Encyclopedia > George Jeffreys

  Article Content

George Jeffreys

George Jeffreys (1648-1689), Baron Wem, better known as "Judge Jeffreys," became notorious during the reign of King James II, rising to the position of Lord Chancellor. He was born near Wrexham[?] in Wales, and embarked on a legal career in 1668. Shortly afterwards, he wormed his way into the favour of the Duke of York, younger brother of Charles II of England, who would succeed Charles as king. This development in Jeffreys's career indicates his ambition, since he had been brought up a strict Protestant, and James was a Catholic. Jeffreys was knighted in 1677 and by 1680 had become chief justice of Chester. Charles II created him a baronet in 1681, and two years later he was chief justice of the King's Bench. His subsequent career showed how willing he was to subordinate his impartiality as a judge to his political ambitions.

One of several trials which showed how far Jeffreys was prepared to go in order to curry royal favour was that of Algernon Sidney, who had been implicated in the Rye House Plot[?] and was convicted on the flimsiest evidence and executed. James II, following his accession to the throne, gave the judge the title of 1st Baron Jeffreys.

His reputation as a judge became even more unsavoury following the sentences he handed out to followers of James, Duke of Monmouth, an episode that concluded the Monmouth Rebellion which became known as the "Bloody Assizes." James created him Lord Chancellor in 1685, and he held this position until James was deposed in 1688. Recognizing what the new reign would mean for him, he attempted to flee the country but was captured and died, unlamented, in the Tower of London.



All Wikipedia text is available under the terms of the GNU Free Documentation License

 
  Search Encyclopedia

Search over one million articles, find something about almost anything!
 
 
  
  Featured Article
Osmosis

... the pressure increases the chemical potential of the system in proportion to the molar volume (δμ = δPV). Therefore, osmosis stops, when the ...