0¼0¼0¼1¼-1¼-1¼-1¼Superbreeders¼These state-of-the-art breeder reactors produce plutonium at twice the speed of normal breeders.¼7¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼-1
1¼0¼240¼2¼-1¼-1¼-1¼Cold reaction isotopes¼Cold reaction isotopes can be produced in a 'cold' reaction, reducing the need for expensive breeder reactors.¼8¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼-1
2¼0¼180¼3¼-1¼-1¼-1¼Synthetic detonation isotopes¼New synthetic detonation isotopes have eliminated dependence on plutonium and uranium and can be 'manufactured' in a laboratory.¼9¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼-1
3¼0¼120¼4¼-1¼-1¼-1¼Crystalline cultivation¼The so-called 'crystalline cultivation' of synthetic fissile elements will further boost this sector's productivity.¼10¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼-1
4¼0¼240¼-1¼-1¼-1¼-1¼Intelligent catalysts¼Intelligent catalysts accelerate the crystalline cultivation of synthetic fissile material.¼12¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼-1
5¼1¼0¼6¼-1¼-1¼-1¼Full-seam extraction¼Full seam extraction uses a complex chemical process to extract large sections of seams or ore from rock deposits.¼-1¼7¼-1¼-1¼-1¼-1¼-1¼-1¼-1
6¼1¼240¼7¼-1¼-1¼-1¼Nuclear miner¼The revolutionary nuclear miner works using a small reactor to provide the high energy levels needed to blast the ore out of the seam.¼-1¼7¼-1¼-1¼-1¼-1¼-1¼-1¼-1
7¼1¼80¼8¼-1¼-1¼-1¼Mine vacuum¼The mine vacuum works to minimize the loss of mineral deposits due to wasteful mining methods and literally sucks excess minerals out of the excavated seam.¼-1¼7¼-1¼-1¼-1¼-1¼-1¼-1¼-1
8¼1¼120¼9¼-1¼-1¼-1¼Chemical miner¼The chemical miner uses an advanced solvent to liquefy the mineral deposits and extract the mineral deposits from rock.¼-1¼7¼-1¼-1¼-1¼-1¼-1¼-1¼-1
9¼1¼180¼-1¼-1¼-1¼-1¼Teleporting¼The use of teleporting technology in mines can double productivity. In seams that are not too deep, the beam can completely eliminate the need for mechanical intervention.¼-1¼13¼-1¼-1¼-1¼-1¼-1¼-1¼-1
10¼2¼0¼11¼-1¼-1¼-1¼Smart plants¼Smart plants are plants genetically engineered to fight off disease.¼-1¼-1¼7¼7¼-1¼7¼-1¼-1¼-1
11¼2¼300¼12¼-1¼-1¼-1¼Moisture intensification¼A further development of smart plants now allows plants in more arid areas to use their water more efficiently¼-1¼-1¼8¼8¼-1¼8¼-1¼-1¼-1
12¼2¼120¼13¼-1¼-1¼-1¼Soil conversion¼This technology is particularly useful in areas where the topsoil has been damaged by excessive use of fertilizers. The converter can re-energize the soil after a single application.¼-1¼-1¼9¼9¼-1¼9¼-1¼-1¼-1
13¼2¼240¼14¼-1¼-1¼-1¼Speed-growing¼Genetic engineering has made another spectacular leap forward. Having identified the genes which control plants' life cycles, scientists are now able to produce plants in a matter of weeks, rather than months.¼-1¼-1¼12¼12¼-1¼12¼-1¼-1¼-1
14¼2¼80¼-1¼-1¼-1¼-1¼Climate engineering¼Climate engineering promises to provide people with the key to controlling their climate, with all its attendant advantages. Climates will be engineered over areas of approximately 200km▓ for farmland.¼-1¼-1¼13¼13¼-1¼13¼-1¼-1¼-1
15¼3¼0¼16¼-1¼-1¼-1¼Improved intelligence chip for robots¼Scientists can now develop an improved intelligence chip for assembly robots, allowing them to react to feedback from a central computer and almost eliminating the need for human supervision.¼-1¼-1¼-1¼-1¼7¼-1¼7¼7¼-1
16¼3¼120¼17¼-1¼-1¼-1¼Component fingerprinting¼Component fingerprinting now allows assembly-line robots to track components individually through all the test and assembly phases of manufacture, reducing the number of defective products.¼-1¼-1¼-1¼-1¼8¼-1¼8¼8¼-1
17¼3¼80¼18¼-1¼-1¼-1¼Depth-perception robots¼Robots with depth perception sufficient to allow them independent movement are on the scientific horizon. It is expected that these robots could represent a significant step forward for the manufacturing industries.¼-1¼-1¼-1¼-1¼9¼-1¼9¼9¼-1
18¼3¼240¼19¼-1¼-1¼-1¼Robotic supercomputing¼Robotic supercomputing allows a central computer to monitor a staff of testing and assembly robots in very much the same way as a human supervisor would.¼-1¼-1¼-1¼-1¼10¼-1¼10¼10¼-1
19¼3¼300¼-1¼-1¼-1¼-1¼Syntheticism¼Syntheticism completely eliminates the need for robots as the requisite materials are simply chemically encouraged to bind themselves together in the correct way to assemble the finished product.¼-1¼-1¼-1¼-1¼13¼-1¼13¼13¼-1
20¼4¼0¼21¼-1¼-1¼-1¼Intelligent lasers¼Intelligent lasers remove one step from the complicated process of hi-tech manufacturing by responding to visual feedback from a computer-controlled monitor.¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼7
21¼4¼120¼22¼-1¼-1¼-1¼3D printer¼The 3D printer actually provides the raw materials for manufacturing in the form of the constituents of the materials needed to make the finished product and sculpts them into the required parts.¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼8
22¼4¼240¼23¼-1¼-1¼-1¼Skeleton crystallization¼Skeleton crystallization takes the 3D printer concept one step further, assembling the product by forming the materials in a quasi-crystalline fashion over a magnetic 'skeleton'.¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼9
23¼4¼100¼24¼-1¼-1¼-1¼Refined 3D printer¼The 3D printer can now be improved using an offshoot of medical technology to set the parts in the required forms using a silicon frame.¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼10
24¼4¼300¼-1¼-1¼-1¼-1¼Freeze-dry moleculization¼Freeze-dry moleculization takes its cue from the recent development of skeleton crystallization, with the difference that the product is assembled almost from the molecular level, thus producing much nicer finish.¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼-1¼12
