{"title":"On the solutions of some Lebesgue–Ramanujan–Nagell type equations","authors":"Elif Kızıldere Mutlu, Gökhan Soydan","doi":"10.1142/s1793042124500593","DOIUrl":null,"url":null,"abstract":"<p>Denote by <span><math altimg=\"eq-00001.gif\" display=\"inline\" overflow=\"scroll\"><mi>h</mi><mo>=</mo><mi>h</mi><mo stretchy=\"false\">(</mo><mo stretchy=\"false\">−</mo><mi>p</mi><mo stretchy=\"false\">)</mo></math></span><span></span> the class number of the imaginary quadratic field <span><math altimg=\"eq-00002.gif\" display=\"inline\" overflow=\"scroll\"><mi>ℚ</mi><mo stretchy=\"false\">(</mo><msqrt><mrow><mo stretchy=\"false\">−</mo><mi>p</mi></mrow></msqrt><mo stretchy=\"false\">)</mo></math></span><span></span> with <span><math altimg=\"eq-00003.gif\" display=\"inline\" overflow=\"scroll\"><mi>p</mi></math></span><span></span> prime. It is well known that <span><math altimg=\"eq-00004.gif\" display=\"inline\" overflow=\"scroll\"><mi>h</mi><mo>=</mo><mn>1</mn></math></span><span></span> for <span><math altimg=\"eq-00005.gif\" display=\"inline\" overflow=\"scroll\"><mi>p</mi><mo>∈</mo><mo stretchy=\"false\">{</mo><mn>3</mn><mo>,</mo><mn>7</mn><mo>,</mo><mn>1</mn><mn>1</mn><mo>,</mo><mn>1</mn><mn>9</mn><mo>,</mo><mn>4</mn><mn>3</mn><mo>,</mo><mn>6</mn><mn>7</mn><mo>,</mo><mn>1</mn><mn>6</mn><mn>3</mn><mo stretchy=\"false\">}</mo></math></span><span></span>. Recently, all the solutions of the Diophantine equation <span><math altimg=\"eq-00006.gif\" display=\"inline\" overflow=\"scroll\"><msup><mrow><mi>x</mi></mrow><mrow><mn>2</mn></mrow></msup><mo stretchy=\"false\">+</mo><msup><mrow><mi>p</mi></mrow><mrow><mi>s</mi></mrow></msup><mo>=</mo><mn>4</mn><msup><mrow><mi>y</mi></mrow><mrow><mi>n</mi></mrow></msup></math></span><span></span> with <span><math altimg=\"eq-00007.gif\" display=\"inline\" overflow=\"scroll\"><mi>h</mi><mo>=</mo><mn>1</mn></math></span><span></span> were given by Chakraborty <i>et al</i>. in [Complete solutions of certain Lebesgue–Ramanujan–Nagell type equations, <i>Publ. Math. Debrecen</i><b>97</b>(3–4) (2020) 339–352]. In this paper, we study the Diophantine equation <span><math altimg=\"eq-00008.gif\" display=\"inline\" overflow=\"scroll\"><msup><mrow><mi>x</mi></mrow><mrow><mn>2</mn></mrow></msup><mo stretchy=\"false\">+</mo><msup><mrow><mi>p</mi></mrow><mrow><mi>s</mi></mrow></msup><mo>=</mo><msup><mrow><mn>2</mn></mrow><mrow><mi>r</mi></mrow></msup><msup><mrow><mi>y</mi></mrow><mrow><mi>n</mi></mrow></msup></math></span><span></span> in unknown integers <span><math altimg=\"eq-00009.gif\" display=\"inline\" overflow=\"scroll\"><mo stretchy=\"false\">(</mo><mi>x</mi><mo>,</mo><mi>y</mi><mo>,</mo><mi>s</mi><mo>,</mo><mi>r</mi><mo>,</mo><mi>n</mi><mo stretchy=\"false\">)</mo><mo>,</mo></math></span><span></span> where <span><math altimg=\"eq-00010.gif\" display=\"inline\" overflow=\"scroll\"><mi>s</mi><mo>≥</mo><mn>0</mn></math></span><span></span>, <span><math altimg=\"eq-00011.gif\" display=\"inline\" overflow=\"scroll\"><mi>r</mi><mo>≥</mo><mn>3</mn></math></span><span></span>, <span><math altimg=\"eq-00012.gif\" display=\"inline\" overflow=\"scroll\"><mi>n</mi><mo>≥</mo><mn>3</mn></math></span><span></span>, <span><math altimg=\"eq-00013.gif\" display=\"inline\" overflow=\"scroll\"><mi>h</mi><mo>∈</mo><mo stretchy=\"false\">{</mo><mn>1</mn><mo>,</mo><mn>2</mn><mo>,</mo><mn>3</mn><mo stretchy=\"false\">}</mo></math></span><span></span> and <span><math altimg=\"eq-00014.gif\" display=\"inline\" overflow=\"scroll\"><mo>gcd</mo><mo stretchy=\"false\">(</mo><mi>x</mi><mo>,</mo><mi>y</mi><mo stretchy=\"false\">)</mo><mo>=</mo><mn>1</mn></math></span><span></span>. To do this, we use the known results from the modularity of Galois representations associated with Frey–Hellegoaurch elliptic curves, the symplectic method and elementary methods of classical algebraic number theory. The aim of this paper is to extend the above results of Chakraborty <i>et al</i>.</p>","PeriodicalId":14293,"journal":{"name":"International Journal of Number Theory","volume":null,"pages":null},"PeriodicalIF":0.5000,"publicationDate":"2024-04-06","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"International Journal of Number Theory","FirstCategoryId":"100","ListUrlMain":"https://doi.org/10.1142/s1793042124500593","RegionNum":3,"RegionCategory":"数学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"MATHEMATICS","Score":null,"Total":0}
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Abstract
Denote by the class number of the imaginary quadratic field with prime. It is well known that for . Recently, all the solutions of the Diophantine equation with were given by Chakraborty et al. in [Complete solutions of certain Lebesgue–Ramanujan–Nagell type equations, Publ. Math. Debrecen97(3–4) (2020) 339–352]. In this paper, we study the Diophantine equation in unknown integers where , , , and . To do this, we use the known results from the modularity of Galois representations associated with Frey–Hellegoaurch elliptic curves, the symplectic method and elementary methods of classical algebraic number theory. The aim of this paper is to extend the above results of Chakraborty et al.
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This journal publishes original research papers and review articles on all areas of Number Theory, including elementary number theory, analytic number theory, algebraic number theory, arithmetic algebraic geometry, geometry of numbers, diophantine equations, diophantine approximation, transcendental number theory, probabilistic number theory, modular forms, multiplicative number theory, additive number theory, partitions, and computational number theory.
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