, but various other radioactive materials. It can be seen that particles and rays collide with each other to form some chemical elements. The principle of simulation experiments, typical magnetically constrained nuclear fusion, but this process does not meet the actual nuclear fusion requirements. It is a subtype magnetically constrained nuclear fusion device, but it can also form a weak confinement space, free negative electrons (B Rays) and positive protons stay in a limited space. Because deuterium and tritium do not have nuclear fusion, but after passing in Y-rays, the deuterium and tritium react cyclically. This reaction is different from the quantum energy emitted by chemical reactions. This energy property is flexible quantum energy, which is closest to the nucleus Core energy level. Magnetically constrained nuclear fusion constrained space. X-rays, B-rays, neutron flow, proton flow and other particles collide with each other. The energy and pressure collapse and the compression density become larger. In the process, the rays provide the required conditions for the quark, and the energy is asymmetric. , So as to achieve the quark effect and the weak electric phase transition effect in the universe.