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The special courses most distinctly marked out are the following:

(a.) In chemistry and metallurgy;

(b.) In civil engineering;

(c.) In mechanical or dynamic engineering;

(d.) In agriculture;

(e.) In natural history;

(f.) In studies preparatory to medical studies;

(g.) In studies preparatory to mining;

(h.) In select studies preparatory to other higher pursuits, to business, &c.

(a.) For chemistry and metallurgy the Sheffield laboratory is fitted up in a complete and convenient manner, is provided with all the requisite apparatus and instruments of research, possesses a considerable collection of chemical preparations, and has a consulting-library of the best treatises on chemistry and the chemical arts. It is open for chemical practice seven hours daily, for five days of the week, but is closed on Saturday. The student works through a course of qualitative and quantitative analysis, which is varied according to his capacity and the object he has in view. Each pupil proceeds by himself independently of the others, under the constant guidance of the instructors. The regular students in chemistry are prepared for chemical work by their practical exercises in the laboratory during freshman year. In the junior and senior years they are required to occupy four to six hours in the laboratory each working-day. Special students who have not had adequate instruction in inorganic chemistry are required to join the freshman class in Eliot and Storer's Manual. Junior students have recitations in analytical chemistry and lectures on theoretical and organic chemistry. Senior students have recitations and lectures on agricultural chemistry and metallurgy. Mineralogy is taught in the junior year by lectures, which are fully illustrated with hand-specimens and models, and by weekly exercises throughout the senior year in the identification of minerals from physical and chemical characters. Instruction is also given in metallurgy, and especial attention is devoted to assaying and the investigation of ores and furnace-products. The student in agriculture has opportunity to acquaint himself with the modes of research employed in agricultural chemistry. The applications of the science to other branches of industry are taught as occasion requires. To advanced students, whether belonging to the regular classes or not, who desire to give attention to particular branches of chemistry, or to pursue original investigations, every facility is accorded. The private libraries of the professors, containing the chemical journals and the recent foreign literature of chemistry and mineralogy, the large collections of ores, furnace-products, &c., belonging to the school, and the extensive private cabinet of the professor of mineralogy, are freely used as aids in instruction.

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(b.) The special course of civil engineering comprises the following departments of study: 1. The higher mathematics, consisting of spherical trigonometry, higher analytical geometery, differential and integral calculus, descriptive geometry, and co-ordinate branches of study, &c. 2. Applied mathematics, which include all the field-operations and plotting comprised i in the various branches of practical surveying. A course of drawing, comprising Binn's Course of Orthographic Projection, with application to mechanical and engineering drawing; shading and tinting nting; linear perspective; free-hand drawing; isometrical, topographical, architectural, and structural drawing. 4. Theoretical mechanics; and mechanics applied to engineering in the construction and operation of machines, the utilization of water-power, the employment of prime movers, including hydraulic motors, and the steam-engine, &c. 5. Fieldengineering, which embraces the laying out of curves, and all the field-operations necessary in locating a line of road, establishing the grade, and determining the amount of excavation and embankment, &c. 6. Civil eng engineering, proper, or the science of construction, in its various departments, including, among many other topics the strength of materials, the establishment of foundations, the construction and stability of walls and arches, the theory and detail of the construction of bridges, roof-trusses, &c., in wood and iron, and the graphics of stone-cutting.

Students who pursue a higher course in engineering, for one year after graduating as bachelors, may receive the degree of civil engineer."

(c.) The course in dynamic engineering comprehends in its various branches of study and preparation all that have an immediate bearing on industrial pursuits, requiring the use of: 1. Instrumental drawing. Beginning with the elements of drawing, the students receive continuous instruction in all the conventional modes and practices of representing objects, machines, or structures, from the study of the objects, by plans, elevations, sections, shading and coloring, while at the same time, and by graphical representation, they learn the detailed construction of all classes of machinery, the application of mechanical movements, and the modes of transmitting motion and power. To these ends a large collection of standard drawings, models, and machines has been obtained and arranged for ready reference. 2. The higher mathematics. Spherical trigonometry, analytical geometry of three dimensions, differential and integral calculus, and descriptive geometry. 3. Applied mathematics and analytical mechanics. The principles of thermodynamics, or the application of mathematics to the investigation of the laws of heat, the principles of cinematics or the comparison of motions; the theory of mechanism. 4. Applied mechanics and thermodynamics. The application of mechanics, cinematics, and thermodynamics to the construction of boilers, or steamgenerators, the construction of steam or heat engines, the construction of water-wheels, shafting, gearing, and the construction and use of tools and machines for performing all kinds of useful work, the construction of iron bridges and structures of iron, the properties of materials as regards resistances to strains, or stresses, elasticity, durability, chemical reactions, friction, &c. 5. Dynamic engineering. The application of the principles of mathematics, mechanics, cinematics, thermodynamics, mechanism, and properties of materials to industrial operation, steamships, railway motive-power, manufactures, mills, forges, fabrication of materials, heating and ventilation, the utilization of water-power, draining, and irrigation, windmills, &c. 6. For students desiring to take a degree of dynamic engineer, two additional years will be required, during which the application of the foregoing studies will be continued in connection with the examination of existing works of industry in the various branches, and the exercises will be extended to the planning of such works, and the original designing of the various kinds of machinery applicable to them.

(d.) Students of agriculture, in addition to those general studies needed for mental discipline or general knowledge and culture, receive instruction in agricultural aud analytical chemistry, vegetable physiology and botany, zoology, entomology, geology, the culture of our staple crops, the principles of stock-breeding and rearing, and rural economy. These instructions are given partly by lectures and partly by recitations. In the coming year, the lectures on stock-breeding, rural economy, and the cultivation of crops, will be given during the fall term only.

(e.) Either geology, mineralogy, zoology, or botany may be made the principal study in natural history, some attention in each case being directed to the other three branches of natural history. In botany the extended course begins with structural and physiological botany, taught by text-books, lectures, and practical work with the microscope. Excursions and practice in identification of species and proper preservation of specimens follow. Familiarity with standard botanical literature is encouraged, and, lastly, students are taught to record their observations in scientific language, and to contribute, if possible, something to botanical science. In geology the instruction consists of recitations in Dana's Manual, illustrated by specimens of minerals, rocks, and fossils. Excursions are made to interesting localities to illustrate certain principles of the science which can be best studied in the field. Special students in geology pursue the practical study of fossils in the zoological laboratory, and of minerals and rocks in the chemical laboratory.

The instruction in zoology includes courses of lectures on systematic zoology, comparative anatomy, and the geographical distribution of animals, illustrated by specimens and a large number of diagrams; excursions for the purpose of studying the habits of living animals and collecting specimens; and practical instruction in the zoological laboratory, in comparative anatomy, embryology, and the identification, description, and classification of animals, together with their preservation and arrangement. The purpose is, in every case, to induce habits of close observation and accurate generalization, and, finally, to lead the student to make original investigations upon the objects of his study.

In mineralogy a course of lectures on elementary crystallography, and the physical properties of minerals, their chemical composition, classification, and the detailed description of mineral species, illustrated by constant reference to the mineral cabinets. Also a course of practical exercises in blow-pipe and determinative mineralogy.

(f.) During one year the work of the medical course will be chiefly under the direction of the instructors in chemistry; during the second year under that of the instructors in zoology and botany. In chemistry especial attention will be given to the examination of urine and the testing of drugs and poisons; in zoology to comparative anatomy, reproduction, embryology, the laws of hereditary descent and human parasites; and in botany to a general knowledge of structural and physiological botany, and to medicinal, food-producing, and poisonous plants.

(g.) Young men desiring to become mining engineers, can pursue the regular course in civil or mechanical engineering, and at its close can spend a fourth year in the study of metallurgy, mineralogy, &c. Should there be a sufficient number of students desiring it, a course of lectures on the subject of mining, will also be provided.

(h.) In accordance with a demand for systematic instruction in scientific studies, without reference to technical pursuits, and with a just regard to intellectual culture, a course is arranged as a basis for higher scientific pursuits, for teachers, business men, those designing to engage in editorial work, and others. This course, in addition to the instructions in German, French, and English, common to all departments of the school, includes instruction from Professer Whitney in the general principles of language, and from Mr. Lounsbury in the critical study of the English language, in its structure, history, and literature. Constant practice in writing is also required. Stu

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dents desiring to pursue the study of Latin, or of other languages, can easily make arrangements for doing so, if their time permits. The course also provides systematic instruction in the physical geography of the globe; in the special physical and historical geography of Europe and the United States; in the outlines of modern history, and in political economy. The students in this course receive from the various professors instruction in agricultural chemistry, botany, zoology, geology, and mineralogy. They attend the lectures on agriculture, rural economy, stock-breeding, &c., and those on general and theoretical chemistry. Their mathematical studies are continued in astronomy. They are expected to keep up the practice of drawing, especially of freehand drawing. So far as it does not interfere with appointments in the school, students in this course are permitted to attend the lectures of the academical depart

ment.

For the benefit of those who desire to pursue some particular studies, without reference to a college degree, most of the various instructors are willing to receive special students for a longer or shorter time. Only persons of mature minds are received. For example, in agriculture the instruction is so arranged that by attendance during the ensuing autumn term the scholar may hear the various lectures, and receive as much technical instruction in this one branch as by remaining through the winter. In the chemical laboratory, students properly qualified are received for short periods of work. In the various departments of natural history special lessons will also be given. Instruction may also be received in practical astronomy and the use of instruments. These opportunities are not offered to persons who are incompetent to go on with regular courses, but are designed to aid those who have been educated elsewhere to increase their proficiency in special branches.

Building and apparatus. Sheffield Hall, bearing the name of the donor, Mr. Joseph E. Sheffield, of New Haven, is a large and well-arranged building, containing recitation and lecture rooms for all the classes, a hall for public assemblies and lectures, laboratories for chemical and metallurgical investigations, a photographical room, an astronomical observatory, museums, a library and reading-room, besides studies for some of the professors, where their private technical libraries are kept.

The following is a summary statement of the collections belonging to the school : 1. Laboratories and apparatus in chemistry, metallurgy, mechanics, photography,

and zoology.

2. Metallurgical museum of ores, furnace-products, &c.

3. Agricultural museum of soils, fertilizers, useful and injurious insects, &c. 4. Collections in zoology.

5. Astronomical observatory, with an equatorial telescope by Clark and Son of Cambridge, a meridian circle, &c.

6. Library and reading-room, containing the Hillhouse Mathematical Library, books of reference, and a selection of German, French, English, and American scientific journals.

7. A collection of physical apparatus, constituting the Collier cabinet, recently bought by Professor Lyman.

8. Models in architecture, civil engineering, and mechanics, and diagrams adapted to public lectures.

9. Maps and charts, topographical, hydrographical, geological, &c.

The mineralogical cabinet of Professor Brush, the herbarium of Professor Brewer, the collection of native birds of Professor Whitney, and the astronomical instruments of Professor Lyman, are all deposited in the building. Professor Eaton's herbarium, near at hand, is freely accessible.

Students in this department are also admitted to the college and society libraries, the college reading-room, the cabinet of minerals and fossils, the school of the fine arts, and the gymnasium for physical exercise.

The instructions of this institution are given chiefly in small class-rooms, by recitations or familiar lectures, illustrated by all the apparatus at the command of the various teachers, A public course of lectures is given every winter on topics of popular interest. On Sunday evenings during a portion of the year lectures are given by resident clergymen of different denominations, and by members of the theological and other college faculties.

Tuition charges. The tuition charge is $150 per year. Besides this there is a charge of $5 annually for the use of the academical reading-room and gymnasium. Freshmen pay $5 for chemicals; and the special students in the chemical laboratory are likewise charged $25 per term for the materials they use-besides breakage. The graduation fee is $10.

Vacations correspond with those of the academical department.

THE STEVENS INSTITUTE OF TECHNOLOGY, HOBOKEN, NEW JERSEY. Officers of instruction. Henry Morton, Ph. D., President; Alfred H. Mayer, Ph. D., Professor of Physics; Robert H. Thurston, C. E., Professor of Mechanical Engineering;

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