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Philipp von Jolly

Philipp von Jolly (26 September 1809 – 24 December 1884) was a experimental and whose work focused on precise measurements in gravitation, , and related fields. Born in to a family of Huguenot descent originally from , he studied at the University of Heidelberg, earning his in 1834, before advancing through academic positions culminating in his appointment as professor of physics at the University of Munich in 1854, succeeding . Jolly's legacy endures through his innovative instruments and methods, which advanced experimental techniques in 19th-century physics. Jolly's most notable invention was the Jolly balance, developed in 1864 as a spring-based device for determining specific gravity by comparing weights in air and water using a double-pan setup suspended from a tapered helical . This tool, valued for its simplicity and speed in measuring large specimens like gems or minerals, remains in use today and exemplified his emphasis on practical instrumentation. He also refined other apparatus, including a mercury air-pump, an air thermometer, and a introduced in 1879 for gas analysis. In gravitation research, Jolly employed the balance with a massive 5,775 kg lead sphere to measure minute weight variations, confirming Newton's law and estimating the Earth's density at approximately 5.7 times that of water. His studies extended to —exploring fluid across membranes—and the composition of air, contributing foundational data to these areas. As an educator, Jolly knighted in 1854 for his scholarly impact, supervised promising students at , including a young . In 1874, when Planck sought guidance on pursuing , Jolly cautioned that the field was "almost everything... already discovered" with only "a few unimportant holes" left to fill, reflecting the era's belief in physics' maturity following principles. Planck disregarded the advice, going on to pioneer in —ironically upending the very completeness Jolly had foreseen. Jolly authored key texts like Physik der Molecularkräfte (1857) on molecular forces and Die Prinzipien der Mechanik (1852) on , solidifying his role in bridging classical experimental and .

Early Life and Education

Family Background

Philipp von Jolly was born on 26 September 1809 in , (now ). His family was of Huguenot descent, originating from , where they had fled at the end of the 17th century following the revocation of the in 1685. Jolly's father, who had served as an army captain before becoming a , provided a stable but non-academic household that emphasized practical ; he later held the position of of for many years. In this environment, Jolly gained early exposure to and through schooling at the local and in , which ignited his foundational interests in these disciplines. These formative experiences in paved the way for his transition to university studies at .

Academic Studies

Philipp von Jolly began his academic studies in the natural sciences in 1829 at the University of , where he initially focused on under the guidance of Wilhelm Eisenlohr, though he supplemented his learning through extensive self-study of works by Leonhard Euler. His early education was supported by his family from , a background that provided the foundation for his pursuit of higher learning despite his frail health during childhood. After continuing his studies in until approximately 1831, Jolly traveled to from 1832 to 1833, where he largely engaged in independent research and practical work as a mechanician in factories and mining plants, interacting with peers such as and Redtenbacher to deepen his understanding of and . He then spent approximately one year in around 1833, immersing himself in the vibrant academic environment and engaging with prominent scholars including Gustav Magnus, Heinrich Wilhelm Dove, and , as well as influences from and Eilhard Mitscherlich, which shifted his focus toward physics. Returning to Heidelberg in 1834, Jolly earned his degree with a dissertation titled De Euleri meritis de functionibus circularibus, exploring Euler's contributions to circular functions—a mathematical topic to mechanics. That same year, he qualified as a Privatdozent in , physics, and at , an achievement that marked the commencement of his teaching career and built on the prize he had won in 1830 for a related paper on Euler's work.

Professional Career

Positions at Heidelberg

In 1839, following his studies in mathematics and physics at the universities of , , and , Philipp von Jolly was appointed as an extraordinary professor of at . In this role, he contributed to the institution's mathematical instruction during a period when the university was expanding its scientific faculties amid the broader reforms in . By 1846, Jolly was promoted to the ordinary professorship of at , marking a significant shift in his academic focus toward and laboratory-based teaching. This promotion came at a time when in was transitioning from theoretical lectures to practical demonstrations, and Jolly played a key role in introducing hands-on courses for students, which were innovative for the era. He emphasized experimental demonstrations to illustrate physical principles, addressing the previous lack of dedicated facilities for such instruction at the . Jolly's tenure also involved substantial administrative efforts to strengthen the university's scientific infrastructure. In 1846, he negotiated with the Baden Minister of Culture to secure funding and resources for a and scientific instruments, partly relying on personal and support. These initiatives led to the establishment of the first Physics Institute in 1850 at Haus zum Riesen on Heidelberg's Hauptstraße, where students could conduct independent experiments for the first time. Additionally, Jolly oversaw the expansion of the Physics Cabinet's collection of apparatus and initiated the of the Friedrichsbau , laying essential groundwork for experimental and in . This period of apparatus building and facility development, from 1846 to 1854, positioned Heidelberg as a center for practical in mid-19th-century .

Professorship at Munich

In 1854, Philipp von Jolly was appointed as ordinary professor of physics at the University of , succeeding the renowned Georg Simon Ohm, and he held this position until his death in 1884. Building on his prior experience directing the physical cabinet at , Jolly arrived to lead the department during a period of growing emphasis on experimental sciences in German academia. Jolly expanded practical training in physics at , developing key apparatuses like air thermometers, spring balances, and air pumps for hands-on student work between the and . These facilities enhanced the institute's capacity for practical instruction, reflecting Jolly's commitment to integrating demonstration and measurement techniques into . His efforts modernized the academic program, fostering a environment where students could engage directly with evolving experimental methods. Jolly's teaching responsibilities included delivering lectures on , , and , renowned for their clarity, elegance, and engaging demonstrations that drew large audiences from various faculties across the university. These courses not only covered foundational principles but also emphasized precise measurement and instrumental techniques, attracting a broad student body interested in applied sciences. Complementing his classroom duties, Jolly oversaw a physical that provided advanced guidance in experimental practices. Beyond teaching, Jolly undertook substantial administrative roles, including participation in the reorganization of Bavarian technical educational institutions and serving as a scientific advisor to the Normalaichungscommission for standardizing weights and measures. He contributed to 's adoption of the , representing the state in the 1861 Federal Assembly and promoting reforms that elevated physics as a central discipline in . Through these initiatives, Jolly helped solidify the university's reputation as a hub for physics instruction and institutional development in 19th-century .

Scientific Contributions

Work on Gravitation

Philipp von Jolly made significant contributions to the experimental determination of gravitational forces, particularly through precise measurements of local variations in and the mean of the . These efforts emphasized the role of instrumental precision in quantifying subtle gravitational effects. Von Jolly's most notable work culminated in a series of experiments conducted between 1879 and 1880 in , where he developed advanced weighing techniques to verify by measuring the decrease in weight with height above the Earth's surface. Using a custom double-beam sensitive to less than 1 μg, he compared the weights of 5 kg mercury-filled globes positioned at different heights—approximately 21 apart in a tower. By interchanging the positions of heavy (mercury-filled) and light (air-filled) globes on the balance arms, he observed a of 31 mg when the heavier was lowered, closely aligning with the theoretically expected value of 33 mg derived from Newton's . This high accuracy, with a relative uncertainty of about 1.2%, confirmed the predicted variation in gravitational force due to distance from the Earth's center. To further probe gravitational interactions and determine the Earth's mean , von Jolly incorporated a massive 5775.2 kg lead (approximately 1 m in diameter) into his setup, positioning it beneath one of the lower balance pans at a distance of about 0.57 m. The 's attraction on the 5 kg mercury mass produced an additional weight increase of 0.589 mg (equivalent to a force of 5.8 μN), allowing him to calculate the Newtonian G = 6.465 \times 10^{-11} m³ kg⁻¹ s⁻². By comparing this attraction to the 's pull on the same test mass and accounting for the planet's radius, he derived an of approximately 5.7 g/cm³, a value that refined contemporary estimates and underscored the uniformity of gravitational law on terrestrial scales. These results were detailed in his publications in the (1878 and 1881). Von Jolly's innovations extended to the design of refined balances, akin to torsion systems in their sensitivity, which he employed for mapping local around . These instruments enabled measurements of the gravity gradient, revealing a decrease of roughly 300 μGal per meter in with height, consistent with theoretical predictions and aiding in the validation of geophysical surveys. His methodological emphasis on minimizing environmental disturbances, such as air and effects, set standards for subsequent precision .

Studies in Osmosis and Instruments

In the 1840s, during his time at the University of , Philipp von Jolly conducted investigations into , focusing on the effects of semi-permeable membranes on solutions of varying concentrations. He measured differences by observing weight changes in custom-designed balances that separated pure solvent from solute-laden solutions, allowing precise quantification of fluid transfer across the membrane. These experiments led Jolly to propose that equal weights of solvent and solute were exchanged, an idea that challenged prevailing views on diffusive equilibrium but was later shown to be incorrect. A key outcome of this work was Jolly's invention of the Jolly balance in 1864, a spring-based apparatus optimized for accurate weight comparisons in studies. The device featured a vertical with a sliding rider for fine adjustments, enabling measurements of small mass differences without traditional beam balances. For and applications, it incorporated attachments like thin wires or rings dipped into liquids, where mercury columns in connected manometers helped calibrate pressure-induced weight shifts across membranes or at liquid interfaces. This setup allowed Jolly to quantify by the force required to detach a ring from a liquid film, providing data on cohesive forces in solutions. Building on these techniques, Jolly adapted methods from his earlier gravitational measurements to enhance in experiments during the . He turned to studies of air composition, employing sealed glass systems to examine density variations and rates. Using a custom —a graduated for gas —he trapped air samples and measured compositional changes under controlled conditions, revealing subtle fluctuations in atmospheric oxygen and levels due to and environmental factors. Jolly's instruments found broader application in exploring capillary action, where the Jolly balance setup was modified to assess liquid rise in narrow tubes. By suspending capillary tubes over mercury reservoirs and recording equilibrium heights via weight comparisons, he detailed how surface tension drove fluid ascension against gravity, offering insights into intermolecular forces without relying on direct height metrics alone. These configurations emphasized practical measurement over theoretical modeling, influencing subsequent experimental designs in fluid mechanics.

Mentorship and Interactions

Advisory Role with Max Planck

In 1874, shortly after beginning his studies at the University of Munich, sought career advice from his physics professor, Philipp von Jolly, who held the chair in there. Von Jolly cautioned Planck against pursuing , describing the field as a highly developed and nearly complete science with only minor gaps remaining to be filled. Despite this discouraging counsel, Planck persisted in his studies and ultimately completed his doctoral dissertation under von Jolly's supervision in 1879. The thesis, titled "On the Second Fundamental Theorem of the Mechanical Theory of Heat," focused on the of and explored within classical frameworks. Von Jolly provided experimental guidance during this period but remained committed to established classical theories, reflecting his preference for refining rather than revolutionizing physical principles. This interaction, recounted by Planck himself, highlights the prevailing late-19th-century perception among some physicists that the discipline had reached a state of maturity, with fundamental discoveries largely exhausted. The illustrates the ironic contrast between von Jolly's conservative outlook and the groundbreaking theoretical advancements that Planck would later pioneer.

Collaborations with Contemporaries

During his time in Munich starting in 1854, Philipp von Jolly engaged in professional interactions with the prominent chemist , including a joint visit to the that facilitated discussions on topics at the intersection of chemistry and physics, such as the properties of . Their shared interests extended to experimental work on solution densities, reflected in Jolly's lectures delivered in Liebig's auditorium at the . Earlier, during his studies in from 1831 to 1833, Jolly interacted closely with Eilhard Mitscherlich, the professor of chemistry there, whose expertise in shaped Jolly's approaches to physical phenomena in crystalline materials and informed his later experimental methods in physics. As a member of the Bavarian Academy of Sciences from 1859, Jolly actively participated in its discussions and sessions, contributing to advancements in ; for instance, his 1865 rectoral address at the University of highlighted the legacy of and engaged with his successors' ongoing work on optical devices in the . Jolly's research on measurements involved collaborative verification through published exchanges with international physicists, as part of broader metrological efforts; he presented key findings in academy proceedings in 1878 and 1881, building on Cavendish's methods and aligning with contemporary experiments across , while contributing to international commissions in (1861), Paris (1872), and (1873).

Publications

Textbooks

Philipp von Jolly's early , Anleitung zur - und (1846), served as a comprehensive guide to and , emphasizing practical examples tailored for physics students to bridge mathematical theory with physical applications. This work, published in by Winter, covered key topics such as Taylor's series, maxima and minima, and applications of , promoting clarity in exposition for educational purposes. Revised editions appeared through the , reflecting ongoing refinements to align with evolving university teaching needs. In 1852, Jolly published Die Principien der Mechanik, gemeinfaßlich dargestellt in , an accessible on and that incorporated experimental illustrations to demonstrate mechanical principles. The book simplified complex concepts for students across disciplines, focusing on key results and intuitive explanations rather than exhaustive derivations, thereby enhancing comprehension in introductory physics courses. Jolly's Physik der Molecularkräfte (Munich, 1857) explored the physics of molecular forces, contributing to 19th-century understandings of intermolecular interactions. Jolly's later educational contribution, Programm zu den Vorlesungen über Experimental-Physik (1873), outlined lectures integrating with practical methods, drawing briefly from his research on to illustrate heat phenomena through verifiable experiments. This -published work emphasized empirical verification over abstract theory, providing students with hands-on approaches to thermal processes.

Scientific Papers

Philipp von Jolly produced an extensive body of peer-reviewed research articles, with a bibliography compiled posthumously listing 28 key contributions from 1834 to 1881, mainly in leading German journals such as Annalen der Physik und Chemie (formerly Poggendorff's Annalen) and proceedings of the Bayerische Akademie der Wissenschaften. These works emphasized experimental precision and instrumental innovation, often referencing apparatus like his spring balance for density measurements as detailed in his instructional texts. A landmark publication on gravitational variations appeared in in 1881, titled "Die Anwendung der Waage auf Probleme der Gravitation," where von Jolly reported an empirical weight difference of 31 mg for 5-kg test masses measured at different heights using a precision balance, alongside detailed instrument calibration protocols to account for environmental factors. This built on earlier academy reports from 1878 and 1881 in Abhandlungen der Bayerischen Akademie der Wissenschaften (II. Classe, Bände XIII and XIV), which outlined the methodology for weighing gravitational effects with large lead spheres to enhance sensitivity. Von Jolly's investigations into were detailed in several articles in Poggendorff's und Chemie during the 1840s, including the foundational 1849 piece "Experimentaluntersuchungen über Endosmose" (Band 78), which quantified differences through porous barriers and included schematics of cells for measuring rates. His studies on air and composition were published in the through the Bayerische Akademie der Wissenschaften, notably "Die Veränderlichkeit in der Zusammensetzung der atmosphärischen Luft" (1878, Abhandlungen II. Classe, Band XIII, Abtheilung II), which presented rates derived from sealed chamber experiments using sensitive balances to detect trace compositional variations over time. These papers highlighted empirical data on atmospheric heterogeneity, attributing minor fluctuations to under controlled conditions.

Legacy and Recognition

Influence on Physics

Philipp von Jolly's development of the Jolly balance in standardized precision measurements of specific gravity for solids and liquids, an instrument that has been employed by generations of students in settings to teach fundamental principles of determination and experimental accuracy. This device, utilizing a spring-based system for assessments, remains referenced in contemporary educational labs, including those exploring properties where accurate data is essential. As a at the University of from 1846 to 1854 and later at , von Jolly emphasized empirical in physics instruction, advocating for dedicated laboratories and hands-on practicals to integrate experimental techniques into the . His initiatives, including the establishment of the Friedrichsbau science building and funding for instructional apparatus, set precedents for experimental in 19th-century German universities, shaping the training of subsequent scientists in rigorous, observation-based inquiry. Von Jolly's gravitational experiments, particularly his 1878 and 1881 beam balance measurements using a 5775 kg lead sphere, provided early precise determinations of the Earth's gravity gradient (approximately 300 μGal m⁻¹) and the Newtonian constant G (6.465 × 10⁻¹¹ m³ kg⁻¹ s⁻²), contributing geophysical constants that informed later gravity mapping and prospecting techniques. These results validated Newton's inverse square law at laboratory scales and laid methodological foundations for advanced gravimetry tools, such as torsion balances and modern gradiometers used in geophysical surveys. An ironic aspect of von Jolly's legacy emerged from his 1874 advice to the young , whom he counseled against pursuing physics on the grounds that the field was "highly developed and virtually full-grown," with only minor refinements remaining after the establishment of . This view, expressed amid the late 19th-century complacency in , starkly contrasted with Planck's subsequent formulation of in 1900, underscoring the unforeseen paradigm shifts that von Jolly's era could not anticipate and highlighting the limitations of even empirical rigor in predicting theoretical revolutions.

Commemorations

Philipp von Jolly died on 24 December 1884 in at the age of 75. After his death, the spring balance he developed in 1864 for measuring specific gravities continued to be referred to as the Jolly balance in physics literature, honoring his contributions to experimental . Original instruments associated with von Jolly's work are preserved at the in , including a torsion balance constructed to his specifications by instrument maker Carl Stollnreuther and the 5,775 kg lead sphere he employed in 1879–1880 to determine the Earth's density. Von Jolly receives posthumous recognition in 20th-century histories of physics, where he is often cited in relation to his mentorship of , as detailed in Abraham Pais's Inward Bound: Of Matter and Forces in the Physical World (1986).

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