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This work is dedicated to the properties of the 3 × 3 magic squares of cubes modulo a prime number. Its central concept is the number of distinct entries of these squares and the properties associated with this number. We call this number the degree of a magic square. The necessary conditions for the magic square of cubes with degrees 3, 5, 7, and 9 are examined. It was established that there are infinitely many primes for which magic squares of cubes with degrees 3, 5, 7, and 9 exist. I apply n-tuples of consecutive cubic residues to prove that there are infinitely many Magic Squares of Cubes with degree 9. Furthermore I use Brauer’s theorem, that guarantees the existence of a sequence of consecutive integers of any length, to construct Magic Squares of Cubes whose entries are all cubic residues. Such analytic tools as Modular Arithmetic, Legendre symbol, Fermat’s Little Theorem, notions of quadratic and cubic residues were employed in the process of research.
In this paper, I examine magic squares of squares (MSS) of order 5 over Zp where p is a prime number. The first approach to the problem is to find how many distinct elements an MSS may have (called the degree of the MSS). In the next step, I study the relationship between the magic sum and the center entry of any MSS. In order to develop construction methods and configurations for magic squares of squares of order 5 with desired degrees, I study Pythagorean triples and sequences of consecutive quadratic residues modulo p. Properties of these sequences are provided and applied to construct desired magic squares of squares. This research focuses on magic squares of squares of order 5 in which the center 3 x 3 square is a magic square of squares of order 3. I claim that the magic sum of such an MSS M is 5c, where c is the center element of M and the degree of M must be odd when p > 5. The main results of the thesis include several configurations for the construction of MSS of a given degree and the existence ofMSSs of all possible odd degrees over Zp for infinitely many primes p. Chapter 1 presents an overview of modular arithmetic as well as some important definitions. Chapter 2 gives the results about the magic sum and degrees. In Chapter 3, I investigate special sequences of quadratic residues and describe properties of them. In Chapter 4, by applying special sequences of quadratic residues, several configurations are developed and they are used to construct MSSs of a given degree. The main results of this thesis are provided in Chapter 4 as well.
The puzzles in this book are based on 5 by 5 pandiagonal magic squares. A pandiagonal magic square has 20 sums to the same number. Each row, each column, each of 5 downward diagonals, and each of 5 upward diagonals sum to the same number, called the magic sum. The four following charts show the 5 rows, the 5 columns, the 5 downward diagonals, and the 5 upward diagonals.The rows, columns, and diagonals will be illustrated using the following magic square. Incidentally, all entries in this magic square are prime integers. 5 103 16067 19 1493 17 1489 17 101 16063 113 16061 13 1487 13 1483 11 109 16073 1116069 23 1481 7 107The 5 rows: 1 1 1 1 12 2 2 2 23 3 3 3 34 4 4 4 45 5 5 5 5The top row sum is 5 + 103 + 16067+19 + 1493 = 17687.The second row sum is 17 + 1489 + 17 + 101 + 16063 = 17687.The third row sum is 113 + 16061 + 13 + 1487 + 13 = 17687.The fourth row sum is 1483 + 11 + 109 + 16073 + 11 = 17687.The fifth row sum is 16069 + 23 + 1481 + 7 + 107 = 17687. 5 103 16067 19 1493 17 1489 17 101 16063 113 16061 13 1487 13 1483 11 109 16073 11 16069 23 1481 7 107The 5 columns:1 2 3 4 51 2 3 4 51 2 3 4 51 2 3 4 51 2 3 4 5The first column sum is 5 + 17 + 113 + 1483 + 16069 = 17687.The second column sum is 103 + 1489 + 16061 + 11 + 23 = 17687.The third column sum is 16067 + 17 + 13 + 109 + 1481 = 17687.The fourth column sum is 19 + 101 + 1487 + 16073 + 7 = 17687.The fifth column sum is 1493 + 16063 + 13 + 11 + 107 = 17687. Four of the downward diagonals and four of the upward diagonals are broken diagonals.They wrap around the edges of the square as shown in the following two diagrams. 5 103 16067 19 1493 17 1489 17 101 16063 113 16061 13 1487 13 1483 11 109 16073 1116069 23 1481 7 107The 5 downward diagonals1 2 3 4 55 1 2 3 44 5 1 2 33 4 5 1 22 3 4 5 1The first downward diagonal sum is 5 + 1489 + 13 + 16073 + 107 = 17687.The second downward diagonal sum is 103 + 17 + 1487 + 11 + 16069 = 17687.The third downward diagonal sum is 16067 + 101 + 13 + 1483 + 23 = 17687.The fourth downward diagonal sum is 19 + 16063 + 113 + 11 + 1481 = 17687.The fifth downward diagonal sum is 1493 + 17 + 16061 + 109 + 7. 5 103 16067 19 1493 17 1489 17 101 16063 113 16061 13 1487 13 1483 11 109 16073 11 16069 23 1481 7 107The 5 upward diagonals5 4 3 2 14 3 2 1 53 2 1 5 42 1 5 4 31 5 4 3 2The first upward diagonal sum is 16069 + 11 + 13 + 101 + 1493 = 17687.The second upward diagonal sum is 1483 + 16061 + 17 + 19 + 107 = 17687.The third upward diagonal sum is 113 + 1489 + 16067 + 19 + 1493 = 17687.The fourth upward diagonal sum is 17 + 103 + 1481 + 16073 + 13 = 17687.The fifth upward diagonal sum is 5 + 23 + 109 + 1487 + 16063 = 17687.Each puzzle has from 10 to 15 of the solution entries marked out. Your task is to fill in the marked out numbers to recreate the magic square that has only prime number entries.
A magic square M over an integral domain D is a 3 x 3 matrix with entries from D such that the elements from each row, column, and diagonal add to the same sum. If all the entries in M are perfect squares in D, we call M a magic square of squares over D. Martin LaBar raised an open question in 1984, which states, “Is there a magic square of squares over the ring Z of the integers which has all the nine entries distinct?” We approach to answering a similar question in case D is a finite field. Our main result confirms that a magic square of squares over a finite field F of characteristic greater than 3 can only hold 3, 5, 7, or 9 distinct entries. Corresponding to LaBar’s question, we claim that there are infinitely many prime numbers p such that, over a finite field of characteristic p, magic squares of squares with nine distinct elements exist. Constructively, we build magic squares of squares using consecutive quadratic residue triples derived from twin primes. We classify all the magic squares of squares over any finite fields of characteristic 2. Description of magic squares over a finite field of characteristic 3 is provided.